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MIT graduate programs provide collaborative environments for advanced study by students and faculty working together to extend the boundaries of knowledge. MIT boasts globally prominent graduate programs in engineering, science, computation, architecture and planning, management, and the social sciences and humanities. MIT's five schools and one college encompass a broad variety of degree paths, each with their unique requirements. Across all schools and the college, MIT graduate programs offer students the opportunity to gain unparalleled discipline-specific knowledge; to master the tools needed to advance research; and to acquire a bedrock foundation in the skills necessary for career advancement.

This section outlines the general requirements together with other important aspects of graduate education, including admissions and financial aid.

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The PDF includes all information on this page and its related tabs. Subject (course) information includes any changes approved for the current academic year.

PhD Program

Year after year, our top-ranked PhD program sets the standard for graduate economics training across the country. Graduate students work closely with our world-class faculty to develop their own research and prepare to make impactful contributions to the field.

Our doctoral program enrolls 20-24 full-time students each year and students complete their degree in five to six years. Students undertake core coursework in microeconomic theory, macroeconomics, and econometrics, and are expected to complete two major and two minor fields in economics. Beyond the classroom, doctoral students work in close collaboration with faculty to develop their research capabilities, gaining hands-on experience in both theoretical and empirical projects.

How to apply

Students are admitted to the program once per year for entry in the fall. The online application opens on September 15 and closes on December 15.

Meet our students

Our PhD graduates go on to teach in leading economics departments, business schools, and schools of public policy, or pursue influential careers with organizations and businesses around the world. 

Academic Programs

• CSE PhD Overview
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MIT Doctoral Programs in Computational Science and Engineering

The Center for Computational Science and Engineering (CCSE) offers two doctoral programs in computational science and engineering (CSE) – one leading to a standalone PhD degree in CSE offered entirely by CCSE (CSE PhD) and the other leading to an interdisciplinary PhD degree offered jointly with participating departments in the School of Engineering and the School of Science (Dept-CSE PhD).

While both programs enable students to specialize at the doctoral level in a computation-related field via focused coursework and a thesis, they differ in essential ways. The standalone CSE PhD program is intended for students who intend to pursue research in cross-cutting methodological aspects of computational science. The resulting doctoral degree in Computational Science and Engineering is awarded by CCSE via the the Schwarzman College of Computing. In contrast, the interdisciplinary CSE PhD program is intended for students who are interested in computation in the context of a specific engineering or science discipline. For this reason, this degree is offered jointly with participating departments across the Institute; the interdisciplinary degree is awarded in a specially crafted thesis field that recognizes the student’s specialization in computation within the chosen engineering or science discipline.

For more information about CCSE’s doctoral programs, please explore the links on the left. Information about our application and admission process is available via the ‘ Admissions ‘ tab in our menu. MIT Registrar’s Office provides graduate tuition and fee rates as set by the MIT Corporation and the Graduate Admissions section of MIT’s Office of Graduate Education (OGE) website contains additional information about costs of attendance and funding .

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Below is a list of the MIT Schwarzman College of Computing’s graduate degree programs. The Doctor of Philosophy (PhD) degree is awarded interchangeably with the Doctor of Science (ScD).

Prospective students apply to the department or program under which they want to register. Application instructions can be found on each program’s website as well as on the MIT Graduate Admissions website.

Center for Computational Science and Engineering

The Center for Computational Science and Engineering (CCSE) brings together faculty, students, and other researchers across MIT involved in computational science research and education. The center focuses on advancing computational approaches to science and engineering problems, and offers SM and PhD programs in computational science and engineering (CSE).

• Computational Science and Engineering, SM and PhD . Interdisciplinary master’s program emphasizing advanced computational methods and applications. The CSE SM program prepares students with a common core of computational methods that serve all science and engineering disciplines, and an elective component that focuses on particular applications. Doctoral program enables students to specialize in methodological aspects of computational science via focused coursework and a thesis which involves the development and analysis of broadly applicable computational approaches that advance the state of the art.
• Computational Science and Engineering, Interdisciplinary PhD. Doctoral program offered jointly with eight participating departments, focusing on the development of new computational methods relevant to science and engineering disciplines. Students specialize in a computation-related field of their choice through coursework and a doctoral thesis. The specialization in computational science and engineering is highlighted by specially crafted thesis fields. 

Department of Electrical Engineering and Computer Science

The largest academic department at MIT, the Department of Electrical Engineering and Computer Science (EECS) prepares hundreds of students for leadership roles in academia, industry, government and research. Its world-class faculty have built their careers on pioneering contributions to the field of electrical engineering and computer science — a field which has transformed the world and invented the future within a single lifetime. MIT EECS consistently tops the U.S. News & World Report and other college rankings and is widely recognized for its rigorous and innovative curriculum. A joint venture between the Schwarzman College of Computing and the School of Engineering, EECS (also known as Course 6) is now composed of three overlapping sub-units in electrical engineering (EE), computer science (CS), and artificial intelligence and decision-making (AI+D).

• Computation and Cognition, MEng*. Course 6-9P builds on the Bachelor of Science in Computation and Cognition to provide additional depth in the subject areas through advanced coursework and a substantial thesis.
• Computer Science, PhD
• Computer Science and Engineering, PhD
• Computer Science, Economics, and Data Science, MEng*. New in Fall 2022, Course 6-14P builds on the Bachelor of Science in Computer Science, Economics, and Data Science to provide additional depth in economics and EECS through advanced coursework and a substantial thesis.
• Computer Science and Molecular Biology, MEng*. Course 6-7P builds on the Bachelor of Science in Computer Science and Molecular Biology to provide additional depth in computational biology through coursework and a substantial thesis.
• Electrical Engineering, PhD
• Electrical Engineering and Computer Science, MEng* , SM* , and PhD . Master of Engineering program (Course 6-P) provides the depth of knowledge and the skills needed for advanced graduate study and for professional work, as well as the breadth and perspective essential for engineering leadership. Master of Science program emphasizes one or more of the theoretical or experimental aspects of electrical engineering or computer science as students progress toward their PhD.
• Electrical Engineer / Engineer in Computer Science.** For PhD students who seek more extensive training and research experiences than are possible within the master’s program.
• Thesis Program with Industry, MEng.* Combines the Master of Engineering academic program with periods of industrial practice at affiliated companies. 

* Available only to qualified EECS undergraduates. ** Available only to students in the EECS PhD program who have not already earned a Master’s and to Leaders for Global Operations students.

Institute for Data, Systems, and Society

The Institute for Data, Systems, and Society advances education and research in analytical methods in statistics and data science, and applies these tools along with domain expertise and social science methods to address complex societal challenges in a diverse set of areas such as finance, energy systems, urbanization, social networks, and health.

• Social and Engineering Systems, PhD. Interdisciplinary PhD program focused on addressing societal challenges by combining the analytical tools of statistics and data science with engineering and social science methods.
• Technology and Policy, SM . Master’s program addresses societal challenges through research and education at the intersection of technology and policy.
• Interdisciplinary Doctoral Program in Statistics . For students currently enrolled in a participating MIT doctoral program who wish to develop their understanding of 21st-century statistics and apply these concepts within their chosen field of study. Participating departments and programs: Aeronautics and Astronautics, Brain and Cognitive Sciences, Economics, Mathematics, Mechanical Engineering, Physics, Political Science, and Social and Engineering Systems.

Operations Research Center

The Operations Research Center (ORC) offers multidisciplinary graduate programs in operations research and analytics. ORC’s community of scholars and researchers work collaboratively to connect data to decisions in order to solve problems effectively — and impact the world positively.

In conjunction with the MIT Sloan School of Management, ORC offers the following degrees:

• Operations Research, SM and PhD . Master’s program teaches important OR techniques — with an emphasis on practical, real-world applications — through a combination of challenging coursework and hands-on research. Doctoral program provides a thorough understanding of the theory of operations research while teaching students to how to develop and apply operations research methods in practice.
• Business Analytics, MBAn. Specialized advanced master’s degree designed to prepare students for careers in data science and business analytics.

Brain and Cognitive Sciences PhD Program

Graduate students in the Department of Brain and Cognitive Sciences are among the sharpest, most innovative brain scientists to be found anywhere. In a given year the department admits 5 to 10 percent of applicants, and our PhD program is consistently ranked among the best in the world. Students work hard to get here, and they are highly valued in the BCS community.

Innovative:  Our students often take on riskier projects and pilot studies that probe the edges of our technical and scientific knowledge. They can move among projects more easily, and their successes lay the foundation for not only their careers but the future directions of their mentors’ labs.

Collaborative:  Our students bring bold, fresh thinking to the department, and exploring these potentially transformative ideas often means reaching across boundaries of lab, center, and department to build new collaborations. Graduate students help BCS mesh with the rest of MIT.

Supportive: Graduate students are the most frequent mentors of undergraduate students in UROPs , actively guiding and developing those who will become the next generation of top-tier graduate students. BCS graduate students also are helping make sure the department is a welcoming, inclusive, and equitable community.

Overview of the Program

Graduate students in the Department of Brain and Cognitive Sciences work with an advisor and advisory committee to pursue an innovative and rigorous program of original research. Students should aim to complete their PhD in five to six years.  

• Students take three to four of their required six courses
• Students complete required Responsible Conduct in Science training.
• Students complete a minimum of three lab rotations by March 31.
• Students select a thesis advisor by April 30.    
• Students complete the remaining two to three of their academic course requirements by the end of the Spring Term.
• Students complete teaching assistant training and their first teaching (TA) requirement.
• Students form their qualifying exam advisory committee, have their first committee meeting, and turn in the completed committee meeting form to BCS HQ by the end of the Spring Term.   
• Students complete the second teaching (TA) requirement.
• Students complete the written and oral qualifying exam in October or November.  
• Students form a thesis committee, submit a written thesis proposal to their committee, orally present their proposal to the thesis committee, and receive committee approval, before the end of the Spring Term.
• Students must meet with their thesis committee once per year.
• Students take the final steps to completing the PhD oral examination (also known as the thesis defense) and submission of the approved written dissertation.

For detailed information on courses, rotations, and other program requirements, see Program Details .

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PhD in Physics, Statistics, and Data Science

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Many PhD students in the MIT Physics Department incorporate probability, statistics, computation, and data analysis into their research. These techniques are becoming increasingly important for both experimental and theoretical Physics research, with ever-growing datasets, more sophisticated physics simulations, and the development of cutting-edge machine learning tools. The Interdisciplinary Doctoral Program in Statistics (IDPS)  is designed to provide students with the highest level of competency in 21st century statistics, enabling doctoral students across MIT to better integrate computation and data analysis into their PhD thesis research.

Admission to this program is restricted to students currently enrolled in the Physics doctoral program or another participating MIT doctoral program. In addition to satisfying all of the requirements of the Physics PhD, students take one subject each in probability, statistics, computation and statistics, and data analysis, as well as the Doctoral Seminar in Statistics, and they write a dissertation in Physics utilizing statistical methods. Graduates of the program will receive their doctoral degree in the field of “Physics, Statistics, and Data Science.”

Doctoral students in Physics may submit an Interdisciplinary PhD in Statistics Form between the end of their second semester and penultimate semester in their Physics program. The application must include an endorsement from the student’s advisor, an up-to-date CV, current transcript, and a 1-2 page statement of interest in Statistics and Data Science.

The statement of interest can be based on the student’s thesis proposal for the Physics Department, but it must demonstrate that statistical methods will be used in a substantial way in the proposed research. In their statement, applicants are encouraged to explain how specific statistical techniques would be applied in their research. Applicants should further highlight ways that their proposed research might advance the use of statistics and data science, both in their physics subfield and potentially in other disciplines. If the work is part of a larger collaborative effort, the applicant should focus on their personal contributions.

For access to the selection form or for further information, please contact the IDSS Academic Office at  [email protected] .

Required Courses

Courses in this list that satisfy the Physics PhD degree requirements can count for both programs. Other similar or more advanced courses can count towards the “Computation & Statistics” and “Data Analysis” requirements, with permission from the program co-chairs. The IDS.190 requirement may be satisfied instead by IDS.955 Practical Experience in Data, Systems, and Society, if that experience exposes the student to a diverse set of topics in statistics and data science. Making this substitution requires permission from the program co-chairs prior to doing the practical experience.

• IDS.190 – Doctoral Seminar in Statistics and Data Science ( may be substituted by IDS.955 Practical Experience in Data, Systems and Society )
• 6.7700[J] Fundamentals of Probability or
• 18.675 – Theory of Probability
• 18.655 – Mathematical Statistics or
• 18.6501 – Fundamentals of Statistics or
• IDS.160[J] – Mathematical Statistics: A Non-Asymptotic Approach
• 6.C01/6.C51 – Modeling with Machine Learning: From Algorithms to Applications or
• 6.7810 Algorithms for Inference or
• 6.8610 (6.864) Advanced Natural Language Processing or
• 6.7900 (6.867) Machine Learning or
• 6.8710 (6.874) Computational Systems Biology: Deep Learning in the Life Sciences or
• 9.520[J] – Statistical Learning Theory and Applications or
• 16.940 – Numerical Methods for Stochastic Modeling and Inference or
• 18.337 – Numerical Computing and Interactive Software
• 8.316 – Data Science in Physics or
• 6.8300 (6.869) Advances in Computer Vision or
• 8.334 – Statistical Mechanics II or
• 8.371[J] – Quantum Information Science or
• 8.591[J] – Systems Biology or
• 8.592[J] – Statistical Physics in Biology or
• 8.942 – Cosmology or
• 9.583 – Functional MRI: Data Acquisition and Analysis or
• 16.456[J] – Biomedical Signal and Image Processing or
• 18.367 – Waves and Imaging or
• IDS.131[J] – Statistics, Computation, and Applications

Grade Policy

C, D, F, and O grades are unacceptable. Students should not earn more B grades than A grades, reflected by a PhysSDS GPA of ≥ 4.5. Students may be required to retake subjects graded B or lower, although generally one B grade will be tolerated.

Unless approved by the PhysSDS co-chairs, a minimum grade of B+ is required in all 12 unit courses, except IDS.190 (3 units) which requires a P grade.

Though not required, it is strongly encouraged for a member of the MIT  Statistics and Data Science Center (SDSC)  to serve on a student’s doctoral committee. This could be an SDSC member from the Physics department or from another field relevant to the proposed thesis research.

Thesis Proposal

All students must submit a thesis proposal using the standard Physics format. Dissertation research must involve the utilization of statistical methods in a substantial way.

PhysSDS Committee

• Jesse Thaler (co-chair)
• Mike Williams (co-chair)
• Isaac Chuang
• Janet Conrad
• William Detmold
• Philip Harris
• Jacqueline Hewitt
• Kiyoshi Masui
• Leonid Mirny
• Christoph Paus
• Phiala Shanahan
• Marin Soljačić
• Washington Taylor
• Max Tegmark

Can I satisfy the requirements with courses taken at Harvard?

Harvard CompSci 181 will count as the equivalent of MIT’s 6.867.  For the status of other courses, please contact the program co-chairs.

Can a course count both for the Physics degree requirements and the PhysSDS requirements?

Yes, this is possible, as long as the courses are already on the approved list of requirements. E.g. 8.592 can count as a breadth requirement for a NUPAX student as well as a Data Analysis requirement for the PhysSDS degree.

If I have previous experience in Probability and/or Statistics, can I test out of these requirements?

These courses are required by all of the IDPS degrees. They are meant to ensure that all students obtaining an IDPS degree share the same solid grounding in these fundamentals, and to help build a community of IDPS students across the various disciplines. Only in exceptional cases might it be possible to substitute more advanced courses in these areas.

Can I substitute a similar or more advanced course for the PhysSDS requirements?

Yes, this is possible for the “computation and statistics” and “data analysis” requirements, with permission of program co-chairs. Substitutions for the “probability” and “statistics” requirements will only be granted in exceptional cases.

For Spring 2021, the following course has been approved as a substitution for the “computation and statistics” requirement:   18.408 (Theoretical Foundations for Deep Learning) .

The following course has been approved as a substitution for the “data analysis” requirement:   6.481 (Introduction to Statistical Data Analysis) .

Can I apply for the PhysSDS degree in my last semester at MIT?

No, you must apply no later than your penultimate semester.

What does it mean to use statistical methods in a “substantial way” in one’s thesis?

The ideal case is that one’s thesis advances statistics research independent of the Physics applications. Advancing the use of statistical methods in one’s subfield of Physics would also qualify. Applying well-established statistical methods in one’s thesis could qualify, if the application is central to the Physics result. In all cases, we expect the student to demonstrate mastery of statistics and data science.

Graduate Program

Pushing the Scholarly Frontier

PhD in Political Science

Our doctoral students are advancing political science as a discipline. They explore the empirical phenomena that produce new scholarly insights—insights that improve the way governments and societies function. As a result, MIT Political Science graduates are sought after for top teaching and research positions in the U.S. and abroad. Read where program alumni are working around the world.

How the PhD program works

The MIT PhD in Political Science requires preparation in two of these major fields:

• American Politics
• Comparative Politics
• International Relations
• Models and Methods
• Political Economy
• Security Studies

We recommend that you take a broad array of courses across your two major fields. In some cases, a single course may overlap across the subject matter of both fields. You may not use more than one such course to "double count" for the course distribution requirement. Keep in mind that specific fields may have additional requirements.

You are free to take subjects in other departments across the Institute. Cross-registration arrangements also permit enrollment in subjects taught in the Graduate School of Arts and Sciences at Harvard University and in some of Harvard's other graduate schools.

Requirements

1. number of subjects.

You will need two full academic years of work to prepare for the general examinations and to meet other pre-dissertation requirements. Typically, a minimum of eight graduate subjects are required for a PhD.

2. Scope and Methods

This required one-semester seminar for first-year students introduces principles of empirical and theoretical analysis in political science.

3. Statistics

You must successfully complete at least one class in statistics.

You must successfully complete at least one class in empirical research methods.

5. Philosophy

You must successfully complete at least one class in political philosophy.

6. Foreign language or advanced statistics

You must demonstrate reading proficiency in one language other than English by successfully completing two semesters of intermediate-level coursework or an exam in that language, or you must demonstrate your knowledge of advanced statistics by successfully completing three semesters of coursework in advanced statistics. International students whose native language is not English are not subject to the language requirement.

7. Field research

We encourage you to conduct field research and to develop close working ties with faculty members engaged in major research activities.

8. Second Year Paper/workshop

You must complete an article-length research paper and related workshop in the spring semester of the second year. The second-year paper often develops into a dissertation project.

9. Two examinations

In each of your two elected fields, you must take a general written and oral examination. To prepare for these examinations, you should take at least three courses in each of the two fields, including the field seminar.

10. Doctoral thesis

As a rule, the doctoral thesis requires at least one year of original research and data collection. Writing the dissertation usually takes a substantially longer time. The thesis process includes a first and second colloquium and an oral defense. Be sure to consult the MIT Specifications for Thesis Preparation as well as the MIT Political Science Thesis Guidelines . Consult the MIT academic calendar to learn the due date for final submission of your defended, signed thesis.

Questions? Consult the MIT Political Science Departmental Handbook or a member of the staff in the MIT Political Science Graduate Office .

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Which program is right for you?

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Earn your MBA and SM in engineering with this transformative two-year program.

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Bring a business perspective to your technical and quantitative expertise with a bachelor’s degree in management, business analytics, or finance.

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This 20-month MBA program equips experienced executives to enhance their impact on their organizations and the world.

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Technological Innovation, Entrepreneurship, and Strategic Management

Technological Innovation, Entrepreneurship, and Strategic Management (TIES) embraces two areas: the organization, development, and commercialization of technology-based innovation in existing firms; and the formation, development, and growth of technology-based new enterprises. Students can integrate these areas in their studies or approach them as distinct elements.

For 40 years, MIT Sloan faculty and their graduate students have distinguished themselves with the breadth and depth of their managerial research and curriculum on all aspects of the management of research, development, technology-based innovation, and technological entrepreneurship. This group also initiated—and now runs—the  MIT Entrepreneurship Center . The E-Center, with its extensive multi-disciplinary curriculum and its wide-ranging program of student activities, also sponsors the nation's premier business plan competition, the  MIT $100K .

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The largest graduate program in MIT’s School of Engineering, EECS has about 700 graduate students in the doctoral program at any given time. Those students conduct groundbreaking research across a wide array of fields alongside world-class faculty and research staff, build lifelong mentorship relationships and drive progress in every sector touched by electrical engineering, computer science, and artificial intelligence and decision-making.

Ph.D./Sc.D. Program

The Doctor of Philosophy and Doctor of Science degrees in Chemical Engineering are identical; students may choose for themselves the appellation they prefer. This traditional, research-based doctoral degree program provides a thorough grounding in the fundamental principles of chemical engineering, as well as an intensive research experience.

The Doctor of Science and the Doctor of Philosophy in Chemical Engineering are identical degree programs. Degree candidates may choose to be called a “doctor of philosophy” or a “doctor of science”.

The degree requires that you complete:

• the core curriculum in chemical engineering
• one chemical engineering H Level class
• the departmental biology requirement
• a minor program of related subjects outside of chemical engineering
• written and oral doctoral qualifying examinations
• the writing and oral defense of a thesis on original research

The core curriculum is:

• Numerical Methods in Chemical Engineering 10.34
• Chemical Engineering Thermodynamics 10.40
• Analysis of Transport Phenomena 10.50
• Chemical Reactor Engineering 10.65

The departmental biology requirement is fulfilled by completing an undergraduate subject equivalent to MIT 7.01x, either at MIT or at your undergraduate institution. Examples of minor programs for some recent doctoral students include applied mathematics, control theory, physical, organic or analytical chemistry, mechanical structure, power systems, process metallurgy, nuclear engineering, management, economics, music, ancient history and philosophy.

The normal duration of the degree program is five to six years. (Including an intermediate M.S. CEP degree normally has little effect on the duration.) A master’s degree is not required for entrance into the doctoral program, nor is the M.S. CEP required.

For incoming, first-year graduate students, academic advisors are members of the Committee for Graduate Students. When you select a research topic and begin your thesis, the research supervisor becomes your academic advisor. In general, students choose research advisors at the end of their first Fall semester at MIT. Should you wish to choose a research advisor from a department other than Chemical Engineering, you will also need to choose a co-advisor from the Chemical Engineering faculty.

Prior to Registration Day (Fall and Spring semesters), your subject selection must first be approved by your advisor before the Graduate Officer can authorize registration on Registration Day. Advisor approval should also be obtained for any subsequent subject add/drop actions during the term (no additional authorization by the Graduate Officer is required).

Graduate Program

The Microbiology Graduate PhD Program is an MIT-wide program that is designed to provide students with broad exposure to modern areas of microbiology and depth in the chosen area of thesis work.

There are more than 50 faculty in 10 different departments and divisions that study microbes. Graduate students admitted to the program will join a vibrant, thriving microbiology community on the MIT campus and will receive training in a broad range of areas in microbiology.

The major components of the training program are described in in this section, along with information on life as a graduate student at MIT.

“Is the MIT Microbiology Graduate Program the right program for me?”

This is a question we often hear, especially if applicants are considering or applying to other departments within MIT.  As you can see from our website, we have over 60 faculty from over 10 different departments participating in the Microbiology Graduate Program.

One way to help you decide where best to apply is for you to determine whether all, or almost all, of the faculty in whose research you are interested are in one department.  If that is the case, applying to that individual department would be more appropriate.  If you are equally interested in faculty and labs from different departments, then a program like MIT Microbiology can provide you the flexibility to bridge different departments and disciplines, both in your coursework and your research.

PhD Building Technology

Phd computation, graduate programs.

Degree Requirements

See an overview of sa+p groups and chart of all degree programs.

Details below for each graduate program’s degree requirements:

• PhD- Building Technology
• PhD- Computation
• PhD- History and Theory of Architecture; and the History and Theory of Art

See MArch program overview

March curriculum chart.

Those who are admitted to MArch require 3½ academic years of residency to fulfill the degree requirements.

Faculty Advising

A faculty advisor with a design background will be assigned to each MArch student before the first term of registration. The advisor will monitor the student’s progress through completion of the degree. 

Subjects and Credit Units

The MArch is awarded upon satisfactory completion of an approved program of 282 graduate units and an acceptable 24-unit thesis for 306 total graduate credits.

Subjects required for the 3½-year program include the following:

• Six architectural design studios (3 core studios and 3 research studios)
• Geometric Disciplines and Architectural Skills I (4.105)
• One Computation restricted elective (4.117, 4.511, 4.521, or 4.567) 
• Three Building Technology subjects (4.464, 4.462, and 4.463)
• Architectural Assemblies (4.123)
• Precedents in Critical Practice (4.210)
• Professional Practice (4.222)
• Architecture from 1750 to the Present (4.645)
• One History, Theory and Criticism restricted elective (4.607, 4.612, 4.621, 4.647, 4.241, or 4.652)
• One History, Theory and Criticism elective
• One Computation/Media Lab elective (4.5xx or MAS.xxx)
• Urban Design elective (11.xxx)
• ACT elective (4.3xx)
• Three open elective subjects (or 24 total credits)
• Preparation for MArch Thesis (4.189)
• Graduate Design Thesis (4.ThG)

Credit for Previous Academic Work

MArch students who have successfully completed the equivalent of one or more required architecture subjects outside MIT (or within MIT as undergraduates) may be given advanced credit for those subjects by submitting a petition for curriculum adjustment with as much relevant material as possible (including a transcript, syllabi, reading lists, problem sets, paper assignments, or portfolios). Petitions are submitted to [email protected] before the first day of class each term and are then reviewed by the MArch Program Committee by the end of the first month of term. The Committee is composed of one faculty member from each of the discipline groups. Depending on the subject for which MIT credit is requested, students may substitute an elective in the discipline group or substitute a free elective. All requests must be resolved by the beginning of the student's penultimate semester. 

A single course at MIT must be specified for each petition (a Petition for Curriculum Adjustment cannot simply indicate “ACT Elective/4.3xx). However, a single petition may use several classes to map onto a single MIT course (i.e., Photography I and Fundamentals of Filmmaking at an undergraduate institution that together seem to cover what MIT's Introduction to Photography and Related Media course indicates).

Alternate Course Petitions

MArch students may submit a petition for an alternate course to be considered for required coursework (i.e., all non-Open Electives). Submit as much relevant material as possible (syllabi, reading lists, problem sets, paper assignments, or portfolios) to [email protected] before the first day of class each term. Please indicate the course title, number, credit units, and for which required course you are requesting the alternate course be substituted. These requests are then reviewed by the MArch Program Committee by the end of the first month of term. The Committee is composed of one faculty member from each of the discipline groups. All requests must be resolved by the beginning of the penultimate semester. *Note: Alternate Coursework Petitions asking for an Independent Study to count towards an elective will not be entertained.

Please note Restricted Electives (COMP: 4.117, 4.511, 4.521, or 4.567 and HTC: 4.241, 4.607, 4.612, 4.621, 4.647, or 4.652) may not be fulfilled by cross registration.

English Proficiency Requirement

An Institute-wide requirement, all students whose first language is not English are required to take the English Evaluation Test (EET) prior to registration at MIT. Even students who satisfy the International English Language Testing System (IELTS) or the Test of English as a Foreign Language (TOEFL) requirement for admission may be required to take specialized subjects in the English Language Studies Program  (ELS), depending on their EET results. These subjects do not count toward the required units, but will prove helpful to students who need to develop the skills necessary to write a thesis.

Faculty advisors may not waive these requirements for their advisees, and students may not defer registration in any English grammar review subject. They should take the courses within their first term or year. The most common results from the EET for Architecture students are to take the following two courses, and they must be taken in sequence:

• To be completed in the first term, for a letter grade only.
• To be completed in the second term; may be taken as optional P/D/F grading, but not as Listener status.

However, MArch students are exempted from the Advanced Writing Workshop course, due to the nature of their research and thesis work, unless otherwise flagged by their instructors and MArch faculty. Failure to take these required courses will result in an internal registration hold being placed on your account. 

Jumpstart  

MIT Architecture's Jumpstart is designed to prepare incoming MArch students for the rigors of the first design studio and to develop basic skills. The course is intended for students with little architectural studio experience but is also open to others who would benefit from introductory exposure to unfamiliar software. Jumpstart is created for our MArch student community by our MArch student community. This experience is taught through exercises that have been handed down from year to year and taught by our esteemed teaching fellows (recent graduates).

Policy on Incomplete Subjects and Thesis Semester

MArch students may have no more than one incomplete in a required subject when they register for thesis (4.THG). This incomplete can be no older than one term (received the term prior to thesis registration).

Students who have incompletes from several subjects or incompletes from earlier terms will be denied registration until those subjects are finished and graded. This policy applies to incompletes in subjects required by the degree curriculum or necessary for units toward the degree. 

Academic Audits

A chart indicating progress through the academic requirements will be maintained as part of each student’s file. The administrator of master’s degree programs will distribute this audit to students and to faculty advisors each term.

Thesis Preparation and Thesis

An MArch thesis at MIT operates as an independent thesis project, interrogating the discipline of architecture. The thesis is developed by the student and is supported by a committee of readers and an advisor. In the next-to-last term of registration (the semester prior to thesis), students enroll in Preparation for MArch Thesis (4.189). This course guides students towards declaring a thesis statement as well as forming the thesis committee. The result of this 9-unit subject is a thesis proposal.

The MArch thesis committee is composed of two members. The thesis advisor must be an eligible faculty member* of the Department of Architecture faculty with an architecture design background. Co-thesis supervision is permitted for dual degree students as long as one of the supervisors is a permanent member of the Department of Architecture faculty with an architecture design background. Download the Thesis Committee Guidelines here .

*A list of eligible faculty is available from the degree administrator.

MArch students are required to register for 24 units of thesis (4.THG) the final term. 

The thesis proposal, including a thesis proposal form signed by both thesis committee members, is due the first week of the term in which the student registers for thesis.

The MArch Thesis Review Schedule includes deadlines for proposal review, public mid-review, penultimate review, final review, and final thesis document.

The MArch degree is awarded after all the degree requirements have been met and the approved, archival-ready thesis has been submitted to the Department of Architecture by the Institute deadline for master’s theses as published in the MIT Academic Calendar . Students must adhere to the Specifications for Thesis Preparation published by the Institute Archives.

SMArchS degree requirement chart

The SMArchS degree may be pursued in one of six areas:

Architectural Design Urbanism Building Technology Design and Computation History Theory + Criticism Aga Khan Program in Islamic Architecture

With one of these areas as an intellectual home, students are encouraged to explore connections in their research across these areas, and beyond to other programs and departments throughout MIT. See the SMArchS degree requirement chart for information on the degree requirements for each of the six areas.

The minimum required residency for students enrolled in the SMArchS program is two full academic years, to be completed in four consecutive semesters of enrollment.

A faculty advisor from the Department of Architecture is assigned to each SMArchS student at matriculation. The advisor weighs in on the student's initial plan of study and on each subsequent term's choice of subjects. This individual should be a faculty member with whom the student is in close contact. The advisor monitors the student's progress through completion of the degree.

The SMArchS degree is awarded upon satisfactory completion of an approved program of at least 96 graduate units and an acceptable thesis. 

Students, with their advisors, construct individual programs of study focused on their particular interests. Individual areas have slightly different requirements. See below for more information. 

English Proficiency Requirement 

All students whose first language is not English are required to take the  English Evaluation Test (EET)  prior to registration at MIT. Even students who satisfy the International English Language Testing System (IELTS) or the Test of English as a Foreign Language (TOEFL) requirement for admission may be required to take specialized subjects in  the English Language Studies Program (ELS), depending on their EET results. These subjects do not count toward the required units but will prove helpful to students who need to develop the skills necessary to write a thesis.

Faculty advisors may not waive these requirements for their advisees, and students may not defer registration in any English grammar review subject. Students should take the courses within their first term or year. The most common result for Architecture students are to take either the following two courses or only the secondary course. When both are recommended, they must be taken in sequence:

• To be completed in the first term, for a letter grade only.
• To be completed in the second term; may be taken as optional P/D/F grading, but not as Listener status.

SMArchS students may have no more than one incomplete in a required subject when they register for thesis (4.THG). This incomplete can be no older than one term (received the term prior to thesis registration).

Students who have unresolved grades (incomplete, missing, or O/X) from several subjects or unresolved grades from earlier terms will be denied registration until those subjects are finished and graded. This  policy  applies to incompletes in subjects required by the degree curriculum or needed for units toward the degree as well as all O/X grades. 

SMArchS Thesis Preparation and Thesis Schedule

Thesis preparation.

Students enroll in Preparation for SMArchS Thesis (4.288) their third term of registration.

By Week 7, students finalize selecting a thesis advisor. The result of this 9-unit subject is a well-formulated thesis proposal and a department-scheduled presentation of the thesis proposal at the end of the term. By Week 14, students must submit an e/signed copy of the thesis proposal form and thesis proposal to the degree administrator for master's programs. Once the SMArchS Committee has approved the thesis proposals in consultation with the thesis advisor, students are permitted to register for thesis the following semester. Any student who is not able to produce an acceptable thesis proposal by the end of their penultimate term will be given until the end of IAP to produce a thesis proposal. If the proposal is still not acceptable, the student will be required to retake Preparation for SMArchS Thesis (4.288) their fourth term of registration.

The SMArchS thesis committee is composed of at least two and no more than three members. The thesis advisor must be permanent member of the Department of Architecture faculty. The first reader must be a permanent faculty member of the Department of Architecture or a related department at MIT. The optional third member (second reader) may be any member of the MIT faculty or research staff, an outside professional, or a faculty member from another institution.

Co-thesis supervision is permitted as long as one of the advisors in a permanent member of the Department of Architecture faculty.

SMArchS students who have an approved thesis proposal are required to register for 36 units of thesis (4.THG) in their fourth and final term.

During Week 7 (before Spring Vacation), each discipline area will schedule the thesis review for its students. At the review, students will submit a draft or prototype or complete conceptual design of the thesis to their thesis committee, and reviewers from across the discipline areas will attend the reviews. If a student's progress is not satisfactory, the student will not be permitted to present at the final review.

During Week 11, SMArchS students will submit one copy of the thesis book to their thesis committees and meet with their thesis committees to formally defend the thesis.

NOTE: The Week 11 defense is a penultimate review. Presenting at the Final Review is seen as a privilege, not a right. Faculty is under no compunction to pass inadequate work. If a student's work is found wanting, the student will not be allowed to present at the public final review. The committee may decide not to pass the thesis or, alternatively, pass it only after the student undertakes additional work to meet targets set by the committee (on a date agreed on by the latter). An extension beyond the academic year will only be granted in response to a written petition by the student concerned. The petition must be addressed to the SMArchS Committee, upon which the committee will reach a decision in consultation with the thesis advisor.

By Week 14, students will submit a digital copy of the final approved, archival-ready thesis to the  Department of Architecture thesis portal. Consult the SMArchS Degree Administrator to confirm the thesis submission deadline, which is prior to the Institute deadline for master's theses as published in the MIT Academic Calendar.  Students must adhere to the Specifications for Thesis Preparation published by the Institute Archives.

The SMArchS thesis final presentations are scheduled by the Department during the last week of the term (Week 15). These presentations, also known as Final Reviews, are made to the Department of Architecture community, faculty, students, and invited external reviewers.

The SMArchS degree is awarded after all the degree requirements have been met and after the approved, archival-ready thesis has been submitted to and approved by the headquarters of the Department of Architecture.

SMArchS Design

The SMArchS Design degree is awarded upon satisfactory completion of an approved program of at least 96 graduate units and an acceptable thesis. 

Students, with their advisors, construct individual programs of study focused on their particular interests. Subjects that must be taken include the following:

• 4.221, Architecture Studies Colloquium (1st term) 
• 4.130, Architecture Design Theory and Methodologies (1st term)
• Six subjects within the student’s area of interest
• Thesis Preparation: 4.288, Preparation for SMArchS Thesis (12 units, 2nd term)
• Thesis: 4.THG, Graduate Thesis (final term)

SMArchS Urbanism

The SMArchS Urbanism degree is awarded upon satisfactory completion of an approved program of at least 96 graduate units and an acceptable thesis. 

• 4.228, Contemporary Urbanism Proseminar: Theory and Representation (1st term) 
• 4.163J, Urban Design Studio (1st term)
• In Urbanism, two of these subjects must be 4.241J, The Making of Cities, and one approved Option Design Studio or a second 4.163J, Urban Design Studio
• Pre-Thesis Preparation: 4.286, SMArchS-URB Pre-Thesis Preparation (2nd term)
• Thesis Preparation: 4.288, Preparation for SMArchS Thesis (9 units, 3rd term) 
• Thesis: Graduate Thesis, 4.THG (final term)

SMArchS Building Technology

The SMArchS Building Technology degree is awarded upon satisfactory completion of an approved program of at least 96 graduate units and an acceptable thesis. 

• 4.481, Building Technology Seminar (1st term)
• Thesis Preparation: 4.288, Preparation for SMArchS Thesis (9 units, 3rd term) 

SMArchS Computation

The SMArchS Computation degree is awarded upon satisfactory completion of an approved program of at least 96 graduate units and an acceptable thesis. 

• 4.580, Inquiry into Computation and Design (1st term)
• Pre-Thesis Preparation: 4.587, SMArchS-COMP Pre-Thesis Preparation (2nd term)
• Thesis Preparation: 4.588, Preparation for SMArchS COMP Thesis (3rd term) 

SMArchS HTC / AKPIA

The SMArchS History Theory + Criticism degree is awarded upon satisfactory completion of an approved program of at least 96 graduate units and an acceptable thesis. 

• 4.661, Theory and Method in the Study of Architecture + Art (HTC students are required to take this subject both fall terms of their residency, 1st & 3rd terms) 
• Pre-Thesis Preparation: 4.688, SMArchS-HTC Pre-Thesis Preparation (2nd term)

The SMArchS Aga Khan Program for Islamic Architecture degree is awarded upon satisfactory completion of an approved program of at least 96 graduate units and an acceptable thesis. 

• 4.619, Historiography of Islamic Art + Architecture
• 4.621, Orientalism, Colonialism + Representation
• in AKPIA, one of these subjects must be 4.612, Islamic Architecture + the Environment 
• Pre-Thesis Preparation: 4.686, SMArchS-AKPIA Pre-Thesis Preparation (2nd term)
• 4.THG, Graduate Thesis (final term)

See SMACT program overview

Smact degree requirements.

The minimum required residency for students enrolled in the SMACT program is two academic years. SMACT students do not register for summer term.

A faculty advisor from the Art, Culture and Technology Program is assigned to each SMACT student at matriculation. The advisor will consult on the student's initial plan of study and on each subsequent term's choice of subjects. This individual should be a faculty member with whom the student is in close contact; changes in advisor may be made to make this possible. The advisor monitors the student's progress through completion of the degree.

A minimum of 135 units of graduate-level coursework is required, not including thesis. Subjects to be taken:

• 4.390 Art, Culture and Technology Studio is taken each of the four terms of enrollment in the program 
• Two ACT graduate subjects, one of which must be taken with an ACT core faculty member
• Two elective subjects that support student's area of study
• 4.387, SMACT Theory & Criticism Colloquium, taken during first term
• 4.388, SMACT Thesis Preparation, taken during second term
• 4.389 SMACT Thesis Tutorial, taken during third term
• 4.THG, Thesis (registration for thesis), taken during fourth term

Art, Culture and Technology Studio

Art, Culture and Technology Studio (4.390) is restricted to SMACT degree students and serves as the core of the curriculum. It is coordinated by an ACT faculty member and involves the participation of all faculty currently advising SMACT candidates. Students are expected to participate in all class meetings. Attendance at the ACT Lecture Series and other ACT events is expected.

SMACT Thesis

For requirements, timeline, and updates, please visit the ArchThesis Website .

See SMBT program overview

Smbt requirements form.

The minimum required residency for students enrolled in the SMBT program is three terms, one of which may be a summer term. However, many take two academic years to complete all the requirements.

Each student in Building Technology is assigned a faculty advisor at matriculation. The advisor weighs in on the student's initial plan of study and on each subsequent term's choice of subjects. This individual should be a faculty member with whom the student is in close contact; changes can be made to make this possible. The advisor monitors the student's progress through completion of the degree.

A Report of Completed SMBT Requirements form is kept by the degree administrator in the headquarters of the Department of Architecture. It is the student's responsibility to work with the thesis advisor to keep this report updated and on file.

A minimum of 66 units of graduate-level coursework is required. Credit received for thesis (4.THG) registration does not count toward this minimum.

Subjects to be taken include the following:

• 4.481, Building Technology Seminar, taken in the fall of the first year of registration. It is expected that the thesis proposal will be a product of this subject.
• 2 subjects in a single field of specialization (major), chosen from thermal science, structures, materials, controls, lighting, or systems analysis.
• 1 subject from another field of specialization (minor) in Building Technology. Other fields may also be accepted for specialization with advisor approval.
• 1 subject in applied mathematics.
• Thesis registration, 4.THG, is allowed only if the thesis proposal has been approved and the Report of Completed SMBT Requirements has been submitted.

A thesis is required for the SMBT degree. The topic is selected from a subject currently being investigated by the faculty, and research is carried out under the direct supervision of a faculty member in the program. This faculty member will be the student's advisor and must approve the thesis proposal prior to thesis registration. Thesis readers are optional.

The SMBT is awarded after a digital copy of the defended, approved, archival-ready thesis has been submitted to Department of Architecture headquarters by the Institute deadline for master's theses as published in the MIT Academic Calendar. Students must adhere to the Specification for Thesis Preparation published by the Institute Archives.

All students whose first language is not English are required to take the English Evaluation Test (EET) prior to registration at MIT. Even students who satisfy the Test of English as a Foreign Language (TOEFL) requirement for admission may be required to take specialized subjects in  the English Language Studies Program (ELS), depending on their EET results. These subjects do not count toward the required units, but will prove helpful to students who need to develop the skills necessary to write a thesis.

Faculty advisors may not waive these requirements for their advisees, and students may not defer registration in any English grammar review subject. They should take the courses within their first term or year. The most common result for Architecture students are to take either the following two courses, or only the secondary course. When both are recommended, they must be taken in sequence:

See BT/PhD program overview

Bt/phd requirements.

It is the student's responsibility to fill out the appropriate section of the Report of Completed BT/PhD Requirements upon completion of the requirements listed below. This document is submitted to the degree administrator and kept in the student's official departmental file. The degree administrator informs the MIT registrar when the degree requirements have been fulfilled.

Qualifying Paper

The qualifying paper, which often emerges from the Building Technology Seminar (4.481), should demonstrate the student's potential for work at a high standard of scholarship. The paper must be completed and accepted by the dissertation committee before a student can continue to the general examination. Insufficiencies in the qualifying paper may require remedial subject work on the part of the student.

Dissertation Proposal

The PhD dissertation is a major work that makes an original scholarly contribution to the field of investigation. Most BT/PhD dissertation research will be a portion of a sponsored research project. The dissertation is the main focus of the doctoral program and the primary indicator of a PhD student's ability to carry out significant independent research. The Building Technology dissertation must result in advances in the state of the art that are worthy of publication in a respected technical journal in the field.

Approval of the dissertation topic is gained through a proposal submitted to the dissertation committee no later than the end of the second term of registration. Once the proposal has been approved, the student may register for Graduate Thesis (4.THG).

Coursework: Major and Minor Fields

Coursework is selected in consultation with the faculty advisor. A normal registration load is 36 units, which would be a combination of specific subjects and research. Though the core group of subjects will be within the department, students are encouraged to take outside subjects. Building Technology Seminar (4.481) is the only specific subject required for the degree and is taken during the student's first term. Typically a student's program will include at least five graduate subjects in the major field and three in the minor field. Preparation for Building Technology PhD Thesis (4.489) is used as registration for research until the dissertation proposal has been approved. After that point, Graduate Thesis (4.THG) is used as registration for research.

General Examination

The purpose of the qualifying examination is to determine whether the student possesses the attributes of a doctoral candidate: mastery of the disciplines of importance to building technology and ingenuity and skill in identifying and solving unfamiliar problems. The examination consists of two parts. (1) A demonstration of mastery in three areas through coursework and (2) a presentation of research as explained below.

Subject Area Mastery Allowable subjects are listed in Discipline areas for the Building Technology PhD General Exam / Record of subject mastery . To pass the subject area mastery portion of the doctoral general exam, students must earn three As and one B (or four As) in at least four subjects chosen across three of the seven areas from Table 1. Substitutions of subjects not included in the table will be considered on a case-by-case basis and will require approval from all BT faculty.

Research Presentation The research presentation exam will take place over 120 minutes, and should include a 45 minute formal presentation by the doctoral student, followed by 45-60 minutes of questions and discussion with all BT faculty. The research presented should be ongoing research or recently completed research carried out in Building Technology. The presentation should put the work in context, present research findings and propose future work. It will be evaluated both for intellectual content and for clarity of communication. The discussion portion of the exam led by BT faculty may cover both the presented work specifically as well as a broader range of related topics to gauge the student's familiarity with their research content.

Logistics   Examinations are offered in January (last week of IAP) and May (the week after final exams). Students must obtain permission of their advisor to take the exam. In case a student is working on a multidisciplinary research topic with a significant component falling outside the expertise of any BT faculty, an expert (ideally MIT faculty) representing the topic area should participate in the general exam. The advisor will invite this expert in consultation with the student. All students must complete the coursework and research presentation portions of the exam by the end of their fourth semester in the PhD program. Advisors of PhD students will submit to the BT faculty the proposed plan for coursework completion for each of their advisees at least three months before the research presentation. Students who do not pass may be invited to retake certain subjects or repeat the research presentation, or they may be asked to terminate their enrollment in the PhD program.

Dissertation Defense

A dissertation committee of three or more people, generally assembled in the first semester of registration, supervises research and writing of the dissertation. The student's advisor is always a member of the dissertation committee and typically serves as its chair. The chair must be a member of the Building Technology faculty. In special circumstances, one of the three members of the dissertation committee may be selected from outside the Department of Architecture. The student is responsible for arranging meetings with the committee at least once each term.

A final draft of the completed dissertation must be delivered to each committee member one month prior to the scheduled defense. The dissertation is presented orally in an open meeting of the faculty of the department; at least three faculty members must be present. After the presentation, the dissertation is either accepted or rejected.

The PhD is awarded after two copies of the defended, approved, archival-ready dissertation have been submitted to the Department of Architecture at its headquarters. The copies must be submitted by the Institute deadline for doctoral theses as published in the MIT Academic Calendar . Students must adhere to the Specifications for Thesis Preparation published by the Institute Archives.

Nonresident Research Status

Students are expected to carry out thesis research while in residence at the Institute. It is rare that a PhD candidate in BT will need to apply for nonresident status. However, should a student who has completed all requirements except for the dissertation need to continue thesis research in years beyond the awarded funding, he or she may opt to apply for nonresident research status with the permission of the dissertation advisor.

All students whose first language is not English are required to take the English Evaluation Test (EET) prior to registration at MIT. Even students who satisfy the International English Language Testing System (IELTS) or Test of English as a Foreign Language requirement for admission may be required to take specialized subjects in  the English Language Studies Program (ELS), depending on their EET results. These subjects do not count toward the required units, but will prove helpful to students who need to develop the skills necessary to write a dissertation.

See Computation/PhD program overview

Computation/phd requirements.

It is the student's responsibility to fill out the appropriate section of the Report of Completed Computation/PhD Requirements upon completion of the requirements listed below. This document is submitted to the degree administrator and kept in the student's official departmental file. The degree administrator informs the MIT registrar that the degree requirements have been fulfilled.

Subject Work

PhD Students are expected to complete at 144 units of subject work while in residency at MIT. This is usually accomplished over two years by enrolling in an average of 36 units per term, which equals three or four subjects per term. In those special cases where the student is awarded advanced standing at admission, the unit requirement is lowered accordingly. The only specific subject requirement is 4.581 Proseminar in Computation. All other subjects are selected in consultation with the faculty advisor and may be taken both in and out of the Department of Architecture. Registration in 4.THG, Graduate Thesis, does not count toward the 144-unit requirement.

PhD students in Computation are expected to enroll in 4.581, Proseminar in Computation, during their first year in residence. The Proseminar is meant to provide a rigorous grounding in the field with a focus on specific research topics related to architecture and design practice.

Major and Minor Fields

Major and minor fields must be approved by the student's advisory committee, which is selected with the assistance of the advisor in the first year of enrollment. Normally, the minor field requirement will be satisfied by outstanding performance in three related subjects (not less than 27 units). The major field requirement is satisfied upon successful completion of the general examination.

The general examination is given after required subject work is completed and is taken no later than the third year of residency. The general examination is meant to show broad and detailed competence in the student's major field of concentration and supporting areas of study. The content and format of the general examination are decided by the student's advisory committee in consultation with the student. The committee evaluates the examination upon completion and may 1) accept the examination, 2) ask for further evidence of competence, or 3) determine that the examination has not been passed. In the event that the general examination is not passed, the committee may allow the student to repeat the examination or may recommend that the student withdraw from the PhD program.

The PhD dissertation is a major work that makes an original scholarly contribution. It is the main focus of the doctoral program in Design and Computation, and it serves as the primary indicator of a PhD student's ability to carry out significant independent research.

The dissertation committee comprises a minimum of three members — one thesis advisor, who also serves as the dissertation committee chair, and two readers. The chair must be a permanent member of the Computation faculty and the student's advisor. The first reader must be a permanent faculty member of MIT. The second reader may come from Computation or may be a faculty member appointed from outside the department or the Institute. Students may add more members in consultation with their advisor. The student is responsible for arranging meetings with the committee members on a regular basis.

Formal approval of the dissertation topic is gained through a proposal, which the student submits and defends to his or her dissertation committee prior to the completion of the sixth semester of registration. The proposal should contain these elements:

• General statement of scope of the thesis
• Significance of the thesis
• Survey of existing research and literature with critical comments and an assessment of the extent to which this material will be utilized
• Method of the thesis work
• Outline or brief sketch of the thesis
• Working bibliography
• Resources for primary material
• Plan of work, including a timetable

An oral examination in which the candidate meets with the dissertation committee to discuss the proposal marks the formal acceptance of the topic. The result of the defense can be that the thesis proposal is accepted, accepted with revisions or rejected.

Students will often register for Preparation for Computation PhD Thesis (4.589) in the term leading up to their proposal defense. Once the proposal has been approved, the student may register for 4.THG, Graduate Thesis. The student may be asked to present his or her dissertation proposal in the class Research Seminar in Computation (4.582).

Students are advised to meet with committee members to obtain comments and guidance throughout the writing phase of the project. Regular contact with committee members during the process of drafting the thesis can ensure a student's readiness for thesis defense. The final draft should be submitted to committee members at least one month prior to the defense. The defense should be scheduled at least two weeks prior to the published Institute PhD thesis deadline.

The dissertation is defended by oral presentation in front of the dissertation committee. At least three faculty members must be present. If a member of the committee is not able to attend, he or she must contact the committee chair with comments and questions. That member must also inform the committee chair of a vote.

The result of the defense can be that the thesis is accepted, accepted with revisions or rejected. If the thesis is accepted with revisions, the student makes the necessary changes to the document and submits them within an agreed time frame to all or some of the committee members. If rejected, the student must re-defend according to a timetable agreed upon at the defense.

The PhD is awarded after a PDF copy of the defended, approved, archival-ready dissertation has been submitted to the Department of Architecture through the Thesis Submission Portal . The copy must be submitted by the Department  deadline for theses as published on the archthesis website . Students must adhere to the Specifications for Thesis Preparation published by the Institute Archives.

Students are expected to carry out thesis research while in residence at MIT. It is rare that a PhD candidate in Design and Computation will need to apply for nonresident status. However, should a student who has completed all requirements except for the dissertation need to continue thesis research in years beyond the awarded funding, he or she may opt to apply for nonresident research status with the permission of the dissertation advisor.

All students whose first language is not English are required to take the English Evaluation Test (EET) prior to registration at MIT. Even students who satisfy the International English Language Testing System (IELTS) or Test of English as a Foreign Language (TOEFL) requirement for admission may be required to take specialized subjects in the English Language Studies Program (ELS), depending on their EET results. These subjects do not count toward the required units, but will prove helpful to students who need to develop the skills necessary to write a dissertation.

See HTC/ PhD program overview

PhD students complete 204 units (not including registration in 4.THG) during their residency at MIT. This is usually accomplished over the first three years of residency by enrolling in an average of 36 units per term, the equivalent of three subjects. The breakdown of required subjects is as follows:

• 4.661, Methods Seminar, is taken each fall term for first two years—2 x 12 = 24 units
• Nine subjects completed by the end of the second year: lecture, seminar and/or independent study—9 x 12 = 108 units
• 4.684 Preparation for HTC Major Exam = 27 units; taken in the 5th semester
• 4.685 Preparation for HTC Minor Exam = 15 units; taken in the 4th semester
• 4.689 Preparation for HTC PhD Thesis = 27 units; taken in the 6th semester

Independent study subjects may be taken with advisor approval after the first year of residency. No more than one independent study project may be taken per term, and no more than 12 units may be devoted to any one research project. Registration for an independent study project requires completion of a departmental  Independent Study Project  form, this constitutes a contract for the deadlines and deliverables for the subject and the definition of supervisory involvement.

Advancement to Candidacy

A student is advanced to doctoral candidacy upon completion of the following “hurdles,” which should be completed by the end of the third year 

• General exam: major field—register for 4.684 (27 credit units)
• General exam: minor field—register for 4.685 (15 credit units)
• Language requirement
• Dissertation proposal—register for 4.689 (15 credit units)

Students are responsible for planning their hurdles in consultation with their advisor in a timely manner, in order to complete degree requirements by the end of semester 6 or the third year. The planner is submitted in the fall of the second year, with updates as needed. The sequence of hurdles completion is determined by the student in consultation with his/her advisor.  All pre-thesis requirements* must be completed and approved by the end of the third year. Failure to complete pre-thesis requirements by the end of the third year (term 7) may result in recommended or required withdrawal from the program.  When the Dissertation Proposal/Prospectus is filed, with all other hurdles completed, the student may enroll in “Thesis,” 4.THG.

Copies of each hurdle are submitted to HTC Staff for filing and completion. The HTC faculty meet at the end of each semester to review student progress in general and advance students to ABD candidacy status. . The degree administrator communicates with the Registrar when degree requirements have been fulfilled, and allows the Institute to certify candidacy.

General Examination: Major and Minor Fields

The fields of examination are set by mutual agreement between the student and their advisor. The purpose is to demonstrate the breadth and depth of the student's critical awareness of the discipline in which he or she works. Most universities, research institutions and other potential employers require assurance that a graduate has areas of competency beyond his or her specialization.

It is strongly recommended that work on the minor exam be completed in three months. The minor exam may cover a different time period from the major exam, or it may have a theoretical focus that complements the historical focus of the major exam, or it may cover in depth a topic within the broader field covered in the major exam. The minor exam may be a three-hour written test, or it may consist of preparing materials for a subject: specifically, a detailed syllabus, a bibliography, an introductory lecture and at least one other lecture. Register for 15 credit units of 4.685 the term in which the minor is completed (the fourth term). 

It is strongly recommended that work on the major exam be completed in three months. The major exam is a three-hour written test covering a historically broad area of interest that includes components of history, historiography and theory. Preparation for the exam will focus on four or five themes agreed upon in advance. Register for 27 credit units of 4.684 during the term in which the major is completed (the fifth term).

Although it is possible for one professor to supervise both exams, such an arrangement limits the student's collaboration with the faculty. With approval, a faculty member outside HTC may administer one of the exams. In this case, an HTC faculty member will also read the exam and submit the grade.

Topics and examiners for the Major and Minor exams should be finalized no later than the fourth semester. 

Language Requirement

It is recommended that students complete their language requirement by the end of the fourth semester.  Because of the foundational role French and German have played in the discipline of art and architectural history and theory, successful study or testing in these two languages constitutes the usual fulfillment of this requirement. For students working on topics for which there is another primary language, a substitution may be approved by the advisor. The MIT Global Studies and Languages department administers graduate language examinations.

The language exam can only be waived under the following circumstances:

• The student is a native speaker of the language needed
• Two years (or four semesters) of university courses have been completed for a language not administered by the language department, and a “B” or better average grade was maintained

Credits accumulated from language subjects taken to fulfill this requirement cannot be used toward the 204 credits of coursework required for the degree.

A dissertation advisor should be selected by the end of the fourth semester.  During the sixth semester, the Dissertation Topic will be presented to students and faculty colleagues.  It is estimated that the writing and revision of the proposal should take no more than four months. 

Following the Thesis Topic Presentation in the sixth semester, an appropriate dissertation committee should be proposed by the student and approved in principle by the advisor. (The committee may be changed with the approval of the advisor up to the eighth semester.) The  dissertation committee  comprises a minimum of three members; two must be MIT Department of Architecture faculty members, and the chair a member of the HTC faculty (and the student's main advisor). The third member may come from HTC or appointed from outside the department or outside the Institute. Students may add additional members in consultation with their advisor. 

The dissertation proposal should be drafted and defended by the end of the sixth semester.  Formal approval of the dissertation topic is gained through a proposal, which the student submits and defends to his or her dissertation committee prior to the end of the sixth semester of registration. The student is strongly advised to have an informal meeting of the committee some weeks prior to the formal defense, to reach a consensus that the thesis topic is of the right scale and the prospectus itself is ready to be defended. Register for 15 credit units of 4.689 the term in which the dissertation proposal is submitted.

A dissertation proposal (also called a prospectus) should contain the following elements:

• General thesis statement
• Scope, significance or “stakes” of the thesis
• Method of the thesis work 
• Outline or brief sketch of the dissertation, e.g. summaries of proposed chapters
• Archives and proof of access; IRB approval if required
• Plan of work, and may include a timetable

The formal defense of the prospectus consists of an oral examination in which the candidate meets with the dissertation committee; the committee decides whether the prospectus is approved as is, requires further revision, or does not pass the defense.

When the approved proposal is filed with the HTC administrator in acknowledgment of successful completion, the dissertation topic and proposal are approved, advancing the student to candidacy. At this point, the student registers for 4.THG, Graduate Thesis. 

Regular contact with committee members during the process of drafting the thesis can ensure a student's readiness for the final thesis defense. Students are advised to meet with committee members to obtain comments and guidance throughout the writing phase of the project. The final draft should be submitted to committee members  no later than one month prior to the defense.  The defense cannot be scheduled any later than two weeks prior to the published Institute PhD thesis deadline.

The dissertation is defended in the presence of the full dissertation committee. If a member of the committee is not able to attend or participate by virtual means, he or she must contact the committee chair with comments and questions. That member should also inform the committee chair of a vote.

The result of the defense is either accepted, accepted with revisions or rejected. If the thesis is accepted with revisions, the student makes necessary changes to the document and submits them within an agreed time frame to committee members, as determined at the defense meeting. If rejected, the student will re-defend to the committee in a timely manner.   Students are strongly advised to set a defense date three months in advance of the deadline to allow for revisions by the committee.

The PhD is awarded upon submission of the defended, approved, archival-ready dissertation to the Department of Architecture, via the PhD Academic Administrator. The final dissertation is submitted by the Institute deadline for doctoral theses as published in the MIT Academic Calendar. The final document conforms with Specifications for Thesis Preparation published by the Institute Archives.

Thesis Research in Absentia

Acceptance into the program is granted with the presumption that students will remain in residence at the Institute during their degree. However, on occasion, work outside the Institute may be essential to gather archival or other materials. Students who have completed all requirements apart from the dissertation may apply to take one or occasionally two semesters in absentia. A proposal for  thesis in absentia , which outlines work to be accomplished, should be delivered to the director and administrator in HTC no later than the drop date of the semester prior to the one in which the student plans to be away. The student should consult with the Academic Programs Manager in Headquarters as well as HTC staff for a review of the financial and academic implications of TIA status. The HTC faculty, the Department, and the dean of the graduate school grant approval.  Students must return to regular registration status for the final term the dissertation is submitted for their degree.  However, the dissertation draft may be submitted to the student’s primary advisor and committee members at any time during the TIA period. Similarly, the defense may be scheduled at any time (as long as the committee has at least 4 weeks to read the full and final draft). Regular registration status is required in order to file the final archival copy for the degree. Students are required to apply for the degree in Websis during the term prior to degree completion.

Graduate Thesis

The thesis comprises an original investigation, including a written report in English, on a subject approved by the Department of Architecture in advance. The Institute requires that each graduate student research and write an individual thesis and submit a final digital copy to the Institute as a permanent record. In order for a degree to be awarded, the department must receive the thesis in accordance with the Specifications for Thesis Preparation published by the MIT Libraries Institute Archives. Please refer to  archthesis.mit.edu  for timelines, specifications, and other useful information.

Thesis work in all master's degree programs in the Department of Architecture extends over two to three terms. Thesis work in doctoral programs extends over four to six terms. Registration for thesis and pre-thesis subjects differs by degree program.

The thesis process begins with one or more terms of thesis preparation and ends with one or more terms of thesis. Thesis registration (4.THG) for all programs begins once the thesis supervisor and/or committee have approved the thesis proposal. An integral element to a successful thesis lies in choosing an appropriate thesis committee. The  Thesis Committee Guidelines  document (updated January 2024) addresses the composition of a thesis committee for each degree program.

The objective of registering for thesis preparation is to produce an acceptable thesis proposal. Students in every degree program register for the thesis preparation subject(s) specific to their program.

MArch Program

• 4.189, Preparation for MArch Thesis , graded A-F, 9 units, taken the penultimate semester of the program.

SMArchS Program

• 4.288, Preparation for SMArchS Thesis , graded P/D/F, 9–12 units, is taken the second semester of the program for students in Design, and in the third semester of the program for students in Urbanism as a coordinated class with regular meeting times. Students in all other areas (BT, HTC, & AKPIA) take 4.288 as an independent study subject graded by the registration advisor.
• 4.587, SMArchS Computation Pre-Thesis Preparation , graded P/D/F, 6 units, taken in the second semester of the program for students in the Computation area.
• 4.588, Preparation for SMArchS Thesis - Computation , graded P/D/F, 6 units, taken in the third semester of the program for students in the Computation area. 
• 4.686 SMArchS AKPIA Pre-Thesis Preparation , graded P/D/F, 3 units, taken in the second semester of the program for students in the AKPIA area.
• 4.687 SMArchS HTC Pre-Thesis Preparation , graded P/D/F, 3 units, taken in the second semester of the program for students in the HTC area.

SMACT Program

• 4.388, Preparation for SMACT Thesis , graded A-F, 9 units, taken in the second semester of the program. Thesis Preparation will develop a proposal for the written thesis. A ten-page thesis proposal is the final project of this class.
• 4.389, SMACT Thesis Tutorial , graded A-F, 9 units, taken in the fourth semester to support the writing of the thesis book.
• SMACT students will submit a twenty-page thesis outline, select their thesis committee, and submit a SMACT Thesis Proposal Completion form by the end of their third term. These must be submitted to the ACT administrative offices for distribution to ACT faculty, by May 1.

SMBT Program

• 4.481, Building Technology Seminar , graded P/D/F, 3 units. All SMBT students are required to register for 4.481 during the first term of the program. The thesis proposal is expected to be a product of this seminar, but the student may register for 4.488 to complete the proposal.
• 4.488, Preparation for SMBT Thesis , graded P/D/F, variable units. 4.488 is an independent study subject graded by the thesis advisor and taken the second term of the program, if necessary to complete the thesis proposal.

Dissertation and Doctoral Programs

• 4.481, Building Technology Seminar , graded P/D/F, 3 H-level units. All BT/PhD students must register for 4.481 during the first term of the program. The thesis proposal is expected to be a product of this seminar, but the student may register for 4.489 to complete the proposal.
• 4.489, Preparation for Building Technology PhD Thesis , graded P/D/F, variable units. This is an independent study subject graded by the thesis advisor and taken the second and third term of the program, if necessary to complete the thesis proposal.
• 4.589, Preparation for Design and Computation PhD Thesis , graded P/D/F, variable units. An optional independent study subject graded by the thesis advisor and generally taken after coursework is completed. 4.589 is taken as preparation for the general examination and/or the dissertation proposal.
• 4.683, Preparation for HTC Qualifying Paper , graded P/D/F, variable units. Required of HTC PhD students as a prerequisite for work on the doctoral dissertation. The qualifying paper is a scholarly article fit to be published in a peer-reviewed journal that is the result of research in the history, theory and criticism of architecture and art. Topic may not be in the area of the proposed thesis. Work is done in consultation with HTC faculty, in accordance with the HTC PhD Degree Program Guidelines.
• 4.684, Preparation for HTC Major Exam , graded P/D/F, variable units. This is required of HTC PhD students as a prerequisite for work on the doctoral dissertation. The Major Exam covers a historically broad area of interest and includes components of history, historiography, and theory. Preparation for the exam will focus on four or five themes agreed upon in advance by the student and the examiner, and are defined by their area of teaching interest. Work is done in consultation with HTC faculty, in accordance with the HTC PhD Degree Program Guidelines.
• 4.685, Preparation for HTC Minor Exam , graded P/D/F, variable units. This is required of HTC PhD students as a prerequisite for work on the doctoral dissertation. The Minor Exam focuses on a specific area of specialization through which the student might develop their particular zone of expertise. Work is done in consultation with HTC faculty, in accordance with the HTC PhD Degree Program Guidelines.
• 4.689, Preparation for History, Theory and Criticism PhD Thesis , graded P/D/F, variable units. This is required of HTC PhD students as a prerequisite for work on the doctoral dissertation. Prior to candidacy, doctoral students are required to write and orally defend a proposal laying out the scope of their thesis, its significance, a survey of existing research and literature, the methods of research to be adopted, a bibliography and plan of work. Work is done in consultation with HTC faculty, in accordance with the HTC PhD Degree Program Guidelines. Students in this program do not register for thesis (4.THG) until all requirements except thesis have been completed.

Thesis Registration—4.THG

Once the thesis proposal is approved and the degree administrators have been notified, students register for thesis and continue to do so each term until graduation. Students who do not have an approved thesis proposal may not register for thesis. The number of units varies by degree program (upon submission of the thesis, 12 units of the grade awarded for 4.THG are entered into the student's cumulative grade point average).

MArch students Register for 24 units of 4.THG. Except for architectural design studio, other subjects needed to complete the degree requirements may be taken simultaneously. The e/signed Thesis Proposal form is due by 8:59am the first Friday of a student's final term. Several reviews of student work lead to the final thesis.

•  Proposal Review—Week 2
•  Mid-Review—Week 7 or 8
•  Penultimate Review—Week 10
•  Final Review—Week 15

SMArchS  students register for 36 units of 4.THG in their fourth and final term. All subjects needed to complete the degree (except architecture design studio) may be taken simultaneously. The e/signed SMArchS Thesis Proposal form is due to [email protected] by 8:59am the Drop Date of a student's penultimate term. The penultimate semester, a Preliminary Thesis Review is held during Reading Period. These Preliminary Reviews serve as an opportunity for SMArchs students to present a summary of their proposed Thesis Projects in a forum where thesis ideas can gain exposure and feedback from faculty and peers. The final semester, three major reviews of the student's thesis work are held with the advisor(s) and all readers — the first, in Week 7, is scheduled by the discipline area, the second is scheduled by the student with the entire thesis committee for a formal thesis defense in Week 11, and the public final review in Week 14. The department degree administrator schedules final reviews during Reading Period.

SMBT  students register for 4.THG upon approval of the thesis proposal and continue to do so each term until graduation. Units will vary according to the number of other subjects being taken. A normal course load for a term is not more than 48 credit units. SMBT students are expected to schedule a Content Review directly with the thesis advisor to take place near the end of the final term. At this point the thesis should be substantially complete; the Content Review marks the point at which the student may turn to production of the final thesis.

SMACT  students register for 24 units of 4.THG in their fourth and final term. Thesis is taken in conjunction with 4.390, Art, Culture, and Technology Studio, which is taken each term, and 4.389, SMACT Thesis Tutorial, which is taken the final two terms. Thesis reviews are scheduled within the forum of 4.390, which is restricted to SMACT students.

PhD  students register for 36 units of 4.THG for terms in which they are resident and not taking other subjects. Students who have been granted nonresident status register for 36 units of 4.THG only (nonresident status is not permitted in the term during which the thesis is submitted). Regular meetings with members of the dissertation committee to review thesis progress is expected and left to the student to schedule. At the conclusion of the thesis, PhD students are required to hold an oral defense of their dissertation. This defense is scheduled directly with the thesis committee, and the date is reported to the degree administrator.

Policy on Incompletes and Thesis Semester

MArch, SMArchS, and SMACT students entering thesis term may have no more than one incomplete in a subject required for the degree, and that incomplete can be no older than the term previous to thesis. Students with several incompletes and/or incompletes from terms further back will be denied registration until those subjects are completed and graded. This policy applies to subjects required by curriculum or needed for units toward the degree.

Policy on Credit and Thesis

MArch students must have their curriculum credits in order by the end of the thesis prep. No substitutions or petitions for credit will be accepted or processed during the thesis term.

Thesis for Dual Degrees

Thesis research for dual degrees must be done under the supervision of an approved member of one of the two participating departments, with the other department providing a co-advisor or thesis reader. Students expecting to receive two advanced degrees must submit all thesis materials to the department in which they register during their final semester and are bound by the thesis specifications and deadlines of that department.

Thesis Guidelines and Deadlines

The Thesis Committee Guidelines  document (updated January 2024) addresses the composition of a thesis committee for each degree program. The thesis committee must be established and approved before thesis registration is permitted.

• Specifications for Thesis Preparation  is published by the MIT Libraries Institute Archives to assist students in the preparation of the thesis document. The Institute is committed to the preservation of the student’s thesis because it is both a requirement of the MIT degree and a record of original research. The library also publishes a guide for following copyright law, which students should review carefully to make certain they remain in compliance and the thesis is acceptable by the MIT Archives .
• The department upholds the requirements of the Institute specifications. In addition, the Department of Architecture requires that each thesis contain a page listing the names and titles of each member of the thesis committee. This page is to be inserted between the title page and the abstract. Students should review the  thesis checklist  before submitting the thesis to the Department.
• At the beginning of the final thesis term, all students must file an online Application for Advanced Degree at MIT via  WebSIS.  The deadline is the end of the first week of term.
• Graduate Policies and Procedures  can be found on a website provided by the Office of Graduate Education (OGE). This website offers additional information on the thesis process, including joint theses; restrictions on thesis publication; patent protection, privacy and security; intellectual property policy; and thesis holds.
• The deadline for submitting the approved, archival copies of the thesis is set by the Department, and can be found on the  Department Thesis website . Only minor errors in formatting and proofing will be subject to change after this date and only at the discretion of the department administrators.

All theses are submitted to the department degree administrators:

• Master's programs:  Kateri Bertin
• Doctoral programs:  Tessa Haynes

Nonresident Doctoral Research

A doctoral student who has completed all requirements except for the dissertation may apply for nonresident thesis research status. Students granted this status pay approximately 5% of regular tuition for the first three terms of nonresident status and 15% for the following three terms. Students are limited to six terms of nonresident status.

Application

Permission to become a nonresident doctoral candidate must be sought from the Dean of Graduate Students. The  request form  is submitted to the Office of Graduate Education (OGE) by July 15 for the fall term, and November 15 for the spring term (a fee is assessed for late requests). The student’s thesis advisor and the department’s graduate officer must approve the application prior to submission. 

Approval can be granted for two successive regular terms in the same academic year (for example, Fall 2021 and Spring 2022, but not Spring 2022 and Fall 2023). Registration as a nonresident student is not required during the summer. Students must reapply each year for additional terms of nonresident status up to a maximum of six terms. Students must return to regular status to defend and submit their doctoral dissertation.

Eligibility

To be eligible to apply for non-resident thesis research status, students must be 

• registered in a doctoral program,
• in residence as a regular graduate student for at least four regular terms,
• have completed all degree requirements except for the dissertation and have submitted required paperwork to the Degree Administrator,
• and have an approved thesis proposal.

Privileges of a Nonresident Student

Nonresident students are considered full-time students. They may retain their MIT IDs and are permitted access to the libraries and athletic facilities. They continue to have the same student health plan options as resident students, although, students are financially responsible for their own health insurance.

However, nonresident students are NOT eligible to

• use offices, laboratories, design studios or computer facilities in the Department unless specifically approved;
• reside in student housing;
• serve as graduate resident tutors; 
• nor accept employment of any kind at MIT. 

For the first three semesters of nonresident status, a student may receive fellowship support from MIT for an amount up to 5% of the cost of tuition per semester. In subsequent terms of nonresident status, students are not eligible to receive financial support from any MIT department, lab, or cost center. This includes fellowships, research or teaching assistantships as well as any work-study programs.

Although nonresident students are responsible for payment of tuition and appropriate fees, U.S. citizens or Permanent Resident students may apply for federal and alternative loans. Current loans may be adjusted because tuition will be decreased to nonresident levels. Questions regarding loans should be addressed to Student Financial Services.

Thesis research is ordinarily done in residence at the Institute. However, on occasion, work away from the Institute may be essential for such tasks as gathering data. Students with compelling educational reasons to do so may therefore apply to take one or two semesters in absentia. 

A proposal for thesis research to be done in absentia must be approved by both the faculty of the specific PhD degree program, the Department's graduate officer, and the Dean of the Graduate School. 

Criteria for thesis in absentia include, but are not limited to the following:

• Evidence that this opportunity will provide continuing intellectual growth.
• Evidence of completion of required coursework and all degree requirements except the thesis.
• The thesis must continue to be supervised by an Institute faculty member or by a senior academic staff member approved by the Department.
• The student must be registered as a regular student during the final term.
• The student must devote full time to thesis research while absent from MIT.

Students approved for thesis in absentia will continue to be registered as full-time students and receive tuition plus their normal fellowship stipends.

The proposal needs to include the following and submitted to the Department's PhD degree administrator:

• Current address
• Current phone
• Current e-mail
• Degree program
• Completion date of general exams
• Completion date of thesis proposal and working title for thesis
• Proposed terms in absentia
• Expected degree date
• Reasons for requesting thesis research in absentia—the opportunity for continued intellectual growth must be evident
• Thesis advisor’s name and title 
• Thesis advisor’s signature of approval
• Degree program director’s signature of approval
• Graduate officer’s signature of approval
• A copy of the signed thesis proposal 

The approved and signed thesis proposal must be attached to the research-in-absentia proposal before the latter is submitted to the Department and, subsequently, the Office of Graduate Education (OGE).

The department offers programs covering a broad range of topics leading to the Doctor of Philosophy and the Doctor of Science degrees (the student chooses which to receive; they are functionally equivalent). Candidates are admitted to either the Pure or Applied Mathematics programs but are free to pursue interests in both groups. Of the roughly 120 Ph.D. students, about 2/3 are in Pure Mathematics, 1/3 in Applied Mathematics.

The two programs in Pure and Applied Mathematics offer basic and advanced classes in analysis, algebra, geometry, Lie theory, logic, number theory, probability, statistics, topology, astrophysics, combinatorics, fluid dynamics, numerical analysis, mathematics of data, and the theory of computation. In addition, many mathematically-oriented courses are offered by other departments. Students in Applied Mathematics are especially encouraged to take courses in engineering and scientific subjects related to their research.

All students pursue research under the supervision of the faculty , and are encouraged to take advantage of the many seminars and colloquia at MIT and in the Boston area.

Degree Requirements

Degree requirements consist of:

• Oral qualifying exam
• Classroom teaching
• Original thesis and defense

Prospective students are invited to consult the graduate career timeline for more information, and to read about the application procedure .

Graduate Co-Chairs

Graduate Student Issues, math graduate admissions

Jonathan Kelner , Davesh Maulik , and Zhiwei Yun

Master’s Degrees

The master’s degree generally requires a minimum of one academic year of study..

Admission to MIT for the master’s degree does not necessarily imply an automatic commitment by MIT beyond that level of study.

In the School of Engineering, students may be awarded the engineer’s degree. This degree program requires two years of study and provides a higher level of professional competence than is required by a master’s degree program, but less emphasis is placed on creative research than in the doctoral program.

Below is a list of programs and departments that offer master-level degrees.

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The Master of Science in the Management of Information Technology Program teaches business and technology professionals how to deliver greater business value through the effective management and use of information technology (IT). The program’s intensive, collaborative 30-credit curriculum synthesizes management disciplines such as finance, strategy, communication and leadership with technical knowledge of enterprise architecture, project and product management, enterprise IT management, and IT-enabled business innovation.

The program’s executive format allows working professionals to complete the degree while remaining fully employed. Specific information about formats and locations can be found at https://www.commerce.virginia.edu/ms-mit/format

Program Prerequisites

To be considered for admission to the M.S. in the Management of IT program, applicants must meet the following minimum requirements:

• Have a conferred bachelor’s degree from a regionally accredited US college or university or its equivalent in another country at the time of matriculation; candidates enroll in the program with a wide range of undergraduate majors
• Have a minimum of two years of professional work experience (post bachelor’s degree) that includes significant managerial or technical involvement with IT
• Show evidence of strong problem-solving and analytical skills through a combination of academic background, work experience, and optional GMAT, GRE or Executive Assessment test scores
• Demonstrate professional readiness and motivation for chosen field of study
• Qualities of character (e.g., academic excellence, intellectual curiosity, strong work ethic, ability to collaborate, awareness & ability to engage cross differences, growth mindset, initiative, resilience & perseverance, social engagement, unique perspective, professional excellence, leadership, and personal & professional integrity)
• Evidence of strong written and oral communication skills; non-native English speakers also must demonstrate proficiency in oral and written English to be successful in the graduate program

Admission Requirements

Candidates seeking admission to the M.S. in the Management of IT program will submit the following items:

• Completed online application
• Three required essays
• One letter of recommendation (professional reference preferred)
• Transcripts and academic records from every college and/or university attended
• TOEFL or IELTS score (if applicable); McIntire requires a minimum TOEFL score of 100iBT or IELTS score of 7.5
• GMAT, GRE or Executive Assessment (EA) score (accepted but not required)  
• Application fee: $85
• Interview (invitation only)

Candidates who accept their offer of admission must submit their online enrollment agreement as well as $1,000 non-refundable deposit to reserve their place in the class and initiate their University of Virginia student account. A second and final non-refundable deposit of $1,500 is required to confirm your place in the class. Please refer to the M.S. in the Management of IT deadlines page for specific enrollment deposit submission dates. Upon enrollment, the entire $2,500 enrollment deposit will be applied to your tuition account.

For additional information, please visit the M.S. in the Management of IT program website or contact:

McIntire Office of Graduate Marketing and Admissions

140 Hospital Drive

P.O. Box 400173

Charlottesville, VA 22904-4173

(434) 982-6800

[email protected]

https://www.commerce.virginia.edu/ms-mit

Departmental Financial Aid

The McIntire School of Commerce offers a limited number of departmental scholarships to qualified graduate students in the M.S. in the Management of IT program. Scholarships are awarded based on merit and financial need and prospective students may express interest in being considered for a departmental scholarship in their application for admission. If awarded, scholarships will be communicated at the time of admission.

Transfer of Credit

The Master of Science in the Management of Information Technology Program typically requires students to complete all 30 credits of the program during their period of enrollment. Transfer credits must be approved by the Director of the M.S. in Management Information Technology Program.

Program Attendance

Given the intensive and cumulative nature of the Master of Science in the Management of Information Technology Program, students are expected to attend all scheduled class meetings (including online meetings) in their entirety. If a student arrives late, leaves early, or misses an entire day, there may be a deduction in class participation, which is part of the final course grade. Absence for more than two days in any module will automatically result in an evaluation of non-performance (“F”) in that module. Students are expected to communicate clearly and in advance their program commitments to all relevant parties, including family and work relationships.  In the event that a student cannot be present for any part of the program, or falls behind for any reason, it is the responsibility of the student to make arrangements with the appropriate faculty to make up the work as approved by the appropriate faculty member.

Grading & Academic Performance Expectations

Grading Policy

Grades are awarded only to students who are registered for and complete a course for credit. All courses are on a credit basis only and students must receive a grade. The letter grades used for grading students in McIntire graduate courses are: A+, A, A-, B+, B, B-, C+, C, C-, D+, D, D-, F.

GPA Requirements for Graduation

Students are required to complete their program of study with a GPA of 2.70 or better in order to graduate.

Academic Performance Expectations

Good academic standing is defined as maintaining a 2.70 cumulative GPA. At the end of each module, a student’s academic performance will be evaluated by the Academic Program Director(s) to determine if a student is still in good academic standing. A student not meeting the 2.70 cumulative GPA criteria at the end of a given term (or after two modules) will be placed on Academic Probation. A notation of Academic Probation will be placed on the student’s academic record until resolution of the academic issues.

Good module performance is defined as a “B” grade or better. A student not meeting the module performance standard or on academic probation will meet regularly with his or her Academic Program Director(s) to ensure appropriate progress is being made toward degree completion.

A student who earns a cumulative GPA below 2.70 in three modules will be dismissed from his or her program of study. A student who earns a grade of “F” in any course will be dismissed from the program.

Behavioral & Administrative Expectations

Behavioral and administrative expectations are outlined throughout the Graduate Record and include but are not limited to required class attendance, making progress toward a degree, and fulfilling all expectations implied by enrollment at the University (e.g. Honor Code or Standards of Conduct).

Student adherence to these expectations will be evaluated periodically or when a situation is brought to the attention of an Academic Program Director.  If a student’s behavior is found to not be in adherence with the expectations, a warning will be issued to the student and a behavior modification plan will be put in place.  This plan will include a timeframe for reevaluation of the student’s behavior.  After a reevaluation is conducted, a student who has met the expectations of the behavior modification plan will return to good standing.  A student who is still not meeting the behavioral expectations outlined in the plan will be given a final opportunity to remediate the deficient behavior and return to good standing.  If, after a second opportunity to meet the expectations of the program and university, a student is still found to display behaviors inconsistent with the program expectations, an ‘Enforced Withdrawal’ will be enacted.

M.S. in MIT Course Descriptions

• GCOM 7790 - Enterprise Architecture Credits: 4
• GCOM 7800 - Advanced Enterprise Architecture Credits: 4
• GCOM 7810 - Strategic Management of IT Credits: 4
• GCOM 7830 - IT Project Management Credits: 2
• GCOM 7831 - IT Product Management Credits: 5
• GCOM 7832 - IT International Project Management Credits: 2
• GCOM 7840 - Innovation and Technology Management Credits: 4
• GCOM 7850 - IT-Driven Organizational Transformation Credits: 3
• GCOM 7860 - Digital Innovation Credits: 4

Optional Independent Study

With approval of the Academic Program Director, students may enroll in GCOM 7993 for any semester in the MSMIT program.  Interested students should consult with the Director of the MS in the Management of Information Technology program.

RIT graduate pursues Ph.D. across time zones

Nastaran Nagshineh, center, defended her Ph.D. thesis at RIT in April. Faculty from RIT’s Rochester and Dubai campuses served on her thesis committee and include, from left to right, Kathleen Lamkin-Kennard, Steven Weinstein, Nathaniel Barlow, and David Kofke (a professor at the University at Buffalo). Mohamed Samaha participated remotely and appears on the video screen behind the group and alongside Nagshineh’s picture.

Nastaran Nagshineh is one of the first Ph.D. candidates to bridge RIT’s Rochester and Dubai campuses. Her accomplishment creates a path for future students at the university’s international campuses.

Nagshineh completed her Ph.D. in mathematical modeling while working full time as a mathematics lecturer at RIT Dubai in the United Arab Emirates, teaching as many as five classes a semester. She described her Ph.D. journey as “an exercise in perseverance” due to competing demands and long days. Rochester is eight hours behind Dubai, and the time difference meant many late-night classes and meetings.

“I saw this collaboration as an opportunity, rather than as a challenge, because my primary adviser, Dr. Steven Weinstein (RIT professor of chemical engineering), and my co-adviser, Dr. Mohamed Samaha (RIT Dubai associate professor of mechanical engineering), both have the same area of research interest,” she said. “They both worked toward my success.”

Nagshineh is one of 67 RIT Ph.D. students who defended their thesis this academic year and who will earn their doctorate. RIT awarded 63 Ph.D. degrees in 2023.

In 2020-2021, RIT’s Graduate School met and surpassed the university’s goal of conferring 50 Ph.D. degrees during an academic year. That number will continue to grow as students cycle through the seven new Ph.D. programs that RIT has added since 2017, said Diane Slusarski , dean of RIT’s Graduate School.

Meeting these goals puts RIT on a path toward achieving an “R1,” or research-intensive designation, from the Carnegie Classification of Institutions of Higher Learning. RIT is currently ranked as an R2 institution . Many factors go into changing a university’s status, including research investment and maintaining a three-year average of 70 Ph.D. degrees awarded per year, according to Slusarski.

“We have met the goals of the strategic plan, and now we look forward to contributing to the research innovation in the future,” Slusarski said. “We want to help the new programs thrive and win national research awards.”

RIT’s emphasis on high-level research is seen in Nagshineh’s Ph.D. work. She applies mathematical modeling to the field of fluid dynamics. Her research has been published in top-tier journals and has gained notice, said Weinstein, her thesis adviser.

Weinstein describes Nagshineh’s accomplishments as “a testament to a fantastic work ethic and commitment” and is inspirational to younger students at Rochester and Dubai.

“The collaboration between RIT Dubai/Rochester has continued,” he said. “Another paper was submitted a few weeks ago with Mohamed Samaha and Nate Barlow (RIT associate professor in the School of Mathematics and Statistics) as co-authors, as well as Cade Reinberger, a younger Ph.D. student in my research group.”

Mathematical modeling is one of RIT’s newer Ph.D. degree programs, and Nagshineh is among its earliest graduates. The program has doubled in size since it began accepting students in 2017, Slusarski said. This past fall, the mathematical modeling program had 35 students, with two graduating this year.

Altogether, RIT has 13 Ph.D. degree programs currently enrolling 438 students, with computing and information sciences accounting for the largest with 117 students. RIT’s other Ph.D. programs include astrophysical sciences and technology , biomedical and chemical engineering , business administration , color science , electrical and computer engineering, imaging science , mechanical and industrial engineering , microsystems engineering , and sustainability .

New programs in cognitive science and physics will launch in the fall.

The growth in RIT graduate education—with more than 3,000 master’s and doctoral students—reflects a demographic change in the student population, Slusarski said. “We have a higher percentage of women in the graduate programs than we have for RIT undergraduate programs.”

RIT’s graduate programs enroll 42 percent women, according to Christie Leone , assistant dean for the Graduate School.

Nagshineh, who also holds an MS in electrical engineering from RIT Dubai, welcomes her role as a mentor to other women students on both campuses.

“As a young woman in an Arabic country, the power of women is often underestimated and undervalued, and I hope to serve as a role model to female students, especially those that question their path,” Nagshineh said.

She plans to continue in her career as a professor and a researcher. “I would like to pursue a research program where I can advise my own students and teach them more deeply.”

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Bilingual Endorsement

What you can earn, credits earned, time commitment, an endorsement for current uw students and in-service teachers.

The Bilingual Endorsement program is designed for any certified educators seeking to enhance their ability to better serve and advocate for multilingual learners in their classes, as well as for those who plan to teach in a Dual Language classroom. Elementary MIT Candidates pursuing this endorsement will remain matriculated as UW graduate students through the summer quarter. In-service teachers will register as NM (non-matriculated students).

What you'll learn

The Bilingual Endorsement in Washington is addressed through standards focusing on: 

• Bilingualism and biliteracy,
• Sociocultural competence,
• Dual language instructional practices and pedagogy,
• Authentic assessment in dual language,
• Professionalism, advocacy and agency,
• Program design and curricular leadership.

You will acquire this knowledge and skills in foundations and methods courses. In addition, you may complete a field experience. The competencies are met through coursework and the completion of supervised fieldwork.   

After graduation

After completion of this endorsement, you will be qualified to teach in a target language (Spanish, Mandarin, Japanese, etc.) in a bilingual or Dual Language classroom setting.

Let's connect

For any questions about the program, contact Patricia Ferreyra, Endorsement Coordinator, at [email protected]

For additional information regarding funding for teachers in Dual Language Schools, contact Renee Shank, at [email protected]

For any questions about endorsement and certification requirements, contact Michael Nielsen, Certification Officer, at [email protected]

Registration for In-Service Teachers

There are three steps to the process:, step 1: register for nm status.

(...or GNM with the College of Education only if you want to do a UW Graduate Program in the future and count your ELL/ML credits toward that degree. Note that the College of Education has its own process, which is not the same as for other UW graduate programs. For more information see:   https://education.uw.edu/admissions/non-matriculated-and-graduate-non-matriculated-students ) )

Registering for NM Status

WA State Employees who intend to apply as a first time or returning non-matriculated (not seeking a degree) students under the tuition exemption program must complete the online non-matriculated application for tuition exemption. There is a $80 non-refundable registration fee.

*Contact Patricia Ferreyra or Michael Nielsen if you want to use endorsement credits toward a graduate degree at UW in the future. In that case, you will have to register for GNM status.

Step 2: Complete Tuition Exemption Forms 

The second step is to submit the correct Tuition Exemption Request form for WA State Employees: Complete and submit Washington State Tuition Exemption Request Form [UoW 1250] .

Application Deadline: Completed forms must be submitted no later than two (2) weeks or ten (10) business days before the first day of the quarter. In Spring 2024, the first day of the quarter is March 25th and the first day of classes for the ELL/ML Endorsement is March 26th. In Summer 2024, the first day of the quarter is June 17. The first day of classes for the ELL/ML Endorsement is July 9.

Late Applications: Forms submitted after the deadline date are considered late. Students may have one late submission only; after which tuition exemption forms cannot be accepted.

Step 3: Register for Classes

The third step, once an employee has obtained student status and submitted a tuition exemption form, is to log into https://my.uw.edu and register for courses on the appropriate eligibility date. If you are prompted to enter edcodes, email Patricia Ferreyra at [email protected] .

* WA public employees who are tuition exempt students do not register using the Non-Matriculated (NM) paper registration approval or registration forms, and do not require instructor signatures to register. Review the Registration Policies & Procedures website for additional information.

Registration Eligibility Dates

All non-UW Washington state employees register on the 4th day of the quarter. WA state employees doing tuition exemption can begin registering on February 9th for Spring Quarter: 

Course enrollment is not permitted prior to the appropriate registration eligibility date for all courses when using a tuition exemption. This includes any additional courses even if they are not taken as tuition exempt. 

Students registering before the assigned tuition exemption registration eligibility date will not be permitted to convert to the tuition exemption program, and will be required to pay regular tuition for all registered credits. Course Adds are not accepted after the third week of the quarter.

The Bilingual Endorsement is an intensive, quarter-long program. Your cohort will follow a sequence together. 

Cohorts take the same course sequence together. The following is a sample schedule and is subject to change.

• EDC&I 540: Foundations of Immigrant Schooling (3 credits) 
• EDC&I 542: Approaches to Assessing Second Language Students in K-12 Schools (3 credits)
• EDC&I 545: Multilingual Socialization and Development (3 credits)
• EDC&I 549: Practicum (3 credits)
• EDC&I 554: Bilingual Teaching Methods and Assessment (4 credits)

There is a required practicum seminar where teachers continue to develop their practice teaching bilingual learners through peer support and reflection. 

The summer practicum experience consists of an online asynchronous course. Candidates meet all assignments, participation expectations, and deadlines as articulated in the syllabus and other course materials in the course learning management system. The course may offer learners optional, ungraded opportunities to meet in real time, such as through virtual office hours. 

Upon completion of coursework and fieldwork, you must take the West-E exam 050 to complete the endorsement requirements. You can register for the exam online at http://www.west.nesinc.com/

Admission requirements and process

Before beginning the application process, we recommend reaching out or attending an information session. This will help us get to know you and make sure you have all the information and materials you need to get started on your application!

Please fill out the Summer 2024 intake form .

Your application materials will be manually assessed and checked into the application database. The Endorsement Coordinator will notify applicants about final status by early June.  

Costs and funding

Estimated costs and funding.

The anticipated cost of completing the spring or summer coursework for current graduate students is $6,528 for a resident* plus any registration, practicum and technology fees. Non-matriculated summer fees are approximately $7,062 (see the  Graduate and Professional Tuition Dashboard ).

The following information is for WA state K-12 teachers who want to complete the UW ELL/ML endorsement, and for those who are also applying for a tuition exemption as WA state employees. 

You will most likely register as a "non-matriculated student" (NM). Start by accessing this resource:

• The University Registrar’s guide on how to apply for a tuition exemption as a WA state employee AND register as an NM student:  https://registrar.washington.edu/registration/tuition-exemption/

In-service educators may also wish to explore the Washington Student Achievement Council’s Educator Retooling Conditional Scholarships. For more information, visit: https://wsac.wa.gov/teachers

Please start with the emails or phone numbers shown below for clarifying questions.  

For general questions about the logistics and contents of the ELL/ML Endorsement, reach out to Patricia Ferreyra at  [email protected] .

Nevada Today

Using curiosity to make a difference: how one ph.d. candidate found her ‘why’, hailey hermann studies a very rare congenital muscular dystrophy.

Hailey Hermann decided to pursue research as a tangible way to make a difference in others' lives.

Hailey Herman has always been a highly curious person. As a first-generation college student, she completed her bachelor’s degree and knew she wanted to do something to benefit others – she just wasn’t quite sure what that would look like. She joined the Burkin lab at the University of Nevada, Reno School of Medicine (UNR Med) where she participates in translational research for different types of muscular dystrophies. Immediately, she knew that contributing to this research was how she could make a difference, and she decided to pursue a Ph.D.    

Reflecting on her time at UNR Med, Herman shares, “I love being a part of the UNR School of Medicine. It is a place filled with such knowledgeable faculty and staff. The academic environment is constantly growing and is very supportive of its students.” She plans to finish her dissertation by the end of the year, and then will stay on as a postdoc in Dr. Burkin’s lab. Still unsure if she will land in academia or industry, she plans on taking a similar approach to her research and “figuring it out little by little after graduation.”

Why did you decide to pursue research and what is your focus?

“ I wanted to do something that would benefit others, so naturally I found research (or maybe research even found me). However, it wasn’t until I joined the Burkin lab that I knew for sure that research was for me, and I wanted to continue and pursue a Ph.D.   

“In the Burkin lab, we focus on translational research for different types of muscular dystrophies. I work on LAMA2-CMD, a very rare congenital muscular dystrophy in which patients ultimately die within the first or second decade of life. There currently is no effective treatment or cure. It is caused by a mutation in the LAMA2 gene which causes complete or partial loss of a protein called laminin-211. Our lab has developed a protein replacement therapy and has previously shown it can slow disease progression.   

“Currently, I am using a new technique called digital spatial profiling to study the proteome and transcriptome in individual human and mouse muscle fibers. The aim of this project is to observe major changes between human patients and control tissues. By looking at the molecular changes, we hope to discover novel biomarkers and demonstrate a potential therapeutic intervention for children affected with LAMA2-CMD .”  

What specialty or area are you most passionate about pursuing, and what draws you to this field?

“The general sense that I can make a difference is what truly drives me to do research. Growing up I played a lot of sports and was very active. I was very interested in wellness, nutrition, and maintaining good health. Once I began studying muscular dystrophy I applied these interests in a different way. Many of these adolescent patients will never gain the ability to walk let alone play on the monkey bars at recess. In a way, it felt unfair that they wouldn’t get a similar experience in childhood that I was able to have.  

“During the beginning half of my Ph.D., I went to my first conference in Nashville that focused on rare congenital muscular dystrophies. This conference is smaller than most and is different because parents and their children affected with muscular dystrophies attend the conference too. Watching the supportive community that the CureCMD organization fostered to support these underrepresented diseases was incredibly moving. Seeing these children fly past you in their motorized wheelchairs while playing tag with huge smiles on their faces in the hotel lobby really helped me understand my ‘why.’”   

What is the biggest challenge you have faced in your UNR Med education and how did you overcome it?  

“Imposter syndrome. One minute it is this thing you hear about and the next minute you are convincing yourself that you somehow managed to fool the application committee filled with seasoned professionals and that you shouldn’t be here. Grad school is hard, and it is supposed to be, and it is very different from your undergraduate years because not every answer can be found in a book. The weirdest part is I don’t know when I overcame it, but just at one point I felt confident in the scientist I was becoming and proud of my work.   

“One thing that helped was that I read somewhere that we can’t think of gaining knowledge as linear because gaining knowledge is more similar to gaining compound interest. The more papers you read and techniques you learn will open multiple avenues to explore and gain insight into other areas. The next important thing that helped was giving myself grace and taking a break once in a while. You can’t achieve an accurate perspective if you are always ‘in it.’ Taking a step back and taking a breather can sometimes be the perfect conditions to ground you.”  

Can you share a memorable experience during your training that has significantly impacted your journey?

“One memorable experience was trying to write my qualifying exam introduction and specific aims. The writing format is an R21 grant proposal, so it is a little different from the writing style I was used to at the time. I found myself procrastinating on getting started so I decided one morning I would go to Coffeebar and not leave until I finished the introduction portion. I had bad writer's block that day and ended up there for four hours and drank about five cold brews. I ended up giving myself caffeine-induced anxiety and wrote as fast as I could just so I could get out of there.   

“The next day, I reread what I worked on, and it was terrible. I was off-tangent and kept switching between present and past tense randomly, so I pretty much scrapped the whole thing. I also couldn’t stomach coffee for about a week. Now I put a lot less pressure on when I write, and it seems to work out much better that way.”   

What advice do you have for future students interested in pursuing research?

“ As cliché as it sounds, don't be afraid to ask questions. Some of the most profound ideas I have had happened when I would ask about something that seemed obscure or not super applicable to my project. You never know where a question may take you. I also like keeping a non-formal journal that is for research. It helps me keep track of ideas I have come up with and how I feel while using a new protocol. Sometimes when I confuse myself, I can flip back in it and see what led up to that point .”

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