Preferred IUPAC name
A Preferred IUPAC name (PIN) is the unique name selected for a chemical compound or structural component according to the systematic rules of IUPAC nomenclature, intended as the principal name for unambiguous identification in scientific literature, regulatory documentation, and international communication.[1] Initially introduced in the 2013 edition of the IUPAC Blue Book (Nomenclature of Organic Chemistry: IUPAC Recommendations and Preferred Names), with subsequent updates including the 2024 web version, the PIN concept addresses the need for a standardized nomenclature amid increasing globalization and the proliferation of chemical data, ensuring consistency while allowing flexibility through general IUPAC names for less formal contexts.[2] Primarily applied to organic compounds, the PIN concept is under development for inorganic nomenclature, while polymers use a separate system of preferred names, though the core framework originates from organic substitutive methods.[3][4] The selection of a PIN follows a strict hierarchical methodology outlined in the Blue Book, prioritizing substitutive nomenclature—where a parent hydride is modified by prefixes, infixes, and suffixes to denote substituents, functional groups, and unsaturation—over alternative approaches like functional class or additive nomenclature.[1] Criteria for choosing the PIN include identifying the senior parent structure based on the presence and seniority of principal characteristic groups (e.g., acids over esters), maximum number of such groups, and preferences for rings over chains or heteroatoms over homocyclic systems; numbering then assigns the lowest locants to these features, followed by substituents and stereodescriptors.[5] Retained names, such as acetic acid for CH₃COOH or pyridine for C₅H₅N, are accepted as PINs for a limited set of common compounds to balance tradition with systematization, classified into types allowing varying degrees of substitution (unlimited, limited, or none).[1] PINs play a critical role in fields like patent law, chemical databases, and safety regulations, where a single authoritative name prevents ambiguity—for instance, distinguishing systematic names like butan-2-one (PIN) from retained or trivial alternatives like methyl ethyl ketone.[5] The IUPAC Division of Chemical Nomenclature and Structure Representation continues to update these recommendations, including errata and revisions as of 2024, with digital tools and brief guides facilitating their application across academia and industry.[6][7][8]Overview and Definitions
Definition of Preferred IUPAC Name
The Preferred IUPAC name (PIN) is defined as the name that is preferred among two or more possible IUPAC names generated for the same chemical structure, ensuring a single, standardized identifier for unambiguous communication in chemistry. This designation arises from the IUPAC Recommendations for Nomenclature of Organic Chemistry (the 2013 Blue Book), where PINs are selected through a hierarchical set of criteria to prioritize substitutive nomenclature while accommodating other systematic methods when applicable.[1] The purpose of the PIN is to promote uniformity and precision in naming across diverse applications, including scientific publications, regulatory filings, intellectual property documentation, and chemical information systems. By establishing a mandatory preferred option, PINs facilitate global consistency, particularly in areas such as chemical safety evaluations, environmental regulations, and commerce, where ambiguous nomenclature could lead to errors or misinterpretation.[2] Key characteristics of PINs include their systematic generation based on established IUPAC rules, which emphasize structural features like parent hydrides, functional groups, and substituents, though a limited set of retained traditional names (e.g., for well-known compounds) may also qualify as PINs to balance innovation with familiarity. PINs are designed for well-defined structures, encompassing organic compounds and extending to certain inorganic and polymer nomenclature, but they exclude provisional or ambiguous cases without full structural specification. The inclusion of stereodescriptors in PINs ensures uniqueness for stereoisomers, distinguishing configurations such as enantiomers or diastereomers within the same constitutional framework.[1]Historical Context
The efforts to standardize chemical nomenclature began in the late 19th century, with the International Chemical Congress of 1892 establishing the Geneva Rules, which provided the first international standards for naming organic compounds.[9] These rules addressed the growing need for systematic naming amid increasing chemical discoveries, marking an early push toward global consistency. The formation of the International Union of Pure and Applied Chemistry (IUPAC) in 1919 formalized these initiatives, as chemists from industry and academia recognized the necessity for ongoing international cooperation in nomenclature.[10] By 1921, IUPAC had appointed its first commissions for organic, inorganic, and biochemical nomenclature, laying the groundwork for comprehensive recommendations.[11] The concept of preferred names evolved within IUPAC's organic nomenclature framework, initially appearing as "recommended names" in the 1993 Guide to IUPAC Nomenclature of Organic Chemistry, known as the Blue Book.[12] This publication highlighted the need for a single, authoritative name to resolve ambiguities in existing systems, responding to the proliferation of chemical literature and databases. A draft version in 2004 introduced the term "Preferred IUPAC Name" (PIN), which was fully formalized in the 2013 Blue Book, titled Nomenclature of Organic Chemistry: IUPAC Recommendations and Preferred Names.[13] This edition systematically applied PINs while reducing the number of retained traditional names to enhance precision and uniqueness.[1] Parallel developments in inorganic nomenclature included the 2005 edition of the Red Book, which provided definitive rules for naming inorganic compounds and contributed to the broader standardization effort.[14] The introduction of PINs was driven by the need to eliminate ambiguities in traditional and retained names, ensuring a unique identifier for each substance in scientific and regulatory contexts.[15] This was particularly important for harmonizing nomenclature with international regulations, such as the European Union's REACH framework enacted in 2007, which mandates the use of IUPAC names for chemical registration and safety assessments.[16] The 2013 Blue Book's emphasis on PINs thus supported global compliance and interoperability. A 2024 update to the Blue Book incorporated corrections and minor revisions but did not alter the core PIN rules, maintaining stability in the system.[17]Core Principles
Selection Criteria
The primary criterion for selecting a Preferred IUPAC Name (PIN) is that it must be unambiguous and reproducible, ensuring a unique identification of the compound's structure, including stereochemistry, to facilitate consistent communication in scientific and regulatory contexts.[1] This requires adherence to a hierarchical set of rules that prioritize clarity and systematic construction over traditional or alternative names.[5] The order of preference among nomenclature methods begins with substitutive nomenclature, which constructs the name from a parent hydride with substituents and functional groups expressed as prefixes or suffixes, as it provides the most straightforward and general approach.[1] If substitutive nomenclature is unsuitable, functional class nomenclature is next, followed by skeletal replacement nomenclature (using 'a' endings for heteroatoms), with multiplicative names employed only as a last resort for complex assemblies; however, functional class nomenclature is preferred for esters, acid halides, and pseudohalides.[5] Seniority rules guide the choice of the principal characteristic group and parent structure, with higher seniority assigned to functions such as carboxylic acids over alcohols, based on a predefined order of precedence.[18] Within this, the name employs the lowest possible set of locants for the principal function, multiple bonds, and substituents, followed by alphabetical ordering of prefixes to resolve any remaining ambiguities.[18] Special considerations apply to isotopes and stereoisomers, where the PIN incorporates specific descriptors to denote modifications; for stereoisomers, Cahn-Ingold-Prelog (CIP) rules mandate prefixes like (2R)- for chiral centers, placed at the front of the name with priority for lowest locants.[1] For isotopic variants, lowest locants are assigned to the modified positions, favoring nuclides with higher mass numbers when choices arise.[18] Retained names serve as exceptions to these systematic criteria in limited cases, as outlined in subsequent sections.[5]Hierarchy of Nomenclature Types
The International Union of Pure and Applied Chemistry (IUPAC) defines a hierarchical order for nomenclature types to systematically generate candidate names for preferred IUPAC names (PINs), ensuring consistency and unambiguity in organic chemical nomenclature. This hierarchy prioritizes methods based on their applicability, simplicity, and ability to express structural features, with substitutive nomenclature serving as the foundational approach for most compounds. The selection follows rules outlined in the 2013 IUPAC Blue Book, particularly in sections P-15 and related chapters, where substitutive is preferred unless structural constraints necessitate alternatives.[1] Substitutive nomenclature holds the highest priority and is the preferred method for naming the majority of organic compounds, including those with chains, rings, and functional groups. It operates by selecting a parent hydride (such as an alkane or arene) and replacing hydrogen atoms with substituents or characteristic groups expressed as prefixes or suffixes, thereby constructing a name that reflects the compound's structure. For example, replacing a hydrogen in methane yields chloromethane. This method is versatile and aligns with the seniority order of classes (detailed below), making it suitable for PINs in most cases as per P-15.2.[1][5] Functional class nomenclature ranks below substitutive in general but is the preferred method for esters, acid halides, and pseudohalides, where the compound is named as a combination of substituent groups followed by the name of the functional class, treating the functional group as a separate entity. For instance, the acyl chloride derived from acetic acid is named acetyl chloride. Although allowed for PINs in these contexts (P-65), it maintains uniformity where substitutive is not preferred.[1][5] Skeletal replacement nomenclature, also known as 'a' nomenclature, occupies an intermediate position in the hierarchy and is utilized for compounds featuring heteroatoms integrated into the carbon skeleton of chains or rings, where substitutive alone is insufficient. It involves replacing carbon atoms in a parent hydride with heteroatoms denoted by 'a' endings (e.g., 'a' for oxygen in oxa-), generating names like 2,5,8,11-tetraoxatridecane for a polyether chain. This method is preferred for heterocyclic or heteroacyclic parent structures in PIN generation (P-22 to P-28, P-15.4), but only when it provides a more senior parent than pure substitutive options.[1] Multiplicative nomenclature is the lowest in the hierarchy and is reserved for symmetrical assemblies of identical structural units linked by multiplicative operators, applied only when substitutive, functional class, or skeletal replacement methods fail to yield a concise name. It uses numerical prefixes like 'bis-', 'tris-', or linking elements to denote replication, as in bis(chloromethyl) ether for a symmetric diether. According to P-51.1.2 and P-15.3, this approach is disallowed for PINs if a substitutive name is feasible, ensuring it serves as a fallback for complex symmetric molecules.[1] Within substitutive nomenclature, the choice of principal characteristic group is governed by a strict seniority order outlined in rule P-41, which ranks classes to determine the suffix and parent structure. The order prioritizes cations first, followed by acids (e.g., carboxylic acids over sulfonic acids), anhydrides, esters, acid halides, amides, nitriles, aldehydes, ketones, alcohols, amines, and hydrocarbons, with further subdivisions for specific subclasses like oxoacids (P-42). For example, in a molecule containing both a carboxylic acid and a ketone, the acid receives the suffix '-oic acid' due to its higher seniority. This hierarchy, detailed in Table 4.1 of the Blue Book, ensures the PIN reflects the most senior functional feature.[19]| Seniority Class | Examples of Suffixes/Groups | Rule Reference |
|---|---|---|
| Cations | -ium | P-41, P-62 |
| Acids | -oic acid, -sulfonic acid | P-41, P-65 |
| Anhydrides | -oic anhydride | P-41, P-66 |
| Esters | alkyl ...oate | P-41, P-65.2 |
| Acid halides | -oyl halide | P-41, P-65.1 |
| Amides | -amide | P-41, P-66 |
| Nitriles | -nitrile | P-41, P-66.1 |
| Aldehydes | -al | P-41, P-66.6 |
| Ketones | -one | P-41, P-66.6 |
| Alcohols | -ol | P-41, P-63 |
Retained Names
Criteria for Retention
The criteria for designating traditional or common names as preferred IUPAC names (PINs) focus on their entrenched status within the chemical community, ensuring they integrate seamlessly with systematic nomenclature while promoting clarity and consistency. According to the 2013 IUPAC Blue Book, retained names must be well-established, unambiguous, and derived from long-standing usage that aligns with the principles of substitutive nomenclature; examples include methane and acetic acid, which serve as parent structures without introducing conflicts in naming derivatives.[13] This policy limits retention to names that avoid ambiguity in structure-to-name correspondence, prioritizing those that facilitate precise communication in scientific and applied contexts. A key guideline in the Blue Book is the reduction of retained names to a core set, with over 200 such names approved as PINs in the 2013 edition—down from a larger number in the 1993 recommendations—to ease the adoption of systematic methods while retaining utility for simple compounds.[13] Decision factors include the frequency of a name's appearance in chemical literature, its regulatory acceptance in areas like patents and international standards, and the potential for systematic alternatives to become excessively complex, thereby hindering practical application.[5] Retained names are thus selected to balance historical precedent with modern needs, ensuring they support educational and professional workflows without compromising the hierarchy of nomenclature types, where they act as exceptions to fully systematic rules.[1] IUPAC's Division VIII on Chemical Nomenclature and Structure Representation oversees the periodic assessment of retained names through specialized task groups, evaluating their ongoing relevance and alignment with evolving practices. The 2013 recommendations represent a comprehensive review that superseded the 1979 and 1993 editions, with no substantial alterations to the core list of retained organic names since then, aside from targeted clarifications in domain-specific areas such as carbohydrate nomenclature.[20] These updates, including revisions to carbohydrate terms initiated in 2012 and refined through 2021, ensure that retained names remain adaptable to advancements in biochemical applications without expanding the overall scope unnecessarily.[21]Specific Retained Names for Common Compounds
The International Union of Pure and Applied Chemistry (IUPAC) has approved a select set of retained names as preferred IUPAC names (PINs) for widely used common compounds, recognizing their entrenched usage in scientific literature, education, and industry while ensuring consistency with nomenclature principles.[5] These retentions are limited to parent structures of high familiarity and do not extend broadly to derivatives, prioritizing biochemical and practical significance.[1]Acyclic Hydrocarbons
For simple acyclic hydrocarbons, IUPAC retains methane, ethene, and propene as PINs due to their fundamental role in foundational organic chemistry and everyday applications, such as fuels and petrochemicals. Methane (CH₄) is the PIN for the simplest alkane, with carbane as the systematic alternative never intended for general replacement.[1] Ethene (H₂C=CH₂) serves as the PIN for the simplest alkene, superseding the traditional name ethylene, which is retained only for general nomenclature.[1] Propene (CH₃-CH=CH₂) is similarly retained as the PIN, reflecting its importance in polymer production, with no preferred traditional alternative like propylene.[1]Functional Compounds
Certain functional compounds with broad utility in chemistry and biology have retained names designated as PINs. Water (H₂O) is the PIN for the inorganic parent hydride, with oxidane used systematically for derivatives but not as a replacement. Ammonia (NH₃) is retained as the PIN, essential in inorganic and organic contexts, while azane is the systematic name for substitutive nomenclature. Acetic acid (CH₃COOH) is the PIN for this carboxylic acid, justified by its prevalence in biochemistry and industry, despite ethanoic acid being the systematic equivalent.[1] Phenol (C₆H₅OH) is retained as the PIN, acknowledging its historical significance in organic synthesis, with benzenol as the systematic alternative.[1] For acetone (CH₃COCH₃), the systematic name propan-2-one is the PIN, but acetone is a retained name for general use due to its ubiquity as a solvent.[1]Carbohydrates and Amino Acids
Retained names for carbohydrates and amino acids are approved as PINs owing to their critical roles in biochemistry, where systematic names would complicate discourse in fields like metabolism and protein science. D-Glucose, the common form of this aldose sugar, is fully retained as the PIN, with the lengthy systematic name (2R,3S,4R,5R)-2,3,4,5,6-pentahydroxyhexanal reserved for precise structural descriptions.[5] Glycine (H₂N-CH₂-COOH), the simplest amino acid, is retained as the PIN for its foundational importance in peptide nomenclature, while aminoacetic acid is the systematic option.[5] The following table summarizes key examples of retained PINs, highlighting their classes and systematic alternatives:| Retained PIN | Systematic Alternative | Compound Class |
|---|---|---|
| Methane | Carbane | Acyclic hydrocarbon |
| Ethene | Ethene (systematic identical) | Acyclic hydrocarbon |
| Propene | Propene (systematic identical) | Acyclic hydrocarbon |
| Water | Oxidane | Inorganic hydride |
| Ammonia | Azane | Inorganic hydride |
| Formic acid | Methanoic acid | Carboxylic acid |
| Acetic acid | Ethanoic acid | Carboxylic acid |
| Phenol | Benzenol | Alcohol (aromatic) |
| D-Glucose | (2R,3S,4R,5R)-2,3,4,5,6-Pentahydroxyhexanal | Carbohydrate |
| Glycine | 2-Aminoacetic acid | Amino acid |
Scope and Applications
Coverage for Organic Compounds
The scope of preferred IUPAC names (PINs) for organic compounds encompasses structures primarily based on carbon atoms bonded to hydrogen and elements from Groups 13 through 17 of the periodic table, such as boron, nitrogen, oxygen, phosphorus, sulfur, and halogens, forming parent hydrides and their functionalized derivatives through substitutive nomenclature.[22] This definition aligns with the traditional understanding of organic chemistry, focusing on covalent compounds where carbon serves as the central framework, while excluding metals from Groups 1, 2, and 12 that would classify structures as organometallic or inorganic. Polymers and general biomolecules fall outside this scope unless they belong to specified natural product classes, such as certain steroids or carbohydrates, for which tailored rules apply.[22] Included classes of organic compounds eligible for PINs span a broad range of hydrocarbons and functional derivatives, including acyclic and cyclic hydrocarbons, alcohols (hydroxy compounds), carbonyl-containing structures like aldehydes, ketones, and carboxylic acids, as well as amines and ethers.[22] Comprehensive rules for generating PINs for these classes are detailed in the IUPAC Blue Book sections P-15 through P-99, which cover nomenclature types (substitutive, functional class, multiplicative, and skeletal replacement), parent hydride selection, functional group suffixes and prefixes, ring systems, stereochemistry, and isotopically modified compounds.[22] Within this framework, retained names—such as those for common functional parents like acetic acid or aniline—may be used as PINs in limited cases to ensure consistency with established practices.[22] Exclusions from PIN applicability include organometallic compounds involving metals from Groups 1, 2, or 12, such as Grignard reagents (e.g., those with magnesium), which are treated under inorganic or specialized nomenclature rather than organic PIN rules.[22] Mixtures, ill-defined substances, and polymers without specific monomeric structures are also not covered, as they do not fit the systematic criteria for unique, unambiguous naming.[22] Boundary cases arise with coordination compounds featuring organic ligands, where hybrid nomenclature applies: the organic ligand portions follow organic PIN rules (P-15 to P-99), while the coordination entity is named according to inorganic conventions, ensuring compatibility across domains.[22]Extensions to Inorganic and Other Areas
The 2005 IUPAC Red Book provides systematic nomenclature for inorganic compounds but does not adopt the PIN system from organic chemistry, noting it as a future development. For simple ionic compounds, recommended names like "sodium chloride" for NaCl are used, prioritizing systematic element-based naming while retaining traditional names for accessibility.[14] This approach prioritizes systematic element-based naming while retaining certain traditional names for well-known entities to balance accessibility and precision.[14] In hybrid areas like organometallic chemistry, the 2013 IUPAC recommendations extend PIN principles to ligands and complexes, integrating substitutive nomenclature from organic systems with coordination rules from inorganic ones. PIN principles have been partially extended to certain inorganic compounds, such as those involving main-group elements (e.g., boron, silicon) in the 2013 Blue Book, using substitutive nomenclature for parent hydrides like borane (BH₃).[13] For instance, the ligand "cyclopentadienyl" (η⁵-C₅H₅) is retained as a preferred name in organometallic contexts, facilitating naming of compounds like ferrocene as bis(η⁵-cyclopentadienyl)iron.[13] These rules address the overlap between organic and inorganic domains by specifying when substitutive or additive nomenclature applies to metal-carbon bonds. Extensions to other domains include isotopically modified compounds, where the 2013 Blue Book (P-8) outlines conventions for denoting isotopic modifications using nuclide symbols, such as (²H₁)methane or [²H]methane for specifically labeled deuterated methane, integrated within the PIN framework for organic compounds.[23] For polymers, the Purple Book (2008, with updates) defines preferred formats based on constitutional repeating units (CRUs), such as "poly(oxyethylene)" for polyethylene oxide, emphasizing structure-based naming over source-based alternatives without establishing a complete PIN hierarchy.[4] No unified PIN system exists for inorganic compounds as of 2025. A project to develop such recommendations concluded in 2020, but no comprehensive publication has followed, leaving gaps in coordination and main-group nomenclature.[3] The 2018 Brief Guide to the Nomenclature of Inorganic Chemistry provides simplified "teaching names" for educational purposes, such as stoichiometric formulas for binary compounds, to bridge formal rules and introductory instruction without resolving broader PIN unification.[24]Examples and Comparisons
Illustrative Examples
To illustrate the application of preferred IUPAC names (PINs), consider the simple hydrocarbon propane, which has the molecular formula C₃H₈ and a linear structure CH₃-CH₂-CH₃. The PIN is propane, derived from the systematic substitutive nomenclature for alkanes, where the parent chain is numbered to reflect the longest continuous carbon chain; here, the name is both retained and identical to the systematic form for this unbranched chain of three carbons. For a functional compound like ethanol (C₂H₅OH), the PIN is ethanol, a retained name for the unsubstituted alcohol that takes precedence over alternative systematic or functional class names such as ethyl alcohol. This choice reflects the criteria for retaining well-established names for simple alcohols in PIN selection, ensuring consistency in regulatory and scientific contexts. A more complex example is aspirin, systematically named as 2-(acetyloxy)benzoic acid (C₉H₈O₄). The PIN is constructed via substitutive nomenclature, selecting benzoic acid as the parent structure due to the seniority of the carboxylic acid group, with the acetyloxy substituent (-OCOCH₃) cited as a prefix at the lowest possible locant (position 2 on the benzene ring). This derivation prioritizes the principal characteristic group and follows rules for ester substituents in aromatic systems. For stereoisomers, consider (R)-lactic acid, which has the structure CH₃-CH(OH)-COOH with specified configuration at the chiral center. The PIN is (2R)-2-hydroxypropanoic acid, where the stereodescriptor "(2R)" precedes the name to indicate the absolute configuration. This descriptor is assigned using the Cahn-Ingold-Prelog (CIP) priority rules: atoms or groups attached to the chiral carbon are ranked by atomic number (or by atomic mass if tied) at the first point of difference, starting from the chiral center; here, the priorities are COOH (1, due to oxygen atoms), OH (2), CH₃ (3), and H (4), and the configuration is determined by viewing the lowest-priority group (H) away from the observer and noting whether the order 1-2-3 is clockwise (R) or counterclockwise (S). The following table provides additional representative examples from diverse compound classes, demonstrating PIN derivation, alternatives, and rationale based on IUPAC substitutive rules.| Structure Description | PIN | Alternative Name | Rationale |
|---|---|---|---|
| CH₃COOH (acetic acid) | acetic acid | ethanoic acid | Retained name preferred for the simplest carboxylic acid; systematic substitutive name uses the alkane chain with "-oic acid" suffix. |
| (CH₃)₂CO (acetone) | propan-2-one | acetone | Systematic name based on propane parent with oxo substituent at position 2; retained name acetone acceptable in general nomenclature but not PIN. |
| C₆H₅OH (phenol) | phenol | hydroxybenzene | Retained name for the parent hydroxyarene; systematic name uses benzene with hydroxy prefix, but retention prioritizes historical usage. |
| CH₂=CH₂ (ethene) | ethene | ethylene | Systematic name from alkene nomenclature with double bond at lowest locant; retained name ethylene for general use only. |
| C₆H₆ (benzene) | benzene | benzol | Retained aromatic hydrocarbon name; no systematic alternative needed as it serves as parent for derivatives. |
| HCONH₂ (formamide) | formamide | methanamide | Retained name for the simplest carboxamide; systematic name uses methane parent with amide suffix. |