In chemistry and physics, valence electrons are electrons in the outermost shell of an atom, and that can participate in the formation of a chemical bond if the outermost shell is not closed. In a single covalent bond, a shared pair forms with both atoms in the bond each contributing one valence electron.
The presence of valence electrons can determine the element's chemical properties, such as its valence—whether it may bond with other elements and, if so, how readily and with how many. In this way, a given element's reactivity is highly dependent upon its electronic configuration. For a main-group element, a valence electron can exist only in the outermost electron shell; for a transition metal, a valence electron can also be in an inner shell.
An atom with a closed shell of valence electrons (corresponding to a noble gas configuration) tends to be chemically inert. Atoms with one or two valence electrons more than a closed shell are highly reactive due to the relatively low energy to remove the extra valence electrons to form a positive ion. An atom with one or two electrons fewer than a closed shell is reactive due to its tendency either to gain the missing valence electrons and form a negative ion, or else to share valence electrons and form a covalent bond.
Similar to a core electron, a valence electron has the ability to absorb or release energy in the form of a photon. An energy gain can trigger the electron to move (jump) to an outer shell; this is known as atomic excitation. Or the electron can even break free from its associated atom's shell; this is ionization to form a positive ion. When an electron loses energy (thereby causing a photon to be emitted), then it can move to an inner shell which is not fully occupied.
Overview
Electron configuration
The electrons that determine valence – how an atom reacts chemically – are those with the highest energy.
For a main-group element, the valence electrons are defined as those electrons residing in the electronic shell of highest principal quantum number n. Thus, the number of valence electrons that it may have depends on the electron configuration in a simple way. For example, the electronic configuration of phosphorus (P) is 1s2 2s2 2p6 3s2 3p3 so that there are 5 valence electrons (3s2 3p3), corresponding to a maximum valence for P of 5 as in the molecule PF5; this configuration is normally abbreviated to [Ne] 3s2 3p3, where [Ne] signifies the core electrons whose configuration is identical to that of the noble gas neon.
However, transition elements have (n−1)d energy levels that are very close in energy to the ns level. So as opposed to main-group elements, a valence electron for a transition metal is defined as an electron that resides outside a noble-gas core. Thus, generally, the d electrons in transition metals behave as valence electrons although they are not in the outermost shell. For example, manganese (Mn) has configuration 1s2 2s2 2p6 3s2 3p6 4s2 3d5; this is abbreviated to [Ar] 4s2 3d5, where [Ar] denotes a core configuration identical to that of the noble gas argon. In this atom, a 3d electron has energy similar to that of a 4s electron, and much higher than that of a 3s or 3p electron. In effect, there are possibly seven valence electrons (4s2 3d5) outside the argon-like core; this is consistent with the chemical fact that manganese can have an oxidation state as high as +7 (in the permanganate ion: MnO−
4). (But note that merely having that number of valence electrons does not imply that the corresponding oxidation state will exist. For example, fluorine is not known in oxidation state +7; and although the maximum known number of valence electrons is 16 in ytterbium and nobelium, no oxidation state higher than +9 is known for any element.)
The farther right in each transition metal series, the lower the energy of an electron in a d subshell and the less such an electron has valence properties. Thus, although a nickel atom has, in principle, ten valence electrons (4s2 3d8), its oxidation state never exceeds four. For zinc, the 3d subshell is complete in all known compounds, although it does contribute to the valence band in some compounds. Similar patterns hold for the (n−2)f energy levels of inner transition metals.
The d electron count is an alternative tool for understanding the chemistry of a transition metal.
The number of valence electrons
The number of valence electrons of an element can be determined by the periodic table group (vertical column) in which the element is categorized. In groups 1–12, the group number matches the number of valence electrons; in groups 13–18, the units digit of the group number matches the number of valence electrons. (Helium is the sole exception.)
| 1 | 2 | 3 | 4 | 5 | 6 | 7 | 8 | 9 | 10 | 11 | 12 | 13 | 14 | 15 | 16 | 17 | 18 | |||||||||||||||
|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|
| 1 | H 1 | He 2 | ||||||||||||||||||||||||||||||
| 2 | Li 1 | Be 2 | B 3 | C 4 | N 5 | O 6 | F 7 | Ne 8 | ||||||||||||||||||||||||
| 3 | Na 1 | Mg 2 | Al 3 | Si 4 | P 5 | S 6 | Cl 7 | Ar 8 | ||||||||||||||||||||||||
| 4 | K 1 | Ca 2 | Sc 3 | Ti 4 | V 5 | Cr 6 | Mn 7 | Fe 8 | Co 9 | Ni 10 | Cu 11 | Zn 12 | Ga 3 | Ge 4 | As 5 | Se 6 | Br 7 | Kr 8 | ||||||||||||||
| 5 | Rb 1 | Sr 2 | Y 3 | Zr 4 | Nb 5 | Mo 6 | Tc 7 | Ru 8 | Rh 9 | Pd 10 | Ag 11 | Cd 12 | In 3 | Sn 4 | Sb 5 | Te 6 | I 7 | Xe 8 | ||||||||||||||
| 6 | Cs 1 | Ba 2 | La 3 | Ce 4 | Pr 5 | Nd 6 | Pm 7 | Sm 8 | Eu 9 | Gd 10 | Tb 11 | Dy 12 | Ho 13 | Er 14 | Tm 15 | Yb 16 | Lu 3 | Hf 4 | Ta 5 | W 6 | Re 7 | Os 8 | Ir 9 | Pt 10 | Au 11 | Hg 12 | Tl 3 | Pb 4 | Bi 5 | Po 6 | At 7 | Rn 8 |
| 7 | Fr 1 | Ra 2 | Ac 3 | Th 4 | Pa 5 | U 6 | Np 7 | Pu 8 | Am 9 | Cm 10 | Bk 11 | Cf 12 | Es 13 | Fm 14 | Md 15 | No 16 | Lr 3 | Rf 4 | Db 5 | Sg 6 | Bh 7 | Hs 8 | Mt 9 | Ds 10 | Rg 11 | Cn 12 | Nh 3 | Fl 4 | Mc 5 | Lv 6 | Ts 7 | Og 8 |
Helium is an exception: despite having a 1s2 configuration with two valence electrons, and thus having some similarities with the alkaline earth metals with their ns2 valence configurations, its shell is completely full and hence it is chemically very inert and is usually placed in group 18 with the other noble gases.
Valence shell
The valence shell is the set of orbitals which are energetically accessible for accepting electrons to form chemical bonds.
For main-group elements, the valence shell consists of the ns and np orbitals in the outermost electron shell. For transition metals the orbitals of the incomplete (n−1)d subshell are included, and for lanthanides and actinides incomplete (n−2)f and (n−1)d subshells. The orbitals involved can be in an inner electron shell and do not all correspond to the same electron shell or principal quantum number n in a given element, but they are all at similar energies.
| Element type | Hydrogen and helium | s- and p-blocks (main-group elements) | d-block (Transition metals) | f-block (Lanthanides and actinides) |
|---|---|---|---|---|
| Valence orbitals |
|
|
|
|
| Electron counting rules | Duet/Duplet rule | Octet rule | 18-electron rule | 32-electron rule |
As a general rule, a main-group element (except hydrogen or helium) tends to react to form a s2p6electron configuration. This tendency is called the octet rule, because each bonded atom has 8 valence electrons including shared electrons. Similarly, a transition metal tends to react to form a d10s2p6 electron configuration. This tendency is called the 18-electron rule, because each bonded atom has 18 valence electrons including shared electrons.
The heavy group 2 elements calcium, strontium, and barium can use the (n−1)d subshell as well, giving them some similarities to transition metals.
Chemical reactions
The number of valence electrons in an atom governs its bonding behavior. Therefore, elements whose atoms have the same number of valence electrons are often grouped together in the periodic table of the elements, especially if they also have the same types of valence orbitals.
The most reactive kind of metallic element is an alkali metal of group 1 (e.g., sodium or potassium); this is because such an atom has only a single valence electron. During the formation of an ionic bond, which provides the necessary ionization energy, this one valence electron is easily lost to form a positive ion (cation) with a closed shell (e.g., Na+ or K+). An alkaline earth metal of group 2 (e.g., magnesium) is somewhat less reactive, because each atom must lose two valence electrons to form a positive ion with a closed shell (e.g., Mg2+).[citation needed]
Within each group (each periodic table column) of metals, reactivity increases with each lower row of the table (from a light element to a heavier element), because a heavier element has more electron shells than a lighter element; a heavier element's valence electrons exist at higher principal quantum numbers (they are farther away from the nucleus of the atom, and are thus at higher potential energies, which means they are less tightly bound).[citation needed]
A nonmetal atom tends to attract additional valence electrons to attain a full valence shell; this can be achieved in one of two ways: An atom can either share electrons with a neighboring atom (a covalent bond), or it can remove electrons from another atom (an ionic bond). The most reactive kind of nonmetal element is a halogen (e.g., fluorine (F) or chlorine (Cl)). Such an atom has the following electron configuration: s2p5; this requires only one additional valence electron to form a closed shell. To form an ionic bond, a halogen atom can remove an electron from another atom in order to form an anion (e.g., F−, Cl−, etc.). To form a covalent bond, one electron from the halogen and one electron from another atom form a shared pair (e.g., in the molecule H–F, the line represents a shared pair of valence electrons, one from H and one from F).[citation needed]
Within each group of nonmetals, reactivity decreases with each lower row of the table (from a light element to a heavy element) in the periodic table, because the valence electrons are at progressively higher energies and thus progressively less tightly bound. In fact, oxygen (the lightest element in group 16) is the most reactive nonmetal after fluorine, even though it is not a halogen, because the valence shells of the heavier halogens are at higher principal quantum numbers.
In these simple cases where the octet rule is obeyed, the valence of an atom equals the number of electrons gained, lost, or shared in order to form the stable octet. However, there are also many molecules that are exceptions, and for which the valence is less clearly defined.
Electrical conductivity
Valence electrons are also responsible for the bonding in the pure chemical elements, and whether their electrical conductivity is characteristic of metals, semiconductors, or insulators.
| 1 | 2 | 3 | 4 | 5 | 6 | 7 | 8 | 9 | 10 | 11 | 12 | 13 | 14 | 15 | 16 | 17 | 18 | |||||||||||||||
|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|
| Group → | ||||||||||||||||||||||||||||||||
| ↓ Period | ||||||||||||||||||||||||||||||||
| 1 | H | He | ||||||||||||||||||||||||||||||
| 2 | Li | Be | B | C | N | O | F | Ne | ||||||||||||||||||||||||
| 3 | Na | Mg | Al | Si | P | S | Cl | Ar | ||||||||||||||||||||||||
| 4 | K | Ca | Sc | Ti | V | Cr | Mn | Fe | Co | Ni | Cu | Zn | Ga | Ge | As | Se | Br | Kr | ||||||||||||||
| 5 | Rb | Sr | Y | Zr | Nb | Mo | Tc | Ru | Rh | Pd | Ag | Cd | In | Sn | Sb | Te | I | Xe | ||||||||||||||
| 6 | Cs | Ba | La | Ce | Pr | Nd | Pm | Sm | Eu | Gd | Tb | Dy | Ho | Er | Tm | Yb | Lu | Hf | Ta | W | Re | Os | Ir | Pt | Au | Hg | Tl | Pb | Bi | Po | At | Rn |
| 7 | Fr | Ra | Ac | Th | Pa | U | Np | Pu | Am | Cm | Bk | Cf | Es | Fm | Md | No | Lr | Rf | Db | Sg | Bh | Hs | Mt | Ds | Rg | Cn | Nh | Fl | Mc | Lv | Ts | Og |
Metallic Network covalent Molecular covalent Single atoms Unknown Background color shows bonding of simple substances in the periodic table. If there are several, the most stable allotrope is considered.
Metallic elements generally have high electrical conductivity when in the solid state. In each row of the periodic table, the metals occur to the left of the nonmetals, and thus a metal has fewer possible valence electrons than a nonmetal. However, a valence electron of a metal atom has a small ionization energy, and in the solid-state this valence electron is relatively free to leave one atom in order to associate with another nearby. This situation characterises metallic bonding. Such a "free" electron can be moved under the influence of an electric field, and its motion constitutes an electric current; it is responsible for the electrical conductivity of the metal. Copper, aluminium, silver, and gold are examples of good conductors.
A nonmetallic element has low electrical conductivity; it acts as an insulator. Such an element is found toward the right of the periodic table, and it has a valence shell that is at least half full (the exception is boron). Its ionization energy is large; an electron cannot leave an atom easily when an electric field is applied, and thus such an element can conduct only very small electric currents. Examples of solid elemental insulators are diamond (an allotrope of carbon) and sulfur. These form covalently bonded structures, either with covalent bonds extending across the whole structure (as in diamond) or with individual covalent molecules weakly attracted to each other by intermolecular forces (as in sulfur). (The noble gases remain as single atoms, but those also experience intermolecular forces of attraction, that become stronger as the group is descended: helium boils at −269 °C, while radon boils at −61.7 °C.)
A solid compound containing metals can also be an insulator if the valence electrons of the metal atoms are used to form ionic bonds. For example, although elemental sodium is a metal, solid sodium chloride is an insulator, because the valence electron of sodium is transferred to chlorine to form an ionic bond, and thus that electron cannot be moved easily.
A semiconductor has an electrical conductivity that is intermediate between that of a metal and that of a nonmetal; a semiconductor also differs from a metal in that a semiconductor's conductivity increases with temperature. The typical elemental semiconductors are silicon and germanium, each atom of which has four valence electrons. The properties of semiconductors are best explained using band theory, as a consequence of a small energy gap between a valence band (which contains the valence electrons at absolute zero) and a conduction band (to which valence electrons are excited by thermal energy).
References
- Petrucci, Ralph H.; Harwood, William S.; Herring, F. Geoffrey (2002). General chemistry: principles and modern applications (8th ed.). Upper Saddle River, N.J: Prentice Hall. p. 339. ISBN 978-0-13-014329-7. LCCN 2001032331. OCLC 46872308.
- The order of filling 3d and 4s orbitals. chemguide.co.uk
- Miessler G.L. and Tarr, D.A., Inorganic Chemistry (2nd edn. Prentice-Hall 1999). p.48.
- Tossell, J. A. (1 November 1977). "Theoretical studies of valence orbital binding energies in solid zinc sulfide, zinc oxide, and zinc fluoride". Inorganic Chemistry. 16 (11): 2944–2949. doi:10.1021/ic50177a056.
- Keeler, James; Wothers, Peter (2014). Chemical Structure and Reactivity (2nd ed.). Oxford University Press. pp. 257–260. ISBN 978-0-19-9604135.
- Chi, Chaoxian; Pan, Sudip; Jin, Jiaye; Meng, Luyan; Luo, Mingbiao; Zhao, Lili; Zhou, Mingfei; Frenking, Gernot (2019). "Octacarbonyl Ion Complexes of Actinides [An(CO)8]+/− (An=Th, U) and the Role of f Orbitals in Metal–Ligand Bonding". Chem. Eur. J. 25 (50): 11772–11784. doi:10.1002/chem.201902625. PMC 6772027. PMID 31276242.
- Greenwood, Norman N.; Earnshaw, Alan (1997). Chemistry of the Elements (2nd ed.). Butterworth-Heinemann. p. 117. ISBN 978-0-08-037941-8.
- Zhou, Mingfei; Frenking, Gernot (2021). "Transition-Metal Chemistry of the Heavier Alkaline Earth Atoms Ca, Sr, and Ba". Accounts of Chemical Research. 54 (15): 3071–3082. doi:10.1021/acs.accounts.1c00277. PMID 34264062. S2CID 235908113.
- Fernández, Israel; Holzmann, Nicole; Frenking, Gernot (2020). "The Valence Orbitals of the Alkaline-Earth Atoms". Chemistry: A European Journal. 26 (62): 14194–14210. doi:10.1002/chem.202002986. PMC 7702052. PMID 32666598.
- Jensen, William B. (2000). "The Periodic Law and Table" (PDF). Archived from the original (PDF) on 2020-11-10. Retrieved 10 December 2022.
External links
- Francis, Eden. Valence Electrons.
In chemistry and physics valence electrons are electrons in the outermost shell of an atom and that can participate in the formation of a chemical bond if the outermost shell is not closed In a single covalent bond a shared pair forms with both atoms in the bond each contributing one valence electron Four covalent bonds Carbon has four valence electrons and here a valence of four Each hydrogen atom has one valence electron and is univalent The presence of valence electrons can determine the element s chemical properties such as its valence whether it may bond with other elements and if so how readily and with how many In this way a given element s reactivity is highly dependent upon its electronic configuration For a main group element a valence electron can exist only in the outermost electron shell for a transition metal a valence electron can also be in an inner shell An atom with a closed shell of valence electrons corresponding to a noble gas configuration tends to be chemically inert Atoms with one or two valence electrons more than a closed shell are highly reactive due to the relatively low energy to remove the extra valence electrons to form a positive ion An atom with one or two electrons fewer than a closed shell is reactive due to its tendency either to gain the missing valence electrons and form a negative ion or else to share valence electrons and form a covalent bond Similar to a core electron a valence electron has the ability to absorb or release energy in the form of a photon An energy gain can trigger the electron to move jump to an outer shell this is known as atomic excitation Or the electron can even break free from its associated atom s shell this is ionization to form a positive ion When an electron loses energy thereby causing a photon to be emitted then it can move to an inner shell which is not fully occupied OverviewElectron configuration The electrons that determine valence how an atom reacts chemically are those with the highest energy For a main group element the valence electrons are defined as those electrons residing in the electronic shell of highest principal quantum number n Thus the number of valence electrons that it may have depends on the electron configuration in a simple way For example the electronic configuration of phosphorus P is 1s2 2s2 2p6 3s2 3p3 so that there are 5 valence electrons 3s2 3p3 corresponding to a maximum valence for P of 5 as in the molecule PF5 this configuration is normally abbreviated to Ne 3s2 3p3 where Ne signifies the core electrons whose configuration is identical to that of the noble gas neon However transition elements have n 1 d energy levels that are very close in energy to the ns level So as opposed to main group elements a valence electron for a transition metal is defined as an electron that resides outside a noble gas core Thus generally the d electrons in transition metals behave as valence electrons although they are not in the outermost shell For example manganese Mn has configuration 1s2 2s2 2p6 3s2 3p6 4s2 3d5 this is abbreviated to Ar 4s2 3d5 where Ar denotes a core configuration identical to that of the noble gas argon In this atom a 3d electron has energy similar to that of a 4s electron and much higher than that of a 3s or 3p electron In effect there are possibly seven valence electrons 4s2 3d5 outside the argon like core this is consistent with the chemical fact that manganese can have an oxidation state as high as 7 in the permanganate ion MnO 4 But note that merely having that number of valence electrons does not imply that the corresponding oxidation state will exist For example fluorine is not known in oxidation state 7 and although the maximum known number of valence electrons is 16 in ytterbium and nobelium no oxidation state higher than 9 is known for any element The farther right in each transition metal series the lower the energy of an electron in a d subshell and the less such an electron has valence properties Thus although a nickel atom has in principle ten valence electrons 4s2 3d8 its oxidation state never exceeds four For zinc the 3d subshell is complete in all known compounds although it does contribute to the valence band in some compounds Similar patterns hold for the n 2 f energy levels of inner transition metals The d electron count is an alternative tool for understanding the chemistry of a transition metal The number of valence electrons The number of valence electrons of an element can be determined by the periodic table group vertical column in which the element is categorized In groups 1 12 the group number matches the number of valence electrons in groups 13 18 the units digit of the group number matches the number of valence electrons Helium is the sole exception 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 181 H 1 He 22 Li 1 Be 2 B 3 C 4 N 5 O 6 F 7 Ne 83 Na 1 Mg 2 Al 3 Si 4 P 5 S 6 Cl 7 Ar 84 K 1 Ca 2 Sc 3 Ti 4 V 5 Cr 6 Mn 7 Fe 8 Co 9 Ni 10 Cu 11 Zn 12 Ga 3 Ge 4 As 5 Se 6 Br 7 Kr 85 Rb 1 Sr 2 Y 3 Zr 4 Nb 5 Mo 6 Tc 7 Ru 8 Rh 9 Pd 10 Ag 11 Cd 12 In 3 Sn 4 Sb 5 Te 6 I 7 Xe 86 Cs 1 Ba 2 La 3 Ce 4 Pr 5 Nd 6 Pm 7 Sm 8 Eu 9 Gd 10 Tb 11 Dy 12 Ho 13 Er 14 Tm 15 Yb 16 Lu 3 Hf 4 Ta 5 W 6 Re 7 Os 8 Ir 9 Pt 10 Au 11 Hg 12 Tl 3 Pb 4 Bi 5 Po 6 At 7 Rn 87 Fr 1 Ra 2 Ac 3 Th 4 Pa 5 U 6 Np 7 Pu 8 Am 9 Cm 10 Bk 11 Cf 12 Es 13 Fm 14 Md 15 No 16 Lr 3 Rf 4 Db 5 Sg 6 Bh 7 Hs 8 Mt 9 Ds 10 Rg 11 Cn 12 Nh 3 Fl 4 Mc 5 Lv 6 Ts 7 Og 8 Helium is an exception despite having a 1s2 configuration with two valence electrons and thus having some similarities with the alkaline earth metals with their ns2 valence configurations its shell is completely full and hence it is chemically very inert and is usually placed in group 18 with the other noble gases Valence shellThe valence shell is the set of orbitals which are energetically accessible for accepting electrons to form chemical bonds For main group elements the valence shell consists of the ns and np orbitals in the outermost electron shell For transition metals the orbitals of the incomplete n 1 d subshell are included and for lanthanides and actinides incomplete n 2 f and n 1 d subshells The orbitals involved can be in an inner electron shell and do not all correspond to the same electron shell or principal quantum number n in a given element but they are all at similar energies Element type Hydrogen and helium s and p blocks main group elements d block Transition metals f block Lanthanides and actinides Valence orbitals 1s ns np ns n 1 d np ns n 2 f n 1 d npElectron counting rules Duet Duplet rule Octet rule 18 electron rule 32 electron rule As a general rule a main group element except hydrogen or helium tends to react to form a s2p6electron configuration This tendency is called the octet rule because each bonded atom has 8 valence electrons including shared electrons Similarly a transition metal tends to react to form a d10s2p6 electron configuration This tendency is called the 18 electron rule because each bonded atom has 18 valence electrons including shared electrons The heavy group 2 elements calcium strontium and barium can use the n 1 d subshell as well giving them some similarities to transition metals Chemical reactionsThe number of valence electrons in an atom governs its bonding behavior Therefore elements whose atoms have the same number of valence electrons are often grouped together in the periodic table of the elements especially if they also have the same types of valence orbitals The most reactive kind of metallic element is an alkali metal of group 1 e g sodium or potassium this is because such an atom has only a single valence electron During the formation of an ionic bond which provides the necessary ionization energy this one valence electron is easily lost to form a positive ion cation with a closed shell e g Na or K An alkaline earth metal of group 2 e g magnesium is somewhat less reactive because each atom must lose two valence electrons to form a positive ion with a closed shell e g Mg2 citation needed Within each group each periodic table column of metals reactivity increases with each lower row of the table from a light element to a heavier element because a heavier element has more electron shells than a lighter element a heavier element s valence electrons exist at higher principal quantum numbers they are farther away from the nucleus of the atom and are thus at higher potential energies which means they are less tightly bound citation needed A nonmetal atom tends to attract additional valence electrons to attain a full valence shell this can be achieved in one of two ways An atom can either share electrons with a neighboring atom a covalent bond or it can remove electrons from another atom an ionic bond The most reactive kind of nonmetal element is a halogen e g fluorine F or chlorine Cl Such an atom has the following electron configuration s2p5 this requires only one additional valence electron to form a closed shell To form an ionic bond a halogen atom can remove an electron from another atom in order to form an anion e g F Cl etc To form a covalent bond one electron from the halogen and one electron from another atom form a shared pair e g in the molecule H F the line represents a shared pair of valence electrons one from H and one from F citation needed Within each group of nonmetals reactivity decreases with each lower row of the table from a light element to a heavy element in the periodic table because the valence electrons are at progressively higher energies and thus progressively less tightly bound In fact oxygen the lightest element in group 16 is the most reactive nonmetal after fluorine even though it is not a halogen because the valence shells of the heavier halogens are at higher principal quantum numbers In these simple cases where the octet rule is obeyed the valence of an atom equals the number of electrons gained lost or shared in order to form the stable octet However there are also many molecules that are exceptions and for which the valence is less clearly defined Electrical conductivityValence electrons are also responsible for the bonding in the pure chemical elements and whether their electrical conductivity is characteristic of metals semiconductors or insulators vteBonding of simple substances in the periodic table1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18Group Period1 H He2 Li Be B C N O F Ne3 Na Mg Al Si P S Cl Ar4 K Ca Sc Ti V Cr Mn Fe Co Ni Cu Zn Ga Ge As Se Br Kr5 Rb Sr Y Zr Nb Mo Tc Ru Rh Pd Ag Cd In Sn Sb Te I Xe6 Cs Ba La Ce Pr Nd Pm Sm Eu Gd Tb Dy Ho Er Tm Yb Lu Hf Ta W Re Os Ir Pt Au Hg Tl Pb Bi Po At Rn7 Fr Ra Ac Th Pa U Np Pu Am Cm Bk Cf Es Fm Md No Lr Rf Db Sg Bh Hs Mt Ds Rg Cn Nh Fl Mc Lv Ts OgMetallic Network covalent Molecular covalent Single atoms Unknown Background color shows bonding of simple substances in the periodic table If there are several the most stable allotrope is considered Metallic elements generally have high electrical conductivity when in the solid state In each row of the periodic table the metals occur to the left of the nonmetals and thus a metal has fewer possible valence electrons than a nonmetal However a valence electron of a metal atom has a small ionization energy and in the solid state this valence electron is relatively free to leave one atom in order to associate with another nearby This situation characterises metallic bonding Such a free electron can be moved under the influence of an electric field and its motion constitutes an electric current it is responsible for the electrical conductivity of the metal Copper aluminium silver and gold are examples of good conductors A nonmetallic element has low electrical conductivity it acts as an insulator Such an element is found toward the right of the periodic table and it has a valence shell that is at least half full the exception is boron Its ionization energy is large an electron cannot leave an atom easily when an electric field is applied and thus such an element can conduct only very small electric currents Examples of solid elemental insulators are diamond an allotrope of carbon and sulfur These form covalently bonded structures either with covalent bonds extending across the whole structure as in diamond or with individual covalent molecules weakly attracted to each other by intermolecular forces as in sulfur The noble gases remain as single atoms but those also experience intermolecular forces of attraction that become stronger as the group is descended helium boils at 269 C while radon boils at 61 7 C A solid compound containing metals can also be an insulator if the valence electrons of the metal atoms are used to form ionic bonds For example although elemental sodium is a metal solid sodium chloride is an insulator because the valence electron of sodium is transferred to chlorine to form an ionic bond and thus that electron cannot be moved easily A semiconductor has an electrical conductivity that is intermediate between that of a metal and that of a nonmetal a semiconductor also differs from a metal in that a semiconductor s conductivity increases with temperature The typical elemental semiconductors are silicon and germanium each atom of which has four valence electrons The properties of semiconductors are best explained using band theory as a consequence of a small energy gap between a valence band which contains the valence electrons at absolute zero and a conduction band to which valence electrons are excited by thermal energy ReferencesPetrucci Ralph H Harwood William S Herring F Geoffrey 2002 General chemistry principles and modern applications 8th ed Upper Saddle River N J Prentice Hall p 339 ISBN 978 0 13 014329 7 LCCN 2001032331 OCLC 46872308 The order of filling 3d and 4s orbitals chemguide co uk Miessler G L and Tarr D A Inorganic Chemistry 2nd edn Prentice Hall 1999 p 48 Tossell J A 1 November 1977 Theoretical studies of valence orbital binding energies in solid zinc sulfide zinc oxide and zinc fluoride Inorganic Chemistry 16 11 2944 2949 doi 10 1021 ic50177a056 Keeler James Wothers Peter 2014 Chemical Structure and Reactivity 2nd ed Oxford University Press pp 257 260 ISBN 978 0 19 9604135 Chi Chaoxian Pan Sudip Jin Jiaye Meng Luyan Luo Mingbiao Zhao Lili Zhou Mingfei Frenking Gernot 2019 Octacarbonyl Ion Complexes of Actinides An CO 8 An Th U and the Role of f Orbitals in Metal Ligand Bonding Chem Eur J 25 50 11772 11784 doi 10 1002 chem 201902625 PMC 6772027 PMID 31276242 Greenwood Norman N Earnshaw Alan 1997 Chemistry of the Elements 2nd ed Butterworth Heinemann p 117 ISBN 978 0 08 037941 8 Zhou Mingfei Frenking Gernot 2021 Transition Metal Chemistry of the Heavier Alkaline Earth Atoms Ca Sr and Ba Accounts of Chemical Research 54 15 3071 3082 doi 10 1021 acs accounts 1c00277 PMID 34264062 S2CID 235908113 Fernandez Israel Holzmann Nicole Frenking Gernot 2020 The Valence Orbitals of the Alkaline Earth Atoms Chemistry A European Journal 26 62 14194 14210 doi 10 1002 chem 202002986 PMC 7702052 PMID 32666598 Jensen William B 2000 The Periodic Law and Table PDF Archived from the original PDF on 2020 11 10 Retrieved 10 December 2022 External linksFrancis Eden Valence Electrons
