IUPAC nomenclature of organic chemistry
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In chemical nomenclature, the IUPAC nomenclature of organic chemistry is a method of naming organic chemical compounds as recommended[1][2] by the International Union of Pure and Applied Chemistry (IUPAC). It is published in the Nomenclature of Organic Chemistry (informally called the Blue Book).[3] Ideally, every possible organic compound should have a name from which an unambiguous structural formula can be created. There is also an IUPAC nomenclature of inorganic chemistry.[4]
To avoid long and tedious names in normal communication, the official IUPAC naming recommendations are not always followed in practice, except when it is necessary to give an unambiguous and absolute definition to a compound. IUPAC names can sometimes be simpler than older names, as with ethanol, instead of ethyl alcohol. For relatively simple molecules they can be more easily understood than non-systematic names, which must be learnt or looked over. However, the common or trivial name is often substantially shorter and clearer, and so preferred. These non-systematic names are often derived from an original source of the compound. Also, very long names may be less clear than structural formulas.
Basic principles
This article needs to be updated. The reason given is: According to current nomenclature, rings are senior to chains and chain length is senior to number of multiple bonds, the list should be revisited and updated as a whole.(February 2020) |
In chemistry, a number of
in the compound.The steps for naming an organic compound are:[5]
- Identification of the most senior group. If more than one functional group, if any, is present, the one with highest group precedence should be used.
- Identification of the ring or chain with the maximum number of senior groups.
- Identification of the ring or chain with the most senior elements (In order: N, P, Si, B, O, S, C).
- Identification of the parent compound. Rings are senior to chains if composed of the same elements.
- For cyclic systems: Identification of the parent cyclic ring. The cyclic system must obey these rules, in order of precedence:
- It should have the most senior heteroatom (in order: N, O, S, P, Si, B).
- It should have the maximum number of rings.
- It should have the maximum number of atoms.
- It should have the maximum number of heteroatoms.
- It should have the maximum number of senior heteroatoms (in order: O, S, N, P, Si, B).
- For chains: Identification of the parent hydrocarbon chain. This chain must obey the following rules, in order of precedence:
- It should have the maximum length.
- It should have the maximum number of heteroatoms.
- It should have the maximum number of senior heteroatoms (in order: O, S, N, P, Si, B).
- For cyclic systems and chains after previous rules:
- It should have the maximum number of multiple, then double bonds.
- It should have the maximum number of substituents of the suffix functional group. By suffix, it is meant that the parent functional group should have a suffix, unlike halogen substituents. If more than one functional group is present, the one with highest group precedence should be used.
- For cyclic systems: Identification of the parent cyclic ring. The cyclic system must obey these rules, in order of precedence:
- Identification of the side-chains. Side chains are the carbon chains that are not in the parent chain, but are branched off from it.
- Identification of the remaining functional groups, if any, and naming them by their ionic prefixes (such as hydroxy for −OH, oxy for =O, oxyalkane for O−R, etc.).
Different side-chains and functional groups will be grouped together in alphabetical order. (The multiplier prefixes di-, tri-, etc. are not taken into consideration for grouping alphabetically. For example, ethyl comes before dihydroxy or dimethyl, as the "e" in "ethyl" precedes the "h" in "dihydroxy" and the "m" in "dimethyl" alphabetically. The "di" is not considered in either case). When both side chains and secondary functional groups are present, they should be written mixed together in one group rather than in two separate groups. - Identification of double/triple bonds.
- Numbering of the chain. This is done by first numbering the chain in both directions (left to right and right to left), and then choosing the numbering which follows these rules, in order of precedence. Not every rule will apply to every compound, rules can be skipped if they do not apply.
- Has the lowest-numbered locant (or locants) for heteroatoms. Locants are the numbers on the carbons to which the substituent is directly attached.
- Has the lowest-numbered locants for the indicated hydrogen. The indicated hydrogen is for some unsaturated heterocyclic compounds. It refers to the hydrogen atoms not attached to atoms with double bonds in the ring system.
- Has the lowest-numbered locants for the suffix functional group.
- Has the lowest-numbered locants for multiple bonds ('ene', 'yne'), and hydro prefixes. (The locant of a multiple bond is the number of the adjacent carbon with a lower number).
- Has the lowest-numbered locants for all substituents cited by prefixes.
- Has the lowest-numbered locants for substituents in order of citation (for example: in a cyclic ring with only bromine and chlorine functional groups, alphabetically bromo- is cited before chloro- and would receive the lower locant).
- Numbering of the various substituents and bonds with their locants. If there is more than one of the same type of substituent/double bond, a prefix is added showing how many there are (di – 2, tri – 3, tetra – 4, then as for the number of carbons below with 'a' added at the end)
The numbers for that type of side chain will be grouped in ascending order and written before the name of the side-chain. If there are two side-chains with the same
- Arrangement in this form: Group of side chains and secondary functional groups with numbers made in step 6 + prefix of parent hydrocarbon chain (eth, meth) + double/triple bonds with numbers (or "ane") + primary functional group suffix with numbers.
Wherever it says "with numbers", it is understood that between the word and the numbers, the prefix (di-, tri-) is used. - Adding of punctuation:
- Commas are put between numbers (2 5 5 becomes 2,5,5)
- Hyphens are put between a number and a letter (2 5 5 trimethylheptane becomes 2,5,5-trimethylheptane)
- Successive words are merged into one word (trimethyl heptane becomes trimethylheptane)
Note: IUPAC uses one-word names throughout. This is why all parts are connected.
The resulting name appears as:
- #,#-di<side chain>-#-<secondary functional group>-#-<side chain>-#,#,#-tri<secondary functional group><parent chain prefix><If all bonds are single bonds, use "ane">-#,#-di<double bonds>-#-<triple bonds>-#-<primary functional group>
where each "#" represents a number. The group secondary functional groups and side chains may not look the same as shown here, as the side chains and secondary functional groups are arranged alphabetically. The di- and tri- have been used just to show their usage. (di- after #,#, tri- after #,#,#, etc.)
Example
Here is a sample molecule with the parent carbons numbered:
For simplicity, here is an image of the same molecule, where the hydrogens in the parent chain are removed and the carbons are shown by their numbers:
Now, following the above steps:
- The parent hydrocarbon chain has 23 carbons. It is called tricosa-.
- The functional groups with the highest precedence are the two ketone groups.
- The groups are on carbon atoms 3 and 9. As there are two, we write 3,9-dione.
- The numbering of the molecule is based on the ketone groups. When numbering from left to right, the ketone groups are numbered 3 and 9. When numbering from right to left, the ketone groups are numbered 15 and 21. 3 is less than 15, therefore the ketones are numbered 3 and 9. The smaller number is always used, not the sum of the constituents numbers.
- The side chains are: an ethyl- at carbon 4, an ethyl- at carbon 8, and a butyl- at carbon 12.
Note: the −O−CH3 at carbon atom 15 is not a side chain, but it is a methoxy functional group.- There are two ethyl- groups. They are combined to create, 4,8-diethyl.
- The side chains are grouped like this: 12-butyl-4,8-diethyl. (But this is not necessarily the final grouping, as functional groups may be added in between to ensure all groups are listed alphabetically.)
- The secondary functional groups are: a hydroxy- at carbon 5, a chloro- at carbon 11, a methoxy- at carbon 15, and a bromo- at carbon 18. Grouped with the side chains, this gives 18-bromo-12-butyl-11-chloro-4,8-diethyl-5-hydroxy-15-methoxy.
- There are two double bonds: one between carbons 6 and 7, and one between carbons 13 and 14. They would be called "6,13-diene", but the presence of alkynes switches it to 6,13-dien. There is one triple bond between carbon atoms 19 and 20. It will be called 19-yne.
- The arrangement (with punctuation) is: 18-bromo-12-butyl-11-chloro-4,8-diethyl-5-hydroxy-15-methoxytricosa-6,13-dien-19-yne-3,9-dione
- Finally, due to cis-trans isomerism, we have to specify the relative orientation of functional groups around each double bond. For this example, both double bonds are trans isomers, so we have (6E,13E)
The final name is (6E,13E)-18-bromo-12-butyl-11-chloro-4,8-diethyl-5-hydroxy-15-methoxytricosa-6,13-dien-19-yne-3,9-dione.
Hydrocarbons
Alkanes
Number of carbons | 1 | 2 | 3 | 4 | 5 | 6 | 7 | 8 | 9 | 10 | 11 | 12 | 13 | 14 | 15 | 16 | 17 | 18 | 19 | 20 |
---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|
Prefix | Meth | Eth | Prop | But | Pent | Hex | Hept | Oct | Non | Dec | Undec | Dodec | Tridec | Tetradec | Pentadec | Hexadec | Heptadec | Octadec | Nonadec | Icos |
For example, the simplest alkane is CH4 methane, and the nine-carbon alkane CH3(CH2)7CH3 is named
Cyclic alkanes are simply prefixed with "cyclo-": for example, C4H8 is cyclobutane (not to be confused with butene) and C6H12 is cyclohexane (not to be confused with hexene).
Branched alkanes are named as a straight-chain alkane with attached
If there is ambiguity in the position of the substituent, depending on which end of the alkane chain is counted as "1", then numbering is chosen so that the smaller number is used. For example, (CH3)2CHCH2CH3 (isopentane) is named 2-methylbutane, not 3-methylbutane.
If there are multiple side-branches of the same size alkyl group, their positions are separated by commas and the group prefixed with multiplier prefixes depending on the number of branches. For example, C(CH3)4 (neopentane) is named 2,2-dimethylpropane. If there are different groups, they are added in alphabetical order, separated by commas or hyphens. The longest possible main alkane chain is used; therefore 3-ethyl-4-methylhexane instead of 2,3-diethylpentane, even though these describe equivalent structures. The di-, tri- etc. prefixes are ignored for the purpose of alphabetical ordering of side chains (e.g. 3-ethyl-2,4-dimethylpentane, not 2,4-dimethyl-3-ethylpentane).
Alkenes
Alkenes are named for their parent alkane chain with the suffix "-ene" and a numerical root indicating the position of the carbon with the lower number for each double bond in the chain: CH2=CHCH2CH3 is but-1-ene. Multiple double bonds take the form -diene, -triene, etc., with the size prefix of the chain taking an extra "a": CH2=CHCH=CH2 is buta-1,3-diene. Simple
Alkynes
Alkynes are named using the same system, with the suffix "
Functional groups
Haloalkanes and haloarenes
In haloalkanes and haloarenes (R−X), Halogen functional groups are prefixed with the bonding position and take the form of fluoro-, chloro-, bromo-, iodo-, etc., depending on the halogen. Multiple groups are dichloro-, trichloro-, etc., and dissimilar groups are ordered alphabetically as before. For example, CHCl3 (chloroform) is trichloromethane. The anesthetic halothane (CF3CHBrCl) is 2-bromo-2-chloro-1,1,1-trifluoroethane.
Alcohols
Alcohols (R−OH) take the suffix "-ol" with a numerical suffix indicating the bonding position: CH3CH2CH2OH is propan-1-ol. The suffixes -diol, -triol, -tetrol, etc., are used for multiple −OH groups: Ethylene glycol CH2OHCH2OH is ethane-1,2-diol.
If higher precedence functional groups are present (see order of precedence, below), the prefix "hydroxy" is used with the bonding position: CH3CHOHCOOH is 2-hydroxypropanoic acid.
Ethers
Ethers (R−O−R) consist of an oxygen atom between the two attached carbon chains. The shorter of the two chains becomes the first part of the name with the -ane suffix changed to -oxy, and the longer alkane chain becomes the suffix of the name of the ether. Thus, CH3OCH3 is methoxymethane, and CH3OCH2CH3 is methoxyethane (not ethoxymethane). If the oxygen is not attached to the end of the main alkane chain, then the whole shorter alkyl-plus-ether group is treated as a side-chain and prefixed with its bonding position on the main chain. Thus CH3OCH(CH3)2 is 2-methoxypropane.
Alternatively, an ether chain can be named as an alkane in which one carbon is replaced by an oxygen, a replacement denoted by the prefix "oxa". For example, CH3OCH2CH3 could also be called 2-oxabutane, and an epoxide could be called oxacyclopropane. This method is especially useful when both groups attached to the oxygen atom are complex.[6]
Aldehydes
Aldehydes (R−CH=O) take the suffix "-al". If other functional groups are present, the chain is numbered such that the aldehyde carbon is in the "1" position, unless functional groups of higher precedence are present.
If a prefix form is required, "oxo-" is used (as for ketones), with the position number indicating the end of a chain: CHOCH2COOH is 3-oxopropanoic acid. If the carbon in the carbonyl group cannot be included in the attached chain (for instance in the case of
Ketones
In general ketones (R2C=O) take the suffix "-one" (pronounced own, not won) with a suffixed position number: CH3CH2CH2COCH3 is pentan-2-one. If a higher precedence suffix is in use, the prefix "oxo-" is used: CH3CH2CH2COCH2CHO is 3-oxohexanal.
Carboxylic acids
In general, carboxylic acids (R−C(=O)OH) are named with the suffix
If there are multiple carboxyl groups on the same parent chain, multiplying prefixes are used: Malonic acid, CH2(COOH)2, is systematically named propanedioic acid. Alternatively, the suffix "-carboxylic acid" can be used in place of "oic acid", combined with a multiplying prefix if necessary – mellitic acid is benzenehexacarboxylic acid, for example. In the latter case, the carbon atoms in the carboxyl groups do not count as being part of the main chain, a rule that also applies to the prefix form "carboxy-". Citric acid serves as an example: it is formally named 2-hydroxypropane-1,2,3-tricarboxylic acid rather than 3-carboxy-3-hydroxypentanedioic acid.
Carboxylates
Esters
Esters (R−C(=O)O−R') are named as alkyl derivatives of carboxylic acids. The alkyl (R') group is named first. The R−C(=O)O part is then named as a separate word based on the carboxylic acid name, with the ending changed from "-oic acid" to "-oate" or "-carboxylate" For example, CH3CH2CH2CH2COOCH3 is methyl pentanoate, and (CH3)2CHCH2CH2COOCH2CH3 is ethyl 4-methylpentanoate. For esters such as ethyl acetate (CH3COOCH2CH3), ethyl formate (HCOOCH2CH3) or dimethyl phthalate that are based on common acids, IUPAC recommends use of these established names, called retained names. The "-oate" changes to "-ate." Some simple examples, named both ways, are shown in the figure above.
If the alkyl group is not attached at the end of the chain, the bond position to the ester group is suffixed before "-yl": CH3CH2CH(CH3)OOCCH2CH3 may be called butan-2-yl propanoate or butan-2-yl propionate.[citation needed]. The prefix form is "oxycarbonyl-" with the (R') group preceding.
Acyl groups
Acyl groups are named by stripping the "-ic acid" of the corresponding carboxylic acid and replacing it with "-yl." For example, CH3CO−R is called ethanoyl-R.
Acyl halides
Simply add the name of the attached halide to the end of the acyl group. For example, CH3COCl is ethanoyl chloride. An alternate suffix is "-carbonyl halide" as opposed to "-oyl halide". The prefix form is "halocarbonyl-".
Acid anhydrides
Acid anhydrides (R−C(=O)−O−C(=O)−R) have two acyl groups linked by an oxygen atom. If both acyl groups are the same, then the name of the carboxylic acid with the word acid is replaced with the word anhydride and the IUPAC name consists of two words. If the acyl groups are different, then they are named in alphabetical order in the same way, with anhydride replacing acid and IUPAC name consists of three words. For example, CH3CO−O−OCCH3 is called ethanoic anhydride and CH3CO−O−OCCH2CH3 is called ethanoic propanoic anhydride.
Amines
Amines (R−NH2) are named for the attached alkane chain with the suffix "-amine" (e.g., CH3NH2 methanamine). If necessary, the bonding position is suffixed: CH3CH2CH2NH2 propan-1-amine, CH3CHNH2CH3 propan-2-amine. The prefix form is "amino-".
For secondary amines (of the form R−NH−R), the longest carbon chain attached to the nitrogen atom becomes the primary name of the amine; the other chain is prefixed as an alkyl group with location prefix given as an italic N: CH3NHCH2CH3 is N-methylethanamine. Tertiary amines (R−NR−R) are treated similarly: CH3CH2N(CH3)CH2CH2CH3 is N-ethyl-N-methylpropanamine. Again, the substituent groups are ordered alphabetically.
Amides
Amides (R−C(=O)NH2) take the suffix "-amide", or "-carboxamide" if the carbon in the amide group cannot be included in the main chain. The prefix form is "carbamoyl-". e.g., HCONH2 methanamide, CH3CONH2 ethanamide.
Amides that have additional substituents on the nitrogen are treated similarly to the case of amines: they are ordered alphabetically with the location prefix N: HCON(CH3)2 is N,N-dimethylmethanamide, CH3CON(CH3)2 is N,N-dimethylethanamide.
Nitriles
Nitriles (R−C≡N) are named by adding the suffix "-nitrile" to the longest hydrocarbon chain (including the carbon of the cyano group). It can also be named by replacing the "-oic acid" of their corresponding carboxylic acids with "-carbonitrile." The prefix form is "cyano-." Functional class IUPAC nomenclature may also be used in the form of alkyl cyanides. For example, CH3CH2CH2CH2C≡N is called pentanenitrile or butyl cyanide.
Cyclic compounds
The IUPAC nomenclature scheme becomes rapidly more elaborate for more complex cyclic structures, with notation for compounds containing conjoined rings, and many common names such as phenol being accepted as base names for compounds derived from them.
Order of precedence of group
When compounds contain more than one functional group, the order of precedence determines which groups are named with prefix or suffix forms. The table below shows common groups in decreasing order of precedence. The highest-precedence group takes the suffix, with all others taking the prefix form. However, double and triple bonds only take suffix form (-en and -yn) and are used with other suffixes.
Prefixed substituents are ordered alphabetically (excluding any modifiers such as di-, tri-, etc.), e.g. chlorofluoromethane, not fluorochloromethane. If there are multiple functional groups of the same type, either prefixed or suffixed, the position numbers are ordered numerically (thus ethane-1,2-diol, not ethane-2,1-diol.) The N position indicator for amines and amides comes before "1", e.g., CH3CH(CH3)CH2NH(CH3) is N,2-dimethylpropanamine.
Priority | Functional group | Formula | Prefix | Suffix |
---|---|---|---|---|
1 | Cations
|
|
-onio-
|
-onium
|
2 | Carboxylic acids | −COOH
|
carboxy-
|
-oic acid*
|
3 | Carboxylic acid derivatives | −COOCO−
|
acyloxy-
|
-R-oic anhydride
|
4 | Nitriles | −CN
|
cyano-
|
-nitrile*
|
5 | Aldehydes
|
−CHO
|
formyl-
|
-al*
|
6 | Ketones | =O
|
oxo-
|
-one
|
7 | Alcohols | −OH
|
hydroxy-
|
-ol
|
8 | Hydroperoxides
|
|
|
|
9 | Amines | −NH2
|
amino-
|
-amine
|
*Note: These suffixes, in which the carbon atom is counted as part of the preceding chain, are the most commonly used. See individual functional group articles for more details.
The order of remaining functional groups is only needed for substituted benzene and hence is not mentioned here.[clarification needed]
Common nomenclature – trivial names
Common nomenclature uses the older names for some organic compounds instead of using the prefixes for the carbon skeleton above. The pattern can be seen below.
Number of carbons |
Prefix as in new system |
Common name for alcohol |
Common name for aldehyde |
Common name for acid |
Common name for ketone |
---|---|---|---|---|---|
1 | Meth- | Methyl alcohol (wood alcohol) |
Formaldehyde | Formic acid | NA |
2 | Eth- | Ethyl alcohol (grain alcohol) |
Acetaldehyde | Acetic acid (vinegar) | NA |
3 | Prop- | Propyl alcohol | Propionaldehyde | Propionic acid | Acetone/dimethyl ketone |
4 | But- | Butyl alcohol | Butyraldehyde | Butyric acid | Methyl ethyl ketone |
5 | Pent- | Amyl alcohol | Valeraldehyde | Valeric acid | •Methyl propyl ketone
•Diethyl ketone |
6 | Hex- | Caproyl alcohol | Caproaldehyde | Caproic acid | •Butyl methyl ketone
•Ethyl propyl ketone |
7 | Hept- | Enanthyl alcohol | Enanthaldehyde | Enanthoic acid | •Methyl pentyl ketone
•Butyl ethyl ketone •Dipropyl ketone |
8 | Oct- | Capryl alcohol | Caprylaldehyde | Caprylic acid | •Hexyl methyl ketone
•Ethyl pentyl ketone •Butyl propyl ketone |
9 | Non- | Pelargonic alcohol | Pelargonaldehyde | Pelargonic acid | •Heptyl methyl ketone
•Ethyl hexyl ketone •Pentyl propyl ketone •Dibutyl ketone |
10 | Dec- | Capric alcohol | Capraldehyde | Capric acid | •Methyl octyl ketone
•Ethyl heptyl ketone •Hexyl propyl ketone •Butyl pentyl ketone |
11 | Undec- | - | - | - | The same pattern continues |
12 | Dodec- | Lauryl alcohol | Lauraldehyde | Lauric acid | |
13 | Tridec- | - | - | - | |
14 | Tetradec- | Myristyl alcohol | Myristaldehyde | Myristic acid | |
15 | Pentadec- | - | - | - | |
16 | Hexadec- | Cetyl alcohol Palmityl alcohol |
Palmitaldehyde | Palmitic acid | |
17 | Heptadec- | - | - | Margaric acid | |
18 | Octadec- | Stearyl alcohol | Stearaldehyde | Stearic acid | |
19 | Nonadec- | - | - | - | |
20 | Icos- | Arachidyl alcohol | - | Arachidic acid | |
21 | Henicos- | - | - | - | |
22 | Docos- | Behenyl alcohol | - | Behenic acid | |
23 | Tricos- | - | - | - | |
24 | Tetracos- | Lignoceryl alcohol | - | Lignoceric acid | |
25 | Pentacos- | - | - | - | |
26 | Hexacos- | Ceryl alcohol | - | Cerotic acid | |
27 | Heptacos- | - | - | - | |
28 | Octacos- | Montanyl alcohol | - | Montanic acid | |
29 | Nonacos- | - | - | - | |
30 | Triacont- | Melissyl alcohol | - | Melissic acid | |
31 | Hentriacont- | - | - | - | |
32 | Dotriacont- | Lacceryl alcohol | - | Lacceroic acid | |
33 | Tritriacont- | Psyllic alcohol | - | Psyllic acid | |
34 | Tetratriacont- | Geddyl alcohol | - | Geddic acid | |
35 | Pentatriacont- | - | - | Ceroplastic acid | |
36 | Hexatriacont- | - | - | - | |
37 | Heptatriacont- | - | - | - | |
38 | Octatriacont- | - | - | - | |
39 | Nonatriacont- | - | - | - | |
40 | Tetracont- | - | - | - |
Ketones
Common names for
- Acetone
- Acetophenone
- Benzophenone
- Ethyl isopropyl ketone
- Diethyl ketone
The first three of the names shown above are still considered to be acceptable IUPAC names.
Aldehydes
The common name for an aldehyde is derived from the common name of the corresponding carboxylic acid by dropping the word acid and changing the suffix from -ic or -oic to -aldehyde.
Ions
The IUPAC nomenclature also provides rules for naming ions.
Hydron
Hydron is a generic term for hydrogen cation; protons, deuterons and tritons are all hydrons. The hydrons are not found in heavier isotopes, however.
Parent hydride cations
Simple cations formed by adding a hydron to a hydride of a halogen, chalcogen or pnictogen are named by adding the suffix "-onium" to the element's root: H4N+ is ammonium, H3O+ is oxonium, and H2F+ is fluoronium. Ammonium was adopted instead of nitronium, which commonly refers to NO+2.
If the cationic center of the hydride is not a halogen, chalcogen or pnictogen then the suffix "-ium" is added to the name of the neutral hydride after dropping any final 'e'. H5C+ is methanium, HO−(O+)H2 is dioxidanium (HO-OH is dioxidane), and H2N−(N+)H3 is diazanium (H2N−NH2 is diazane).
Cations and substitution
The above cations except for methanium are not, strictly speaking, organic, since they do not contain carbon. However, many organic cations are obtained by substituting another element or some functional group for a hydrogen.
The name of each substitution is prefixed to the hydride cation name. If many substitutions by the same functional group occur, then the number is indicated by prefixing with "di-", "tri-" as with halogenation. (CH3)3O+ is trimethyloxonium. CH3F3N+ is trifluoromethylammonium.
See also
- Descriptor (chemistry)
- Hantzsch–Widman nomenclature
- International Union of Biochemistry and Molecular Biology
- Nucleic acid notation
- Organic nomenclature in Chinese
- Phanes
- Preferred IUPAC name
- Von Baeyer nomenclature
- IUPAC nomenclature of inorganic chemistry
References
- ISBN 0-408-70144-7.
- )
- ^ "Blue Book". IUPAC | International Union of Pure and Applied Chemistry. Retrieved 19 September 2024.
- ^ "Brief Guide to Inorganic Nomenclature". iupac.qmul.ac.uk. Retrieved 19 September 2024.
- ISSN 1365-3075.
- ^ "Basic IUPAC Organic Nomenclature".
- ISBN 9780632034888.
Bibliography
- Favre, Henri A.; Powell, Warren H. (2013). Nomenclature of Organic Chemistry: IUPAC Recommendations and Preferred Names 2013. ISBN 978-0-85404-182-4.
External links
- IUPAC Nomenclature of Organic Chemistry (online version of several older editions of the IUPAC Blue Book)
- IUPAC Recommendations on Organic & Biochemical Nomenclature, Symbols, Terminology, etc. (includes IUBMB Recommendations for biochemistry)
- Bibliography of IUPAC Recommendations on Organic Nomenclature (last updated 11 April 2003)
- ACD/Name Software for generating systematic nomenclature
- ChemAxon Name <> Structure – ChemAxon IUPAC (& traditional) name to structure and structure to IUPAC name software. As used at chemicalize.org
- chemicalize.org A free web site/service that extracts IUPAC names from web pages and annotates a 'chemicalized' version with structure images. Structures from annotated pages can also be searched.
- Eller, Gernot A. (2006). "Improving the Quality of Published Chemical Names with Nomenclature Software" (PDF). PMID 18007396.
- American Chemical Society, Committee on Nomenclature, Terminology & Symbols
- Leigh, G. J.; Favre, H. A.; Metanomski, W. V. (1998). Principles of Chemical Nomenclature. A Guide to IUPAC Recommendations (PDF). Blackwell.