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In , a molecule or ion is called chiral () if it cannot be superposed on its by any combination of rotations, translations, and some conformational changes. This geometric property is called chirality (). Organic Chemistry (4th Edition) Paula Y. Bruice. Pearson Educational Books. Organic Chemistry (3rd Edition) Marye Anne Fox, James K. Whitesell Jones & Bartlett Publishers (2004) The terms are derived from ( cheir) 'hand'; which is the example of an object with this property.

A chiral molecule or ion exists in two that are mirror images of each other, called ; they are often distinguished as either "right-handed" or "left-handed" by their absolute configuration or some other criterion. The two enantiomers have the same chemical properties, except when reacting with other chiral compounds. They also have the same properties, except that they often have opposite . A homogeneous mixture of the two enantiomers in equal parts is said to be , and it usually differs chemically and physically from the pure enantiomers.

Chiral molecules will usually have a stereogenic element from which chirality arises. The most common type of stereogenic element is a stereogenic center, or stereocenter. In the case of organic compounds, stereocenters most frequently take the form of a carbon atom with four distinct (different) groups attached to it in a tetrahedral geometry. Less commonly, other atoms like N, P, S, and Si can also serve as stereocenters, provided they have four distinct substituents (including lone pair electrons) attached to them.

A given stereocenter has two possible configurations (R and S), which give rise to stereoisomers ( and ) in molecules with one or more stereocenter. For a chiral molecule with one or more stereocenter, the enantiomer corresponds to the stereoisomer in which every stereocenter has the opposite configuration. An organic compound with only one stereogenic carbon is always chiral. On the other hand, an organic compound with multiple stereogenic carbons is typically, but not always, chiral. In particular, if the stereocenters are configured in such a way that the molecule can take a conformation having a plane of symmetry or an inversion point, then the molecule is achiral and is known as a .

Molecules with chirality arising from one or more stereocenters are classified as possessing central chirality. There are two other types of stereogenic elements that can give rise to chirality, a stereogenic axis () and a stereogenic plane (). Finally, the inherent curvature of a molecule can also give rise to chirality (inherent chirality). These types of chirality are far less common than central chirality. BINOL is a typical example of an axially chiral molecule, while trans-cyclooctene is a commonly cited example of a planar chiral molecule. Finally, possesses helical chirality, which is one type of inherent chirality.

Chirality is an important concept for and . Most substances relevant to are chiral, such as (, , and ), all but one of the that are the building blocks of , and the . Naturally occurring are often chiral, but not always. In living organisms, one typically finds only one of the two enantiomers of a chiral compound. For that reason, organisms that consume a chiral compound usually can metabolize only one of its enantiomers. For the same reason, the two enantiomers of a chiral usually have vastly different potencies or effects.

Definition
The chirality of a molecule is based on the molecular symmetry of its conformations. A conformation of a molecule is chiral if and only if it belongs to the Cn, Dn, T, O, or I (the chiral point groups). However, whether the molecule itself is considered to be chiral depends on whether its chiral conformations are persistent isomers that could be isolated as separated enantiomers, at least in principle, or the conformers rapidly interconvert at a given temperature and timescale through low-energy conformational changes (rendering the molecule achiral). For example, despite having chiral gauche conformers that belong to the C2 point group, is considered achiral at room temperature because rotation about the central C–C bond rapidly interconverts the enantiomers (3.4 kcal/mol barrier). Similarly, cis-1,2-dichlorocyclohexane consists of chair conformers that are nonidentical mirror images, but the two can interconvert via the cyclohexane chair flip (~10 kcal/mol barrier). As another example, amines with three distinct substituents (R1R2R3N:) are also regarded as achiral molecules because their enantiomeric pyramidal conformers rapidly undergo pyramidal inversion.

However, if the temperature in question is low enough, the process that interconverts the enantiomeric chiral conformations becomes slow compared to a given timescale. The molecule would then be considered to be chiral at that temperature. The relevant timescale is, to some degree, arbitrarily defined: 1000 seconds is sometimes employed, as this is regarded as the lower limit for the amount of time required for chemical or chromatographic separation of enantiomers in a practical sense. Molecules that are chiral at room temperature due to restricted rotation about a single bond (barrier to rotation ≥ ca. 23 kcal/mol) are said to exhibit .

A chiral compound can contain no improper axis of rotation ( Sn), which includes planes of symmetry and inversion center. Chiral molecules are always dissymmetric (lacking Sn) but not always asymmetric (lacking all symmetry elements except the trivial identity). Asymmetric molecules are always chiral.Cotton, F. A., "Chemical Applications of Group Theory," John Wiley & Sons: New York, 1990.

The following table shows some examples of chiral and achiral molecules, with the Schoenflies notation of the point group of the molecule. In the achiral molecules, X and Y (with no subscript) represent achiral groups, whereas X and X or Y and Y represent . Note that there is no meaning to the orientation of an S axis, which is just an inversion. Any orientation will do, so long as it passes through the center of inversion. Also note that higher symmetries of chiral and achiral molecules also exist, and symmetries that do not include those in the table, such as the chiral C or the achiral S.

+ Molecular symmetry and chirality
Achiral
inversion center
S2 = i

C

C
Note: This also has a mirror plane.

An example of a molecule that does not have a mirror plane or an inversion and yet would be considered achiral is 1,1-difluoro-2,2-dichlorocyclohexane (or 1,1-difluoro-3,3-dichlorocyclohexane). This may exist in many conformers (conformational isomers), but none of them has a mirror plane. In order to have a mirror plane, the ring would have to be flat, widening the bond angles and giving the conformation a very high energy. This compound would not be considered chiral because the chiral conformers interconvert easily.

An achiral molecule having chiral conformations could theoretically form a mixture of right-handed and left-handed crystals, as often happens with mixtures of chiral molecules (see Chiral resolution#Spontaneous resolution and related specialized techniques), or as when achiral liquid is cooled to the point of becoming chiral .

Stereogenic centers
A stereogenic center (or stereocenter) is an atom such that swapping the positions of two ligands (connected groups) on that atom results in a molecule that is stereoisomeric to the original. For example, a common case is a tetrahedral carbon bonded to four distinct groups a, b, c, and d (C abcd), where swapping any two groups (e.g., C bacd) leads to a stereoisomer of the original, so the central C is a stereocenter. Many chiral molecules have point chirality, namely a single chiral stereogenic center that coincides with an atom. This stereogenic center usually has four or more bonds to different groups, and may be carbon (as in many biological molecules), phosphorus (as in many ), silicon, or a metal (as in many chiral coordination compounds). However, a stereogenic center can also be a trivalent atom whose bonds are not in the same plane, such as in P-chiral phosphines (PRR′R″) and in S-chiral sulfoxides (OSRR′), because a lone-pair of electrons is present instead of a fourth bond.

Similarly, a stereogenic axis (or plane) is defined as an axis (or plane) in the molecule such that the swapping of any two ligands attached to the axis (or plane) gives rise to a stereoisomer. For instance, the C2-symmetric species 1,1′-bi-2-naphthol (BINOL) and 1,3-dichloro have stereogenic axes and exhibit , while ( E)- and many derivatives bearing two or more substituents have stereogenic planes and exhibit .

Chirality can also arise from isotopic differences between atoms, such as in the PhCHDOH; which is chiral and optically active ( αD = 0.715°), even though the non-deuterated compound PhCH2OH is not.

If two enantiomers easily interconvert, the pure enantiomers may be practically impossible to separate, and only the racemic mixture is observable. This is the case, for example, of most amines with three different substituents (NRR′R″), because of the low energy barrier for nitrogen inversion.

When the optical rotation for an enantiomer is too low for practical measurement, the species is said to exhibit .

Chirality is an intrinsic part of the identity of a molecule, so the includes details of the absolute configuration ( R/S, D/L, or other designations).

Manifestations of chirality
  • Flavor: the artificial sweetener has two enantiomers. L-aspartame tastes sweet whereas D-aspartame is tasteless.
  • Odor: R-(–)- smells like whereas S-(+)-carvone smells like .
  • Drug effectiveness: the drug is sold as a mixture. However, studies have shown that only the ( S)-(+) enantiomer () is responsible for the drug's beneficial effects.
  • Drug safety: is used in chelation therapy and for the treatment of rheumatoid arthritis whereas L‑penicillamine is toxic as it inhibits the action of , an essential B vitamin.

In biochemistry
Many biologically active molecules are chiral, including the naturally occurring (the building blocks of ) and .

The origin of this in is the subject of much debate.

(2025). 9783540768852, Springer.
Most scientists believe that Earth life's "choice" of chirality was purely random, and that if carbon-based life forms exist elsewhere in the universe, their chemistry could theoretically have opposite chirality. However, there is some suggestion that early amino acids could have formed in comet dust. In this case, circularly polarised radiation (which makes up 17% of stellar radiation) could have caused the selective destruction of one chirality of amino acids, leading to a selection bias which ultimately resulted in all life on Earth being homochiral.

, which are chiral, often distinguish between the two enantiomers of a chiral substrate. One could imagine an enzyme as having a glove-like cavity that binds a substrate. If this glove is right-handed, then one enantiomer will fit inside and be bound, whereas the other enantiomer will have a poor fit and is unlikely to bind.

L-forms of amino acids tend to be tasteless, whereas D-forms tend to taste sweet. leaves contain the L-enantiomer of the chemical or R-(−)-carvone and seeds contain the D-enantiomer or S-(+)-carvone. The two smell different to most people because our olfactory are chiral.

Chirality is important in context of ordered phases as well, for example the addition of a small amount of an optically active molecule to a nematic phase (a phase that has long range orientational order of molecules) transforms that phase to a chiral nematic phase (or cholesteric phase). Chirality in context of such phases in polymeric fluids has also been studied in this context.

In inorganic chemistry
Chirality is a symmetry property, not a property of any part of the periodic table. Thus many inorganic materials, molecules, and ions are chiral. is an example from the mineral kingdom. Such noncentric materials are of interest for applications in .

In the areas of coordination chemistry and organometallic chemistry, chirality is pervasive and of practical importance. A famous example is tris(bipyridine)ruthenium(II) complex in which the three bipyridine ligands adopt a chiral propeller-like arrangement.von Zelewsky, A. (1995). Stereochemistry of Coordination Compounds. Chichester: John Wiley.. . The two enantiomers of complexes such as Ru(2,2′-bipyridine)32+ may be designated as Λ (capital , the Greek version of "L") for a left-handed twist of the propeller described by the ligands, and Δ (capital delta, Greek "D") for a right-handed twist (pictured). dextro- and levo-rotation (the clockwise and counterclockwise optical rotation of plane-polarized light) uses similar notation, but shouldn't be confused.

Chiral ligands confer chirality to a metal complex, as illustrated by metal- complexes. If the metal exhibits catalytic properties, its combination with a chiral ligand is the basis of asymmetric catalysis.Hartwig, J. F. Organotransition Metal Chemistry, from Bonding to Catalysis; University Science Books: New York, 2010.

Methods and practices
The term is derived from the interaction of chiral materials with polarized light. In a solution, the (−)-form, or form, of an optical isomer rotates the plane of a beam of linearly polarized light . The (+)-form, or form, of an optical isomer does the opposite. The rotation of light is measured using a and is expressed as the optical rotation.

Enantiomers can be separated by chiral resolution. This often involves forming crystals of a salt composed of one of the enantiomers and an acid or base from the so-called of naturally occurring chiral compounds, such as or the amine . Some racemic mixtures spontaneously crystallize into right-handed and left-handed crystals that can be separated by hand. used this method to separate left-handed and right-handed crystals in 1849. Sometimes it is possible to seed a racemic solution with a right-handed and a left-handed crystal so that each will grow into a large crystal.

Liquid chromatography (HPLC and TLC) may also be used as an analytical method for the direct separation of and the control of enantiomeric purity, e.g. active pharmaceutical ingredients (APIs) which are chiral.; Tanwar, S. J. Chromatogr. A 2010, 1395–1398. ()Ravi Bhushan Chem. Rec. 2022, e102100295. ()

Miscellaneous nomenclature
  • Any non- chiral substance is called scalemic. Scalemic materials can be enantiopure or enantioenriched.
  • A chiral substance is enantiopure when only one of two possible enantiomers is present so that all molecules within a sample have the same chirality sense. Use of homochiral as a synonym is strongly discouraged.
  • A chiral substance is enantioenriched or heterochiral when its enantiomeric ratio is greater than 50:50 but less than 100:0.
  • Enantiomeric excess or e.e. is the difference between how much of one enantiomer is present compared to the other. For example, a sample with 40% e.e. of R contains 70% R and 30% S (70% − 30% = 40%).

History
The rotation of plane polarized light by chiral substances was first observed by Jean-Baptiste Biot in 1812, and gained considerable importance in the , analytical chemistry, and pharmaceuticals. deduced in 1848 that this phenomenon has a molecular basis.
(1994). 9780471016700, Wiley & Sons.
The term chirality itself was coined by in 1894. Different enantiomers or diastereomers of a compound were formerly called optical isomers due to their different optical properties. At one time, chirality was thought to be restricted to organic chemistry, but this misconception was overthrown by the resolution of a purely inorganic compound, a cobalt complex called , by in 1911.

In the early 1970s, various groups established that the human olfactory organ is capable of distinguishing chiral compounds.

See also

Further reading

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