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Covalent Bonding

10th -  12th  , chemical bonding, polarity practice, metric conversions practice, chemical bonds, lewis structures.

8th - 11th grade

63 questions

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• 1. Multiple Choice Edit 1 minute 1 pt How many Hydrogen are in 4H 2 O? 6 8 2 4
• 2. Multiple Choice Edit 30 seconds 1 pt How many are shared in a single bond? 2 pairs 4 2 1
• 3. Multiple Choice Edit 1 minute 1 pt How many atoms are there TOTAL in: H 2 SO 4 6 5 7 3
• 4. Multiple Choice Edit 1 minute 1 pt How many elements are in C 6 H 12 O 6 ? 1 2 3 4
• 5. Multiple Choice Edit 1.5 minutes 1 pt Number of N in (NH₄)₂CrO₄ 1 2 8 16
• 6. Multiple Choice Edit 30 seconds 1 pt How many O's are in Al₂(SO₄)₃ 4 12 7 24
• 7. Multiple Choice Edit 30 seconds 1 pt What does a sodium atom become when it loses its only valence electron? sodium compound sodium atom ionic compound sodium ion
• 8. Multiple Choice Edit 30 seconds 1 pt What is the charge of an aluminum ion that has 13 protons and 10 electrons? 1+ 3+ 2+ 3-
• 9. Multiple Choice Edit 30 seconds 1 pt What is the charge of a sodium ion with 11 protons and 10 electrons? 1+ 1- 2+ 2-
• 10. Multiple Choice Edit 30 seconds 1 pt What type of compound is CaF 2 ? covalent ionic polar metallic
• 11. Multiple Choice Edit 1 minute 1 pt What is the rule for figuring out if it is ionic or covalent? Covalent bonds form between two metals. Ionic bonds form between two metals. Covalent bonds form between a metal and a non-metal. Ionic bonds form between a metal and a non-metal.
• 12. Multiple Choice Edit 30 seconds 1 pt Ionic or covalent? Na  F Ionic Covalent

Ionic or covalent?

• 14. Multiple Choice Edit 30 seconds 1 pt The force of attraction that holds atoms or ions together covalent compound chemical bond ionic compound valence electron

What molecule is this?

What is the chemical formula for this molecule?

• 17. Multiple Choice Edit 30 seconds 1 pt What two types of atoms make a covalent bond? 2 Nonmetals 1 Nonmetal and 1 Metal 2 Metals 2 Noble Gases
• 18. Multiple Choice Edit 30 seconds 1 pt Nonmetals are most likely to _____________ valence electrons in order to have a stable arrangement. lose gain gain or share share
• 19. Multiple Choice Edit 30 seconds 1 pt Ionic Bonds form between two ions that have ionic compounds negative charges positive charges opposite charges
• 20. Multiple Choice Edit 30 seconds 1 pt If "ionization" is the process of an atom becoming an ion, which of the following describes this? The atom jumps from one period to another Atom loses or gains protons Lithium turns into flourine Atom loses or gains electrons
• 22. Multiple Choice Edit 30 seconds 1 pt Hydrogen needs _____ electrons in its valence shell to be stable. 4 6 8 2
• 23. Multiple Choice Edit 30 seconds 1 pt Metals and nonmetals form which kind of bond? Polar covalent Ionic Non-polar covalent Metallic
• 24. Multiple Choice Edit 1 minute 1 pt How many electrons should Lithium have around its Lewis dot model? 1 2 3 4
• 25. Multiple Choice Edit 1 minute 1 pt How many electrons should Boron have around its Lewis dot model? 1 3 5 7
• 26. Multiple Choice Edit 1 minute 1 pt How many electrons should Chlorine have around its Lewis dot model? 5 6 7 8
• 27. Multiple Choice Edit 1 minute 1 pt Which is involved in bonding? protons neutrons electrons valence electrons
• 28. Multiple Choice Edit 30 seconds 1 pt How are covalent bonds explained? When one atom takes the other atom's electron When the atom shares an electron with an another atom When the two nucleus merge When the neutrons leave the nucleus
• 29. Multiple Choice Edit 1 minute 1 pt Why do ionic bonds form? so the number of protons equals the number of electrons to fill the outermost energy level so an atom can become unstable
• 30. Multiple Choice Edit 30 seconds 1 pt Atoms form ions in order to become this isotopes stable metals nonmetals
• 31. Multiple Choice Edit 30 seconds 1 pt How are ionic bonds formed? When atoms share an electron When opposite charged atoms attract When one atom takes a proton When one atom takes a neutron
• 32. Multiple Choice Edit 45 seconds 1 pt Which of the following is a compound? Co O 2 C CO 2
• 33. Multiple Choice Edit 45 seconds 1 pt How many atoms are there TOTAL in: H 2 SO 4 6 5 7 3
• 34. Multiple Choice Edit 45 seconds 1 pt How many elements are in C 6 H 12 O 6 ? 1 2 3 4
• 35. Multiple Choice Edit 30 seconds 1 pt a capital letter or combination of a capital letter and a small letter that is used to represent an element is called a(n) ________ chemical symbol element sign
• 36. Multiple Choice Edit 20 seconds 1 pt an electron has this charge positive negative neutral
• 37. Multiple Choice Edit 30 seconds 1 pt What is the atomic number? number of protons number of neutrons
• 38. Multiple Choice Edit 45 seconds 1 pt How many TOTAL atoms are in this compound? H 2 C 3 O 4 N 5 5 14 15 19
• 39. Multiple Choice Edit 30 seconds 1 pt if METALS are more likely to LOSE electrons, they will form ... anions neutral atoms positive ions negative ions
• 40. Multiple Choice Edit 1 minute 1 pt How do positive ions form? by gaining electrons getting compliments by losing electrons gaining more protons
• 41. Multiple Choice Edit 30 seconds 1 pt Atoms that lose electrons become... negatively charged postively charged remain neutral, no charge losers
• 42. Multiple Choice Edit 1 minute 1 pt If an oxygen atom has 8 protons (+) and 10 electrons (-), what is it's charge? O 10- O 8+ O 2- O 10+
• 43. Multiple Choice Edit 30 seconds 1 pt Atoms form ions in order to become this isotopes stable metals nonmetals
• 44. Multiple Choice Edit 30 seconds 1 pt How many electrons should Chlorine have around its Lewis dot model? 5 6 7 8
• 50. Multiple Choice Edit 30 seconds 1 pt If an ion has lost an electron and has  more protons than electrons , what is its charge? Negative Positive Neutral This is impossible
• 51. Multiple Choice Edit 30 seconds 1 pt Which groups of the table are most likely to become  positively charged  ions? 1 and 2 Metals 16 and 17 The Noble Gases
• 55. Multiple Choice Edit 30 seconds 1 pt Looking at the Periodic Table, how many valence electrons does lithium (Li) have? 1 2 3  8
• 56. Multiple Choice Edit 30 seconds 1 pt How many valence electrons does neon (Ne) have? 1 5 7 8
• 57. Multiple Choice Edit 30 seconds 1 pt Which of the following is a compound? Au O 2 Ne H 2 O
• 58. Multiple Choice Edit 30 seconds 1 pt Why is water a  covalent bond Water is two nonmetal atoms which share electrons forming a molecule  Water forms solid crystals over a given amount of time The electrons from the hydrogen and oxygen in water are shared in a pool Hydrogen and oxygen gain and lose electrons when forming the molecule water
• 59. Multiple Choice Edit 30 seconds 1 pt Dot diagrams are used to represent _____ Valence electrons Protons Atomic mass The structure of the nucleus
• 60. Multiple Choice Edit 30 seconds 1 pt The chemical formula for glucose is C 6 H 12 O 6 how many hydrogen atoms are there in glucose 12 1 6 24
• 61. Multiple Choice Edit 30 seconds 1 pt In carbon dioxide, each oxygen atom shares four electrons with the carbon atom.  What is this type of bond called Double covalent Triple Covalent Polar covalent Quadruple covalent
• 62. Multiple Choice Edit 30 seconds 1 pt Atoms gain, lose or share electrons to become as chemically stable as  Nobel Gases Neutral Atoms Ions Neutral Compounds
• 63. Multiple Choice Edit 30 seconds 1 pt What is a bond that forms when electrons are transferred from one atom to another? ionic bond electron bond crystal bond atom bond

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Chemical Bonds in Compounds Quiz

Self-Test for Bonds, Electron Transfer, and Compounds

• Chemical Laws
• Periodic Table
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• Ph.D., Biomedical Sciences, University of Tennessee at Knoxville
• B.A., Physics and Mathematics, Hastings College
• shared equally
• shared unequally

An example would be the bond between two hydrogen atoms to form hydrogen gas.

The alkaline earths are the second group (column) in the periodic table. Atoms of these elements form ions with a +2 charge. Knowing the usual valence of elements in a group helps when it comes to predicting the compounds that can be formed.

• iron chloride
• iron (I) chloride
• iron (II) chloride
• iron (III) chloride

Transition metals can have different valences, so it's important to list the valence in a compound name.

• covalent, dinitrogen tetroxide
• covalent, nitrogen tetroxide
• ionic, nitrogen oxide
• ionic, dinitrogen oxide

Nonmetals form covalent bonds with each other. Rather than call any combination of nitrogen and oxygen "nitrogen oxide", you should specify how many atoms of each type are present.

• polar covalent
• nonpolar covalen

Nonmetals form covalent bonds. Since the electronegativity values are not identical, you know it's a polar bond.

Answer this by looking up the atomic number (number of protons) on the periodic table. The number of protons and electrons is not the same, so you're dealing with an ion. If there are more protons than electrons, there's a net positive charge. If there are more electrons than protons, it's an ion with a negative charge.

• MgNO₃
• Mg₂NO₃
• Mg(NO₃)₂
• Mg₂(NO₃)₃

Polyatomic ions are groups of atoms bound together that act as a cation or anion to form bonds and make compounds. To answer this question, you need to know the formula of a nitrate .

The tri- prefix in the name means "three".

• loses 2 electrons to form a magnesium ion with a 2- charge
• gains 2 electrons to form a magnesium ion with a 2- charge
• loses 2 electrons to form a magnesium ion with a 2+ charge
• gains 2 electrons to form a magnesium ion with a 2+ charge

Magnesium and other alkaline earth atoms form cations with a 2+ charge. To get that positive charge, you need 2 more protons than electrons.

The electron dot diagram shows how many lone electron pairs are present, which is similar to the valence on the atom.

You're on track to learn more about chemical bonds and how they work. Your biggest friend when it comes to understanding chemical bonding is the periodic table because it's organized to group elements with similar charges together (for example, all of the alkali metals carry a +1 charge). Electronegativity is a periodic table trend . Atoms with the same electronegativity form nonpolar covalent bonds. Atoms with similar but not identical electronegativity (two different nonmetals) form polar covalent bonds. When the electronegativity difference is large (think metals with nonmetals), you get ionic bonds.

When you balance chemical formulas, remember the electrical charges cancel out. So, if you have two positive charges, you form a neutral compound if it bonds with two negative charges.

From here, you might want to review the types of chemical bonds  and how chemical formulas work . If you're ready for another quiz, see if you understand the basics about atoms and their parts .

Bravo! You understand how chemical bonds form and how electrons are transferred or shared to form ions and compounds. If you're ever in doubt about the type of bonds formed between atoms, look at their position on the periodic table. Atoms with the same electronegativity (like two oxygen atoms) form nonpolar covalent bonds. Atoms with close electronegativity values (like two nonidentical nonmetals) form polar covalent bonds. If the electronegativity difference is large (between a metal and a nonmetal) then ionic bonds form.

From here, you can test yourself to see if you know the trends in the periodic table or you might wish to review the types of chemical bonds .

If you're ready for another quiz, find out which type of mad scientist you are  or you can practice naming ionic compounds .

• Why Do Atoms Create Chemical Bonds?
• What Are Some Examples of Covalent Compounds?
• What Is a Covalent Bond in Chemistry?
• The Main Types of Chemical Bonds
• Examples of Ionic Bonds and Compounds
• Compounds With Both Ionic and Covalent Bonds
• Polar Bond Definition and Examples
• Predicting Formulas of Compounds with Polyatomic Ions
• Ionic vs. Covalent Bonds: How Are They Different?
• What Type of Bonds Does Carbon Form?
• Atoms and Atomic Theory - Study Guide
• Formulas of Ionic Compounds
• Types of Chemical Bonds in Proteins
• Predicting Formulas of Ionic Compounds
• Bonds Definition in Chemistry
• Electronegativity and Chemical Bonding

Chemical Bonding: Ionic and covalent bonds and polarity

by Anthony Carpi, Ph.D., Adrian Dingle, B.Sc.

Did you know that the 118 elements on the periodic table combine to make millions and millions of chemical compounds? This is because chemical bonds between atoms result in new substances that are very different from the elements they are made of. For example, chlorine can be used as a chemical weapon and yet it combines with sodium, a highly reactive element, to make common table salt.

When a force holds atoms together long enough to create a stable, independent entity, that force can be described as a chemical bond.

The 118 known chemical elements interact with one another via chemical bonds, to create brand new, unique compounds that have entirely different chemical and physical properties than the elements that make them up.

It is helpful to think of chemical bonding as being on a sliding scale, where at one extreme there is pure covalent bonding, and at the other there is pure ionic bonding. Most chemical bonds lie somewhere between those two extremes.

When a chemical bond is formed between two elements, the differences in the electronegativity of the atoms determine where on the sliding scale the bond falls. Large differences in electronegativity favor ionic bonds, no difference creates non-polar covalent bonds, and relatively small differences cause the formation of polar-covalent bonds.

This is an updated version of the module Chemical Bonding (previous version) .

Life on Earth depends on water – we need water to drink, bathe, cool ourselves off on a hot summer day (Figure 1). In fact, evidence suggests that life on Earth began in the water, more specifically in the ocean, which has a combination of water and salts , most prominently common table salt – sodium chloride. But where do water and these common salts appear on the great organizer of the elements , the periodic table? Well they, and millions of other substances, are not found on the most famous of all chemistry references: the periodic table. Why not? The answer is a simple one.

Figure 1 : Life on Earth depends on water, not only for key biological functions but also for pleasure. For example, this relaxing oasis on the Mediterranean Sea, Cala Tío Ximo beach in Benidorm, Spain.

The periodic table organizes the 118 currently recognized chemical elements , but water and sodium chloride are not elements. Rather, both are substances that are made up of a combination of elements in a fixed ratio . Such fixed ratio combinations of those 118 elements are known as compounds .

In its chemical reactions and physical interactions, sodium chloride doesn’t act like the elements that make it up (sodium and chlorine); rather, it acts as a completely different and unique substance. That’s a good thing since chlorine is a poisonous gas that has been used as a chemical weapon, and sodium is a highly reactive metal that is mildly explosive with water. So what allows sodium chloride to act in an entirely different way? The answer is that within table salt , sodium and chlorine are joined together by a chemical bond that creates a unique compound , very different from the individual elements that comprise it.

The chemical bond can be thought of as a force that holds the atoms of various elements together in such compounds . It opens up the possibility of millions and millions of combinations of the elements, and the creation of millions and millions of new compounds. In short, the existence of the chemical bonds accounts for the richness of chemistry that reaches far beyond just those 118 building blocks.

• The history of the chemical bond

When discussing the history of chemistry it’s always dangerous to point to the specific origin of an idea, since by its very definition, the scientific process relies upon the gradual refinement of ideas that came before. However, as is the case with a number of such ideas, one can point to certain seminal moments, and in the case of chemical bonding , a famous early 18th century publication provides one such moment.

In his 1704 publication Opticks , Sir Isaac Newton makes mention of a force that points to the modern idea of the chemical bond . In Query 31 of the book, Newton describes ‘forces’ – other than those of magnetism and gravity – that allow ‘particles’ to interact.

In 1718, while translating Opticks into his native language, French chemist Étienne François Geoffroy created an Affinity Table. In this fascinating first look at the likelihood of certain interactions, Geoffroy tabulated the relative affinity that various substances had for other substances, and therefore described the strength of the interactions between those substances.

While Newton and Geoffroy’s work predated our modern understanding of elements and compounds , their work provided insight into the nature of chemical interactions. However, it was over 100 years before the concept of the combining power of elements was understood in a more modern sense. In a paper in the journal Philosophical Transactions entitled “On a new series of organic bodies containing metals” (Frankland, 1852), Edward Frankland describes the “"combining power of elements,” a concept now known as valency in chemistry. Frankland summarized his thoughts by proposing what he described as a ‘law’:

A tendency or law prevails (here), and that, no matter what the characters of the uniting atoms may be, the combining power of the attracting element, if I may be allowed the term, is always satisfied by the same number of these atoms.

Frankland’s work suggested that each element combined with only a limited number of atoms of another element, thus alluding to the concept of bonding . But it was two other scientists who performed the most important contemporary research on the concept of bonding.

In 1916, the American scientist Gilbert N. Lewis published a now famous paper on bonding entitled “The atom and the molecule” (Lewis, 1916). In that paper he outlined a number of important concepts regarding bonding that are still used today as working models of electron arrangement at the atomic level. Most significantly, Lewis developed a theory about bonding based on the number of outer shell, or valence , electrons in an atom. He suggested that a chemical bond was formed when two atoms shared a pair of electrons (later renamed a covalent bond by Irving Langmuir). His "Lewis dot diagrams" used a pair of dots to represent each shared pair of electrons that made up a covalent bond (Figure 2).

Figure 2 : Lewis dot structures for the elements in the first two periods of the periodic table. The structures are written as the element symbol surrounded by dots that represent the valence electrons.

Lewis also championed the idea of ‘octets’ (groups of eight), that a filled valence shell was crucial in understanding electronic configuration as well as the way atoms bond together. The octet had been discussed previously by chemists such as John Newland, who felt it was important, but Lewis advanced the theory .

Comprehension Checkpoint

• The modern chemical bond

While still in college, a young chemist by the name of Linus Pauling familiarized himself with Lewis’s work and began to consider how it might be interpreted within the context of the newly developed field of quantum mechanics . The theory of quantum mechanics, developed in the first half of the 20th century, had redefined our modern understanding of the atom and so any theory of bonding would be incomplete if it were not consistent with this new theory (see our modules Atomic Theory II: Bohr and the Beginnings of Quantum Theory and Atomic Theory III: Wave-Particle Duality and the Electron for more information).

Pauling’s greatest contribution to the field was his book The Nature of the Chemical Bond (Pauling, 1939). In it, he linked the physics of quantum mechanics with the chemical nature of the electron interactions that occur when chemical bonds are made. Pauling’s work concentrated on establishing that true ionic bonds and covalent bonds sit at extreme ends of a bonding spectrum, and that most chemical bonds are classified somewhere between those extremes. Pauling further developed a sliding scale of bond type governed by the electronegativity of the atoms participating in the bond.

Pauling’s immense contributions to our modern understanding of the chemical bond led to his being awarded the 1954 Nobel Prize for "research into the nature of the chemical bond and its application to the elucidation of the structure of complex substances."

• Types of chemical bonds

Chemical bonding and interactions between atoms can be classified into a number of different types. For our purposes we will concentrate on two common types of chemical bonds , namely covalent and ionic bonding.

Molecular bonds are formed when constituent atoms come close enough together such that the outer (valence) electrons of one atom are attracted to the positive nuclear charge of its neighbor. As the independent atoms approach one another, there are both repulsive forces (between the electrons in each atom and between the nuclei of each atom), and attractive forces (between the positive nuclei and the negative valence electrons). Some constituents require the addition of energy , called the activation energy , to overcome the initial repulsive forces. But at various distances, the atoms experience different attractive and repulsive forces, ultimately finding the ideal separation distance where the electrostatic forces are reduced to a minimum. This minimum represents the most stable position, and the distance between the atoms at this point is known as the bond length .

• Covalent bonding

As the name suggests, covalent bonding involves the sharing ( co , meaning joint ) of valence (outer shell) electrons . As described previously, the atoms involved in covalent bonding arrange themselves in order to achieve the greatest energetic stability. And the valence electrons are shared – sometimes equally, and sometimes unequally – between neighboring atoms. The simplest example of covalent bonding occurs when two hydrogen atoms come together to ultimately form a hydrogen molecule , H 2 (Figure 3).

Figure 3 : Here the interaction of two gaseous hydrogen atoms is charted showing the potential energy (purple line) versus the internuclear distance of the atoms (in pm , trillionths of a meter). The observed minimum in potential energy is indicated as the bond length ( r ) between the atoms.

The covalent bond in the hydrogen molecule is defined by the pair of valence electrons (one from each hydrogen atom) that are shared between the atoms , thus giving each hydrogen atom a filled valence shell . Since one shared pair of electrons represents one covalent bond , the hydrogen atoms in a hydrogen molecule are held together with what is known as a single covalent bond, and that can be represented with a single line, thus H-H.

• Multiple covalent bonds

There are many instances where more than one pair of valence electrons are shared between atoms , and in these cases multiple covalent bonds are formed. For example, when four electrons are shared (two pairs), the bond is called a double covalent bond ; in the case of six electrons being shared (three pairs) the bond is called a triple covalent bond.

Common examples of such multiple bonds are those formed between atoms in oxygen and nitrogen gas . In oxygen gas (O 2 ), two atoms share a double bond resulting in the structure O=O. In nitrogen gas (N 2 ), a triple bond exists between two nitrogen atoms, N≡N (Figure 4).

Figure 4 : The bonds between gaseous oxygen and nitrogen atoms. In oxygen gas (O 2 ), two atoms share a double bond resulting in the structure O=O. In nitrogen gas (N 2 ), a triple bond exists between two nitrogen atoms, N≡N.

Double covalent bonds are shorter and stronger than comparable single covalent bonds , and in turn, triple bonds are shorter and stronger than double bonds – nitrogen gas , for example, does not react readily because it is a strongly bonded stable compound .

• Ions and ionic bonding

Ionic bonding occurs when valence electrons are shared so unequally that they spend more time in the vicinity of their new neighbor than their original nuclei. This type of bond is classically described as occurring when atoms interact with one another to either lose or gain electrons. Those atoms that have lost electrons acquire a net positive charge and are called cations , and those that have gained electrons acquire a net negative charge and are referred to as anions . The number of electrons gained or lost by a constituent atom commonly conforms with Lewis’s valence octets, or filled valence shell principle .

In reality even the most classic examples of ionic bonding , such as the sodium chloride bond , contain characteristics of covalent bonding, or sharing of electrons of outer shell electrons. A common misconception is the idea that elements tend to bond with other elements in order to achieve these octets because they are 'stable' or, even worse, 'happy', and that’s what elements 'want'. Elements have no such feelings; rather, the actual reason for bond formation should be considered in terms of the energetic stability arising from the electrostatic interaction of positively charged nuclei with negatively charged electrons.

Substances that are held together by ionic bonds (like sodium chloride) can commonly separate into true charged ions when acted upon by an external force , such as when they dissolve in water. Further, in solid form, the individual atoms are not cleanly attracted to one individual neighbor, but rather they form giant networks that are attracted to one another by the electrostatic interactions between each atom’s nucleus and neighboring valence electrons . The force of attraction between neighboring atoms gives ionic solids an extremely ordered structure known as an ionic lattice , where the oppositely charged particles line up with one another to create a rigid, strongly bonded structure (Figure 5).

Figure 5 : A sodium chloride crystal, showing the rigid, highly organized structure.

The lattice structure of ionic solids conveys certain properties common to ionic substances. These include:

• High melting and boiling points (due to the strong nature of the ionic bonds throughout the lattice).
• An inability to conduct electricity in solid form when the ions are held rigidly in fixed positions within the lattice structure. Ionic solids are insulators . However, ionic compounds are often capable of conducting electricity when molten or in solution when the ions are free to move.
• An ability to dissolve in polar solvents such as water, whose partially charged nature leads to an attraction to the oppositely charged ions in the lattice.

The special properties of ionic solids are discussed in further detail in the module Properties of Solids .

• Lewis dot diagrams

Lewis used dots to represent valence electrons . Lewis dot diagrams (see Figure 1) are a quick and easy way to show the valence electron configuration of individual atoms where no bonds have yet been made.

The dot diagrams can also be used to represent the molecules that are formed when different species bond with one another. In the case of molecules, dots are placed between two atoms to depict covalent bonds , where two dots (a shared pair of electrons) denote a single covalent bond. In the case of the hydrogen molecule discussed above, the two dots in the Lewis diagram represent a single pair of shared electrons and thus a single bond (Figure 6).

Figure 6 : Two hydrogen atoms are connected by a covalent bond. This can be represented by two dots (left) or a single bar (right).

• When is it ionic? When is it covalent?

If ionic bonding and covalent bonding sit at the extreme ends of a bonding spectrum, how do we know where any particular compound sits on that spectrum? Pauling’s theory relies upon the concept of electronegativity , and it is the differences in electronegativity between the atoms that is crucial in determining where any bond might be placed on the sliding scale of bond type.

Pauling’s scale of electronegativity assigns numbers between 0 and 4 to each chemical element . The larger the number, the higher the electronegativity and the greater the attraction that element has for electrons . The difference in electronegativity between two species helps identify the bond type. Ionic bonds are those in which a large difference in electronegativity exists between two bonding species. Large differences in electronegativity usually occur when metals bond to non-metals, so bonds between them tend to be considered ionic.

When the difference in electronegativity between the atoms that make up the chemical bond is less, then sharing is considered to be the predominant interaction, and the bond is considered to be covalent. While it is by no means absolute, some consider the boundary between ionic and covalent bonding to exist when the difference in electronegativity is around 1.7 – less of a difference tends toward covalent, and a larger difference tends towards ionic. Smaller differences in electronegativity usually occur between elements that are both considered non-metals, so most compounds that are made up from two non-metal atoms are considered to be covalent.

• How covalent is covalent?

Once differences in electronegativity have been considered, and a bond has been determined as being covalent, the story is not quite over. Not all covalent bonds are created equally. The only true, perfectly covalent bond will be one where the difference in electronegativity between the two atoms within the bond is equal to zero. When this occurs, each atom has exactly the same attraction for the electrons that make up the covalent bond, and therefore the electrons are perfectly shared. This typically occurs in diatomic (two-atom) molecules such as H 2 , N 2 , O 2 , and those of the halogen compounds when the atoms in the bond are identical.

However, most covalent bonds occur between elements where even though the electronegativity difference is lower than 1.7, it is not zero. In these cases, the electrons are still considered shared, that is, the bond is still considered covalent, but the sharing is not perfect.

• Polarity and dipoles in covalent molecules

Most covalent bonds are formed between atoms of differing electronegativity , meaning that the shared electrons are attracted to one atom within the bond more than the other. As a result, the electrons tend to spend more time at one end of the bond than the other. This sets up what is known as a dipole , literally meaning ‘two poles’. One end of the bond is relatively positive (less attraction for electrons), and one end of the bond is relatively negative (more attraction for electrons). If this difference in electron affinity exists across the molecule , then the molecule is said to be polar – meaning that it will have two different, and opposite, partial charges at either end. Water (H 2 O) is an excellent example of a polar molecule . Electrons are not shared evenly since hydrogen and oxygen have different electronegativities. This creates dipoles in each H-O bond, and these dipoles do not cancel each other out, leaving the water molecule polar overall (Figure 7). (Read more about these bonds in our module Properties of Liquids .)

Figure 7 : In panel A, a molecule of water, H 2 O, is shown with uneven electron sharing resulting in a partial negative charge around the oxygen atom and partial positive charges around the hydrogen atoms. In panel B, three H 2 O molecules interact favorably, forming a dipole-dipole interaction between the partial charges.

When the electrons in a bond are perfectly shared, there is no dipole , and neither end of the bond carries any partial charge . When no such overall charge exists, the molecule is said to be non-polar. An example of such a non-polar molecule is hydrogen, H 2 . In larger molecules with multiple covalent bonds , each bond will have either no dipole or a dipole with varying degrees of partial charge. When all of these dipoles are taken into consideration in three dimensions, the uneven distribution of charge caused by the dipoles may cancel out, making the molecule non-polar.

Alternatively, there may be a partial electrical charge across the molecule , making it a polar molecule. An example of a multiple atom non-polar molecule is carbon dioxide. Electrons are not shared evenly across the C=O bonds since carbon and oxygen have different electronegativities. This creates dipoles in each C=O bond, but because these are aligned oppositely across a linear molecule, with the oxygen atoms on either side of the carbon atom, they cancel via symmetry to leave the carbon dioxide molecule non-polar (Figure 8).

Figure 8 : Electrons are not shared evenly across the C=O bonds in CO 2 and thus it contains two dipoles. Since these two dipoles are opposite to one another across a linear molecule, they cancel via symmetry to leave the carbon dioxide molecule non-polar.

• Other types of bonding and the future

We have limited our discussion to ionic and covalent bonding and the sliding scale of bond type that exists between them. However, many other types of interactions and bonds between atoms exist, notably metallic bonding (the attractions that hold metal atoms together in metallic elements), and intermolecular forces (the interactions that exist between, rather than within, covalently bonded molecules). These each involve similar electrostatic interactions to the ones described in ionic and covalent bonds , but even those extensions are far from the end of the bonding story.

In 2014, researchers found the first experimental evidence for a new type of interaction between atoms that had been predicted in the 1980s (Fleming et al., 2014). Named a "vibrational bond," the theory describes a lightweight element (in this case, an isotope of hydrogen) oscillating or "bouncing" between two much heavier atoms (in this case, bromine) and effectively holding the larger atoms together. Donald Fleming, a chemist based at the University of British Columbia in Canada, described the new bond as being "like a Ping Pong ball bouncing between two bowling balls." As research continues, we can expect to understand interactions at the molecular level with increasing sophistication, and with it, a greater understanding of what we call chemical bonding.

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