THC Science

Sulfur as a yellow powder. When melted and cooled quickly it changes into rubbery ribbons of plastic sulfur, an allotropic form.^[1]

Germanium looks metallic, conducts electricity poorly and behaves chemically like a nonmetal.^[2]

About 25 ml of bromine, a liquid at room temperature, and an essential trace element.^[3]

A partially filled ampoule of liquefied xenon, set inside an acrylic cube. Xenon is otherwise a colorless gas at room temperature.

In chemistry, a nonmetal is a chemical element that usually gains one or more electrons when reacting with a metal and forms an acid when combined with oxygen and hydrogen. At room temperature about half are gases, one (bromine) is a liquid, and the rest are solids. Most solid nonmetals are shiny, whereas bromine is colored, and the remaining gaseous nonmetals are colored or colorless. The solids are either hard and brittle or soft and crumbly, and tend to be poor conductors of heat and electricity and have no structural uses (as is the case for nonmetals generally).

There is no universal agreement on which elements are nonmetals; the numbers generally range from fourteen to twenty-three, depending on the criterion or criteria of interest.

Different kinds of nonmetallic elements include, for example, (i) noble gases; (ii) halogens; (iii) elements such as silicon, which are sometimes instead called metalloids; and (iv) several remaining nonmetals, such as hydrogen and selenium. The latter have no widely recognised collective name and are hereafter informally referred to as "unclassified nonmetals". Metalloids have a predominately (weak) nonmetallic chemistry. The unclassified nonmetals are moderately nonmetallic, on a net basis. Halogens, such as bromine, are characterized by stronger nonmetallic properties and a tendency to form predominantly ionic compounds with metals. Noble gases such as xenon are distinguished by their reluctance to form compounds.

The distinction between different kinds of nonmetals is not absolute. Boundary overlaps, including with the metalloids, occur as outlying elements among each of the kinds of nonmetals show or begin to show less-distinct, hybrid-like, or atypical properties.

Although five times more elements are metals than nonmetals, two of the nonmetals—hydrogen and helium—make up about 99% of the observable universe by mass.^[4] Another nonmetal, oxygen, makes up almost half of the Earth's crust, oceans, and atmosphere.^[5]

Nonmetals largely exhibit a breadth of roles in sustaining life. Living organisms are composed almost entirely of the nonmetals hydrogen, oxygen, carbon, and nitrogen.^[6] A near-universal use for nonmetals is in medicine and pharmaceuticals.

Definition and applicable elements

There is no rigorous definition of a nonmetal.^[7] Broadly, any element lacking a preponderance of metallic properties such as luster, deformability, and good electrical conductivity,^{[n 1]} can be regarded as a nonmetal.^[11] Some variation may be encountered among authors as to which elements are regarded as nonmetals.

The fourteen elements effectively always recognized as nonmetals are hydrogen, oxygen, nitrogen, and sulfur; the corrosive halogens fluorine, chlorine, bromine, and iodine; and the noble gases helium, neon, argon, krypton, xenon, and radon.^{[n 2]} Up to a further nine elements can be counted as nonmetals, including carbon, phosphorus, and selenium; and the elements otherwise commonly recognized as metalloids namely boron; silicon and germanium; arsenic and antimony; and tellurium, bringing the total up to twenty-three nonmetals.^[14]

Astatine, the fifth halogen, is often ignored on account of its rarity and intense radioactivity;^[15] it is here regarded as a metal.^{[n 3]} The superheavy elements copernicium (Z = 112) and oganesson (118) may turn out to be nonmetals; their actual status is not known.^{[n 4]}

Since there are 118 known elements,^[35] as of September 2021, the nonmetals are outnumbered by the metals several times.

Boron, shown here in the form of its β-rhombohedral phase (its most thermodynamically stable form)^[36]
Carbon (as graphite). Delocalized valence electrons within the layers of graphite give it a metallic appearance.^[37]
Liquid oxygen (LOX) boiling. The higher density of LOX increases the likelihood of excitation interactions between two O₂ molecules and a photon that result in a blue color.^[38]
A test tube of pale yellow liquid fluorine in a cryogenic bath. Unlike its next door neighbor oxygen, which is colorless as a gas, fluorine retains its yellow coloration in gaseous form.^[39]

Origin and use of the term

The distinction between metals and nonmetals arose, in a convoluted manner, from a crude recognition of natural kinds^{[n 5]} of matter. Thus, matter could be divided into pure substances and mixtures; pure substances eventually could be distinguished as compounds and elements; and "metallic" elements seemed to have broadly distinguishable attributes that other elements did not, such as their ability to conduct heat or for their "earths" (oxides) to form basic solutions in water, quicklime (CaO) for example.^[44] Use of the word nonmetal can be traced to as far back as Lavoisier's 1789 work Traité élémentaire de chimie in which he distinguished between simple metallic and nonmetallic substances.^{[n 6]}

Honing the concept

Any one or more of a range of properties have been used to hone the distinction between metals and nonmetals, including:

Physical—fusibility, malleability and ductility;^[46] opacity;^[47] bulk coordination number;^[48] minimum excitation potential;^[49] sonorousness;^[50] physical state;^[51] critical temperature;^[52] Goldhammer-Herzfeld metallicity criterion ratio;^[53] enthalpy of vaporization;^[54] liquid range;^[55] temperature coefficient of resistivity;^[56] atomic conductance;^[57] packing efficiency;^[58] 3D electrical conductivity;^[59] electrical conductivity at absolute zero;^[60] thermal conductivity;^[61]

Chemical—cation formation;^[62] acid-base character of oxides;^[63] sulfate formation;^[64] oxide solubility in acids;^[65] or

Electrical—electron configuration^[66] and band structure.^[60]

Johnson^[51] noted that physical properties can best indicate the metallic or nonmetallic properties of an element, with the proviso that other properties will be needed in a number of ambiguous cases.

Kneen at al.^[67] added that:

"It is merely necessary to establish and apply a criterion of metallicity…many arbitrary classifications are possible, most of which, if chosen reasonably, would be similar, but not necessarily identical…the relevance of the criterion can only be judged by the usefulness of the related classification."

Once a basis for distinguishing between the "two great classes of elements"^[68] is established, the nonmetals are found to be those lacking the properties of metals,^[69] to greater or lesser degrees.^[70]

Properties

Physical

**% packing efficiencies of non-gaseous nonmetals**
*(with nearby metals for comparison)*^[71]
Group
13	14	15	16	17^{[n 7]}
B 38	C 17
Al 74	Si 34	S 19
Ga 39	Ge 34	As 38	Se 24	Br 15
In 68	Sn 53	Sb 41	Te 36	I 24
Tl 74	Pb 74	Bi 43	Po 53	At 74
Most metals, such as those in a gray cell,^{[n 8]} have close-packed centro-symmetrical structures featuring metallic bonding and a packing efficiency of at least 68%.^{[n 9]} Nonmetals, and some nearby metals (Ga, Sn, Bi, Po) have more open-packed directional structures featuring either covalent or partial covalent bonding and, subsequently, lower packing densities.

Physically, nonmetals in their most stable forms exist as either polyatomic solids (carbon, for example) with open-packed forms; diatomic molecules such as hydrogen (a gas) and bromine (a liquid); or monatomic gases (such as neon). They usually have small atomic radii. Metals, in contrast, are nearly all solid and close-packed, and mostly have larger atomic radii.^[75] Other than sulfur, solid nonmetals have a submetallic appearance and are brittle, as opposed to metals, which are lustrous, and generally ductile or malleable. Nonmetals usually have lower densities than metals; are mostly poorer conductors of heat and electricity; and tend to have significantly lower melting points and boiling points.^[76]

The physical differences between metals and nonmetals arise from internal and external atomic forces. Internally, an atom's nuclear charge acts to hold its valence electrons in place. Externally, the same electrons are subject to attractive forces from the nuclear charges in nearby atoms. When the external forces are greater than, or equal to, the internal force, valence electrons are expected to become itinerant and metallic properties are predicted. Otherwise nonmetallic properties are anticipated.^[77]

Chemical

Chemically, nonmetals mostly have higher ionization energies, higher electron affinities,^{[n 10]} higher electronegativity values, and higher standard reduction potentials than metals. Here, and in general, the higher an element's ionization energy, electron affinity, electronegativity, or standard reduction potentials, the more nonmetallic that element is.^[79]

In chemical reactions, nonmetals tend to gain or share electrons unlike metals which tend to donate electrons. More specifically, and given the stability of the noble gases, nonmetals generally gain a number of electrons sufficient to give them the electron configuration of the following noble gas whereas metals tend to lose electrons sufficient to leave them with the electron configuration of the preceding noble gas.^{[n 11]} For nonmetallic elements this tendency is encapsulated by the duet and octet rules of thumb (and for metals there is a less rigorously followed 18-electron rule). A key attribute of nonmetals is that they never form basic oxides; their oxides are generally acidic.^[81] Moreover, solid nonmetals (including metalloids) react with nitric acid to form an oxide (carbon, silicon, sulfur, antimony, and tellurium) or an acid (boron, phosphorus, germanium, selenium, arsenic, iodine).^[41]

Some typical chemistry-based
differences between nonmetals and metals^[82]
Aspect	Nonmetals	Metals
In aqueous solution^[83]	Exist as anions or oxyanions^{[n 12]}	Exist as cations
Oxidation states	Negative or positive	Positive
Bonding	Covalent between nonmetals	Metallic between metals (via alloy formation)
Bonding	Ionic between nonmetals and metals
Oxides	Acidic	Basic in lower oxides; increasingly acidic in higher oxides

The chemical differences between metals and nonmetals largely arise from the attractive force between the positive nuclear charge of an individual atom and its negatively charged valence electrons. From left to right across each period of the periodic table the nuclear charge increases as the number of protons in the core increases.^[85] There is an associated reduction in atomic radius^[86] as the increasing nuclear charge draws the valence electrons closer to the core.^[87] In metals, the nuclear charge is generally weaker than that of nonmetallic elements. In chemical bonding, metals therefore tend to lose electrons, and form positively charged or polarized atoms or ions whereas nonmetals tend to gain those same electrons due to their stronger nuclear charge, and form negatively charged ions or polarized atoms.^[88]

The number of compounds formed by nonmetals is vast.^[89] The first nine places in a "top 20" table of elements most frequently encountered in 8,427,300 compounds, as listed in the Chemical Abstracts Service register for July 1987, were occupied by nonmetals. Hydrogen, carbon, oxygen and nitrogen were found in the majority (greater than 64%) of compounds. Silicon, a metalloid, was in 10th place. The highest rated metal, with an occurrence frequency of 2.3%, was iron, in 11th place.^[90] Examples of nonmetal compounds are: boric acid H
₃BO
₃, used in ceramic glazes; selenocysteine; C
₃H
₇NO
₂Se, the 21st amino acid of life;^[91] phosphorus sesquisulfide (P₄S₃), in strike anywhere matches; and teflon (C
₂F
₄)_n.^[92]

Complications

Complicating the chemistry of the nonmetals are the anomalies seen in the first row of each periodic table block, particularly in hydrogen, (boron), carbon, nitrogen, oxygen and fluorine; secondary periodicity or non-uniform periodic trends going down most of the p-block groups;^[93] and unusual valence states in the heavier nonmetals.

First row anomaly. The first row anomaly largely arises from the electron configurations of the elements concerned. Hydrogen is noted for the different ways it forms bonds. It most commonly forms covalent bonds.^[94] It can lose its single valence electron in aqueous solution, leaving behind a bare proton with tremendous polarizing power. This subsequently attaches itself to the lone electron pair of an oxygen atom in a water molecule, thereby forming the basis of acid-base chemistry.^[95] A hydrogen atom in a molecule can form a second, weaker, bond with an atom or group of atoms in another molecule. Such bonding, "helps give snowflakes their hexagonal symmetry, binds DNA into a double helix; shapes the three-dimensional forms of proteins; and even raises water's boiling point high enough to make a decent cup of tea."^[96]

From boron to neon, since the 2p subshell has no inner analogue and experiences no electron repulsion effects it has a relatively small radius, unlike the 3p, 4p and 5p subshells of heavier elements.^[97]^{[n 13]} Ionization energies and electronegativities among these elements are consequently higher than would otherwise be expected, having regard to periodic trends. The small atomic radii of carbon, nitrogen, and oxygen facilitate the formation of triple or double bonds.^[98]

Secondary periodicity. Immediately after the first row of the transition metals, the 3d electrons in the 4th row of periodic table elements, i.e. in gallium (a metal), germanium, arsenic, selenium, and bromine, are not as effective at shielding the increased nuclear charge. The net result, especially for the group 13–15 elements, is that there is an alternation in some periodic trends going down groups 13 to 17.^[99]^{[n 14]}

Unusual valence states. The larger atomic radii of the heavier group 15–18 nonmetals enable higher bulk coordination numbers, and result in lower electronegativity values that better tolerate higher positive charges. The elements involved are thereby able to exhibit valences other than the lowest for their group (that is, 3, 2, 1, or 0) for example in phosphorus pentachloride (PCl₅), sulfur hexafluoride (SF₆), iodine heptafluoride (IF₇), and xenon difluoride (XeF₂).^[101]

Subclasses

Approaches to classifying nonmetals may involve from as few as two subclasses to up to six or seven. For example, the Encyclopedia Britannica periodic table has noble gases, halogens, and other nonmetals, and splits the elements commonly recognized as metalloids between the "other metals" and the "other nonmetals";^[116] the Royal Society of Chemistry periodic table shows the nonmetallic elements as occupying seven groups.^[117]

From right to left in periodic table terms, three or four kinds of nonmetals are more or less commonly discerned.^{[n 17]} These are:

the relatively inert noble gases;
a set of chemically strong halogen elements—fluorine, chlorine, bromine and iodine—sometimes referred to as nonmetal halogens^[130] (the term used here) or stable halogens;^[131]
a set of unclassified nonmetals, including elements such as hydrogen, carbon, nitrogen, and oxygen, with no widely recognized collective name; and
the chemically weak nonmetallic metalloids,^[132] sometimes considered to be nonmetals and sometimes not.^{[n 18]}

Since the metalloids occupy frontier territory, where metals meet nonmetals, their treatment varies from author to author. Some consider them separate from both metals and the nonmetals; some regard them as nonmetals^[134] or as a sub-class of nonmetals;^[135] others count some of them as metals, for example, arsenic and antimony due to their similarities with heavy metals.^[136]^{[n 19]} Metalloids are here treated as nonmetals in light of their chemical behavior, and for comparative purposes.

Aside from the metalloids, some boundary fuzziness and overlapping (as occurs with classification schemes generally) can be discerned among the other nonmetal subclasses. Carbon, phosphorus, selenium, iodine border the metalloids and show some metallic character, as does hydrogen. Among the noble gases, radon is the most metallic and begins to show some cationic behavior, which is unusual for a nonmetal.^[146]

Noble gases

Some property spans and average values
for the subclasses of nonmetallic elements^[147]
Property	Metalloid	Unclassified nonmetal	Nonmetal halogen	Noble gas

Atomic radii (Å), periods 2 to 4 ^{[n 20]}
Span	2.05 to 2.31	1.9 to 2.24	1.63 to 2.19	1.56 to 2.12
Average	2.25	2.04	1.96	1.88
Ionization energy (kJ mol⁻¹)
Span	768 to 953	947 to 1,320	1,015 to 1,687	1,037 to 2,372
Average	855	1,158	1,276	1,590
Electron affinity (kJ mol⁻¹)
Span	27 to 190	−0.07 to 200	295 to 349	−120 to −50
Average	108	134	324	−79
Electronegativity (Allred-Rochow)
Span	1.9 to 2.18	2.19 to 3.44	2.66 to 3.98	2.1 to 5.2
Average	2.05	2.65	3.19	3.38
Standard reduction potential (V)
Span	−0.91 to 0.93	0.00 to 2.08	0.53 to 2.87	2.12 to 2.26
Average	−0.09	0.55	1.48	2.26
Average	4.77	6.76	8.5	8.6
Goldhammer-Herzfeld criterion ratio (unit less)
Span	0.87–1.09	0.07–0.95	0.1–0.77	0.02–0.16
Average	0.99	0.50^{[n 21]}	0.39	0.16
Average values of atomic radius, ionization energy, electron affinity, electronegativity,^{[n 22]} and standard reduction potential generally show a left to right increase consistent with increased nonmetallic character. Electron affinity values collapse at the noble gases due to their filled outer orbitals. Electron affinity can be defined as, "the energy required to remove the electron of a gaseous anion of −1 charge to produce a gaseous atom of that element e.g. Cl⁻(g) → e⁻ = 348.8 kJ mol⁻¹"; the zeroth ionization energy, in other words.^[154] The standard reduction potentials are for stable species in water, at pH 0, within the range −3 to 3 V.^[155] The values in the noble gas column are for xenon only. The Goldhammer-Herzfeld ratio ^[156] is an approximate (non-relativistic) measure of how metallic an element is, metals having values ≥ 1. It quantifies the explanation given for the differences between metals and nonmetals set out at the end of the Properties section.^{[n 23]}

Six nonmetals are classified as noble gases: helium, neon, argon, krypton, xenon, and the radioactive radon. In conventional periodic tables they occupy the rightmost column. They are called noble gases in light of their characteristically very low chemical reactivity.^[157]

They have very similar properties, all being colorless, odorless, and nonflammable. With their closed valence shells the noble gases have feeble interatomic forces of attraction resulting in very low melting and boiling points.^[158] That is why they are all gases under standard conditions, even those with atomic masses larger than many normally solid elements.^[159]

Chemically, the noble gases have relatively high ionization energies, nil or negative electron affinities, and relatively high electronegativities. Compounds of the noble gases number in the hundreds although the list continues to grow,^[160] with most of these occurring via oxygen or fluorine combining with either krypton, xenon or radon.^[161]

In periodic table terms, an analogy can be drawn between the noble gases and noble metals such as platinum and gold, with the latter being similarly reluctant to enter into chemical combination.^[162]

Nonmetal halogens

While the nonmetal halogens are corrosive and markedly reactive elements, they can be found in such innocuous compounds as ordinary table salt NaCl. Their remarkable chemical activity as nonmetals can be contrasted with the equally remarkable chemical activity of the alkali metals such as sodium and potassium, located at the far left of the periodic table.^{[n 24]}^[164]

Physically, fluorine and chlorine are pale yellow and yellowish green gases; bromine is a reddish-brown liquid; and iodine is a silvery metallic solid.^{[n 25]} Electrically, the first three are insulators while iodine is a semiconductor (along its planes).^[165]

Chemically, they have high ionization energies, electron affinities, and electronegativity values, and are mostly relatively strong oxidizing agents.^[166] Manifestations of this status include their intrinsically corrosive nature.^[167] All four exhibit a tendency to form predominately ionic compounds with metals^[168] whereas the remaining nonmetals, bar oxygen, tend to form predominately covalent compounds with metals.^{[n 26]} The reactive and strongly electronegative nature of the nonmetal halogens represents the epitome of nonmetallic character.^[172]

In periodic table terms, the counterparts of the highly nonmetallic halogens, in group 17 are the highly reactive alkali metals, such as sodium and potassium, in group 1.^[173]^{[n 27]}

Unclassified nonmetals

After the nonmetallic elements are classified as either noble gases, halogens or metalloids (following), the remaining seven nonmetals are hydrogen, carbon, nitrogen, oxygen, phosphorus, sulfur and selenium. Three are colorless gases (H, N, O); three have a metal-like appearance (C, P, Se);^{[n 28]} and one is yellow (S). Electrically, graphitic carbon is a semimetal (along its planes);^{[n 29]} phosphorus and selenium are semiconductors;^[178] and hydrogen, nitrogen, oxygen, and sulfur are insulators.^{[n 30]}

They are generally regarded as being too diverse to merit a collective examination,^[180]^[91] and have been referred to as other nonmetals,^[181] or more plainly as nonmetals, located between metalloids and halogens.^[182] Consequently, their chemistry tends to be taught disparately, according to their four respective periodic table groups,^[180] for example: hydrogen in group 1; the group 14 carbon nonmetals (carbon, and possibly silicon and germanium); the group 15 pnictogen nonmetals (nitrogen, phosphorus, and possibly arsenic and antimony); and the group 16 chalcogen nonmetals (oxygen, sulfur, selenium, and possibly tellurium). Other subdivisions are possible according to the individual preferences of authors.^{[n 31]}

Hydrogen, in particular, behaves in some respects like a metal and in others like a nonmetal.^[184] Like a metal it can (first) lose its single valence electron;^[185] it can stand in for alkali metals in typical alkali metal structures;^[186] and is capable of forming alloy-like hydrides, featuring metallic bonding, with some transition metals.^[187] On the other hand, it is an insulating diatomic gas, like a typical nonmetal, and in chemical reactions more generally, it has a tendency to attain the electron configuration of helium.^[188] It does this by way of forming a covalent or ionic bond^[187] or, if its has lost its valence electron, attaching itself to a lone pair of electrons.^[189]

Some or all of these nonmetals nevertheless have several shared properties. Their physical and chemical character is "moderately non-metallic", on a net basis.^[91] Being less reactive than the halogens,^[190] most of them, except for phosphorus, can occur naturally in the environment.^[16] They have prominent biological^[191]^[192] and geochemical aspects.^[91] When combined with halogens, unclassified nonmetals form (polar) covalent bonds.^[193] When combined with metals they can form hard (interstitial or refractory) compounds,^[194] in light of their relatively small atomic radii and sufficiently low ionization energy values.^[91] Unlike the halogens, unclassified nonmetals show a tendency to catenate, especially in solid-state compounds.^[195]^[91] Diagonal relationships among these nonmetals echo similar relationships among the metalloids.^[196]^{[n 32]}

In periodic table terms, a geographic analogy is seen between the unclassified nonmetals and transition metals. The unclassified nonmetals occupy territory between the strongly nonmetallic halogens on the right and the weakly nonmetallic metalloids on the left. The transition metals occupy territory, "between the 'virulent and violent' metals on the left of the periodic table, and the 'calm and contented' metals to the right...[and]...form "a transitional bridge between the two".^[203]

Metalloids

The six elements more commonly recognized as metalloids are boron, silicon, germanium, arsenic, antimony, and tellurium, with each having a metal appearance.^{[n 33]} On a standard periodic table, they occupy a diagonal area in the p-block extending from boron at the upper left to tellurium at lower right, along the dividing line between metals and nonmetals shown on some periodic tables.^[12]

They are brittle and only fair conductors of electricity and heat. Boron, silicon, germanium, tellurium are semiconductors. Arsenic and antimony have the electronic band structures of semimetals although both have less stable semiconducting allotropes.^[12]

Chemically the metalloids generally behave like (weak) nonmetals. Among the nonmetallic elements they tend to have the lowest ionization energies, electron affinities, and electronegativity values; and are relatively weak oxidizing agents. They further demonstrate a tendency to form alloys with metals.^[12]

Like hydrogen among the unclassified nonmetals, boron is chemically similar to metals in some respects.^[205]^{[n 34]} It has fewer electrons than orbitals available for bonding. Analogies with transition metals occur in the formation of complexes,^[207] and adducts (for example, BH₃ + CO →BH₃CO and, similarly, Fe(CO)₄ + CO →Fe(CO)₅),^{[n 35]} as well as in the geometric and electronic structures of cluster species such as [B₆H₆]²⁻ and [Ru₆(CO)₁₈]²⁻.^[209]

To the left of the weakly nonmetallic metalloids, in periodic table terms, are found an indeterminate set of weakly metallic metals (such as tin, lead and bismuth)^[210] sometimes referred to as post-transition metals.^[211]

Comparison

Properties of metals and those of the (sub)classes of metalloids, unclassified nonmetals, nonmetal halogens, and noble gases are summarized in the following two tables. Physical properties apply to elements in their most stable forms in ambient conditions, unless otherwise specified, and are listed in loose order of ease of determination. Chemical properties are listed from general to specific, and then to descriptive. The dashed line around the metalloids denotes that, depending on the author, the elements involved may or may not be recognized as a distinct class or subclass of elements. Metals are included as a reference point.