Fact-checked by Grok 2 weeks ago

E – Z notation

The E–Z notation is a stereodescriptor system in organic chemistry used to specify the absolute configuration of substituents around a carbon–carbon double bond, particularly in alkenes, by assigning the prefixes E (from German entgegen, meaning "opposite") or Z (from zusammen, meaning "together") based on the relative positions of the highest-priority substituents on each end of the double bond, as determined by the Cahn–Ingold–Prelog (CIP) priority rules.^[1] This method provides a rigorous and unambiguous way to describe geometric isomerism where the traditional cis–trans nomenclature is inadequate, such as in tri- or tetra-substituted alkenes or when substituents have similar structures.^[2] Developed to address limitations in earlier naming conventions, the E–Z system was first proposed in 1968 by a team at the Chemical Abstracts Service, including J. E. Blackwood and colleagues, as part of an effort to unify stereochemical nomenclature across organic compounds.^[1] It was formally adopted and detailed in the IUPAC recommendations on stereochemistry published in 1976, replacing tentative rules from 1951 for olefinic hydrocarbons and extending applicability to all relevant double bonds, including those in chains, rings, and cumulative systems, while retaining cis–trans descriptors for simple disubstituted cases and monocyclic compounds.^[1] Under the CIP rules, priorities are assigned to substituents by comparing atomic numbers at the first point of difference, moving outward from the double-bonded carbon; if priorities tie, phantom atoms or further branching is considered to resolve them.^[2] The Z configuration indicates that the two highest-priority groups (one from each carbon) lie on the same side of the reference plane defined by the double bond and its attached atoms, while E denotes opposite sides; these descriptors are placed in parentheses before the compound name, with locants for multiple double bonds (e.g., (2E,4Z)-hexa-2,4-diene).^[1] This notation is essential for precise communication in synthesis, spectroscopy, and reactivity studies of unsaturated compounds, ensuring consistency in international chemical literature.^[2]

Fundamentals

Historical Development

The Cahn-Ingold-Prelog (CIP) system was first introduced in 1956 by Robert Sidney Cahn, Christopher Kelk Ingold, and Vladimir Prelog through their seminal paper "The Specification of Configuration in Optically Active Compounds," published in Experientia. This work established a systematic approach to assigning absolute configurations to chiral centers based on atomic numbers and substituent priorities, addressing the need for unambiguous stereochemical descriptors in organic molecules.^[3] Building on this foundation, the CIP rules were extended and formalized in a comprehensive 1966 review titled "Specification of Molecular Chirality" in Angewandte Chemie International Edition, which incorporated descriptors for various stereogenic units, including chiral centers and conformations. The E/Z notation for double bonds in alkenes, providing a priority-based method to describe geometric isomerism beyond the limitations of traditional cis-trans terminology, was proposed in 1968 by a team at the Chemical Abstracts Service, including J. E. Blackwood, C. L. Gladys, K. L. Loening, A. E. Petrarca, and J. E. Rush, as documented in Journal of the American Chemical Society and Journal of Chemical Documentation.^[1] This development was motivated by the requirement for a universal system applicable to all stereoisomers, ensuring consistency in nomenclature across complex structures. The 1968 proposal aligned closely with emerging IUPAC guidelines and was formally adopted in the IUPAC recommendations on stereochemistry published in 1976, standardizing E/Z descriptors within the broader CIP framework for international use in chemical literature. Vladimir Prelog's contributions to this system were recognized with the 1975 Nobel Prize in Chemistry, awarded for his research into the stereochemistry of organic molecules and reactions.^[4] Subsequent refinements to the CIP rules, including enhancements to E/Z notation for handling intricate molecular architectures such as those with multiple stereocenters or unsaturated systems, appeared in IUPAC's Nomenclature of Organic Chemistry (the Blue Book). Notable updates occurred in the 1993 edition, which clarified applications in preferred IUPAC names, and the 2013 edition, which further integrated considerations for priority assignment in complex cases.

Relation to Cis-Trans Notation

The cis-trans notation describes geometric isomerism in alkenes based on the relative positions of substituents with respect to the plane of the double bond, where "cis" indicates substituents on the same side and "trans" on opposite sides. This system works well for disubstituted alkenes with identical substituents on each carbon of the double bond, such as cis- and trans-2-butene, where the two methyl groups are either on the same side (cis) or opposite sides (trans) of the double bond.^[5] However, the cis-trans system has significant limitations and becomes ambiguous or inapplicable for trisubstituted or tetrasubstituted alkenes, where the substituents on each carbon of the double bond are not identical, making it unclear which groups are "across" or on the "same side."^[6] For instance, in 2-pentene, one carbon of the double bond bears a hydrogen and a methyl group, while the other bears a hydrogen and an ethyl group; without pairs of identical substituents, assigning cis or trans lacks a clear reference, leading to potential confusion in nomenclature.^[7] The E-Z notation addresses these shortcomings by providing a systematic method based on the Cahn-Ingold-Prelog (CIP) priority rules, which assign priorities to substituents according to atomic numbers; the configuration is then designated as Z (zusammen, meaning together) if the highest-priority groups are on the same side of the double bond, or E (entgegen, meaning opposite) if on opposite sides.^[8] In simple disubstituted cases like 2-butene, the E designation corresponds to the trans isomer and Z to the cis isomer, but E-Z extends reliably to all substitution patterns, including those where cis-trans fails.^[5] This transition to E-Z notation, proposed in 1968 and formalized by IUPAC in 1976 through the CIP rules, offers key advantages as the preferred IUPAC method, ensuring universal applicability, unambiguous stereochemical description, and consistency in chemical naming, database indexing, and literature communication.^[9]

Priority Rules

Cahn-Ingold-Prelog Sequence Rules

The Cahn-Ingold-Prelog (CIP) sequence rules provide a systematic, hierarchical method for assigning priorities to substituents attached to a stereogenic unit, such as the carbons in a double bond for E–Z designation. Priorities are ranked from 1 (highest) to 2 (lowest) for the two substituents on each double-bonded carbon based on the first point of difference when comparing the atoms and groups step by step, using a digraph representation that expands the molecular structure into ranked "spheres" or branches of attached atoms. This approach ensures unambiguous ordering by treating the substituent as a tree-like graph rooted at the attachment point to the double-bonded carbon.^[10] The primary rule (Rule 1a) assigns higher priority to the substituent with the atom of higher atomic number directly attached to the double-bonded carbon. For instance, among common atoms, the order is Br (atomic number 35) > Cl (17) > O (8) > C (6) > H (1), so a bromo group outranks a methyl group at the first point of comparison. If the directly attached atoms have the same atomic number, the comparison proceeds to the atoms attached to them (Rule 1b), ranking the sets of attached atoms in decreasing order of atomic number and comparing pairwise from the highest to the lowest until a difference is found; branches are explored simultaneously in parallel "spheres," with identical inner-sphere atoms taking precedence over identical outer-sphere atoms.^[10] Multiple bonds are handled by a duplication method to account for valence (part of Rule 1), where atoms involved in double or triple bonds are replicated as if bonded to identical phantom atoms of the same type, effectively simulating the higher connectivity. For example, a carbonyl group (=O) is treated as if the carbon is attached to two oxygen atoms and the oxygen to two carbons, with terminal phantoms having atomic number zero if necessary to balance valence. This rule elevates the priority of unsaturated groups, such as ranking -CH=CH₂ higher than -CH₂CH₃ because the duplicated representation gives the vinyl carbon attachments of (C,C,H) versus (C,H,H) at the first differing sphere.^[10] If atomic numbers are tied through all comparable atoms, Rule 2 resolves the priority by favoring the substituent with the higher atomic mass (isotopic mass number) at the first point of difference; for example, deuterium (²H, mass 2) outranks protium (¹H, mass 1). The lower priority (2) is typically assigned to hydrogen or the least substituted group, such as in the alkene CH₃CH=CHCl, where the chlorine atom directly attached to one of the double-bonded carbons receives priority 1 due to its higher atomic number (17) compared to hydrogen (1) on the same carbon.^[10]

Assigning Priorities to Substituents

In the context of E–Z notation, the two carbon atoms of an alkene double bond each bear two substituents, and the Cahn–Ingold–Prelog (CIP) sequence rules are applied independently to rank these substituents on each carbon, identifying the higher-priority group on each side for subsequent configuration assignment.^[10] This ranking ensures unambiguous stereodescriptors by prioritizing based on atomic connectivity rather than spatial arrangement.^[11] The step-by-step process starts at the point of attachment to the double-bond carbon. The atoms directly bound to this carbon are compared by atomic number, with higher atomic number conferring higher priority; ties are resolved by moving outward along substituent branches to the next atoms, repeating the comparison until a difference emerges. For example, in the alkene \ce{ClHC=CHBr}, the left carbon has substituents Cl and H, where Cl (atomic number 17) ranks higher than H (1); similarly, on the right carbon, Br (35) outranks H (1).^[10]^[11] When substituents involve carbon chains, they are represented as digraphs—tree-like structures expanding from the attachment point—and ranked by listing attached atoms in decreasing order of atomic number at each level, duplicating atoms for multiple bonds if necessary. Consider \ce{-CH2CH3} versus \ce{-CH(CH3)2}: both attach via C, but the first C in \ce{-CH2CH3} connects to (C, H, H), while in \ce{-CH(CH3)2} it connects to (C, C, H); the branched chain receives higher priority due to the second C exceeding H at the first point of difference.^[10]^[11] A frequent error in priority assignment is relying on molecular weight or size instead of atomic number sequences, which can lead to incorrect rankings. For instance, the substituent \ce{-I} has higher priority than \ce{-CH2CH2CH2CH3}, as I (atomic number 53) surpasses the initial C (6) of the chain, regardless of the alkyl group's greater mass.^[10]^[11] To aid visualization, priority diagrams depict the double bond with substituents labeled: the higher-priority group on each carbon marked as "1" and the lower as "2," facilitating quick assessment of relative positions without full CIP reapplication.^[10] These diagrams emphasize the independent ranking per carbon, underscoring the CIP rules' focus on topological priority over empirical properties.^[11]

Configuration Assignment

Determining E or Z Configuration

Once the priorities of the substituents attached to each carbon atom of the double bond have been determined using the Cahn-Ingold-Prelog sequence rules, the E or Z configuration is assigned by examining the relative positions of the highest-priority substituent on each carbon.^[11] The two carbons of the double bond are considered, and the substituent with the highest priority (ranked as 1) on each is identified. The configuration is designated as Z (from the German zusammen, meaning "together") if the two highest-priority substituents are located on the same side of the double bond.^[8] Conversely, it is designated as E (from the German entgegen, meaning "opposite") if these substituents are on opposite sides of the double bond.^[8] This determination relies on viewing the molecule in a planar representation where the double bond lies flat, allowing a clear assessment of whether the high-priority groups are cis-like (Z) or trans-like (E).^[10] In descriptive terms, the rule can be summarized as follows: if the priority-1 substituent on the first carbon of the C=C bond and the priority-1 substituent on the second carbon are on the same side, the configuration is Z; if on opposite sides, it is E.^[11] A classic example is 2-butene (CH₃-CH=CH-CH₃). On each carbon of the double bond, the methyl group (CH₃) has higher priority than the hydrogen atom (H). In the isomer where the two methyl groups are on opposite sides, the configuration is E, as the highest-priority substituents are trans to each other.^[12]

Notation in Molecular Formulas

In IUPAC nomenclature, the E or Z descriptor is placed as an italicized prefix in parentheses at the beginning of the complete name, immediately preceding the root name, and is accompanied by a numerical locant to specify the position of the configured double bond. For compounds featuring multiple double bonds, separate E or Z descriptors, each with its own locant, are cited in ascending numerical order within the same set of parentheses. This systematic placement ensures unambiguous identification of stereochemical configurations in chemical names. The International Union of Pure and Applied Chemistry (IUPAC) prefers E/Z descriptors over the older cis/trans notation in preferred IUPAC names (PIN) for all cases involving double bond stereochemistry, as E/Z provides a more precise and universally applicable method based on sequence rules, a recommendation formalized in the IUPAC Blue Book. While cis/trans remains acceptable in general or retained nomenclature for simple disubstituted cases, E/Z is mandatory for preferred names to avoid ambiguity in complex structures. In two-dimensional structural formulas, E/Z configurations are typically depicted by drawing the double bond with substituents arranged on the same side (Z) or opposite sides (E) of the bond axis, often supplemented with explicit "E" or "Z" labels adjacent to the double bond for clarity. Three-dimensional representations, such as in molecular modeling software, illustrate the planar geometry of the double bond with substituents in the appropriate cis or trans orientation relative to the pi bond plane, sometimes using dashed or wedged lines to emphasize spatial relationships. In computational chemistry and databases, E/Z stereochemistry is encoded in line notations for machine-readable representation. The Simplified Molecular Input Line Entry System (SMILES) uses directional bond symbols "/" and "" around the "=" to specify the relative positions of substituents; for instance, opposite directional bonds indicate the E configuration, while matching directions denote Z. The IUPAC International Chemical Identifier (InChI) incorporates double bond stereochemistry in its "/b" layer, employing "+" or "-" suffixes after bond locants to distinguish E (trans-like) from Z (cis-like) arrangements. These encodings facilitate the storage, retrieval, and interconversion of stereospecific molecular data in chemical informatics systems.

Applications and Examples

Use in IUPAC Nomenclature

E/Z notation is integrated into the IUPAC systematic nomenclature for unsaturated organic compounds, particularly alkenes featuring carbon-carbon double bonds, as a stereodescriptor to specify the geometric configuration around the double bond in both acyclic chains and cyclic structures.^[10] It relies on the Cahn-Ingold-Prelog (CIP) priority rules to assign priorities to substituents on each end of the double bond, designating "E" when the higher-priority groups are on opposite sides and "Z" when on the same side.^[8] This notation is mandatory for preferred IUPAC names (PINs) of compounds where the double bond exhibits stereoisomerism, ensuring unambiguous identification of isomers that cannot be distinguished by cis/trans descriptors alone.^[10] In naming acyclic alkenes, the parent chain is selected as the longest continuous carbon chain that includes the double bond, with numbering directed to assign the lowest possible locant to the double bond's first carbon atom; the E/Z descriptor is then incorporated as a prefix immediately preceding the base name, enclosed in parentheses and italicized.^[10] For compounds with multiple double bonds, locants for each are cited in ascending order, followed by the corresponding E or Z descriptors in sequence, such as (2E,4Z)-hexa-2,4-diene.^[10] In cyclic compounds, E/Z notation applies primarily to exocyclic double bonds or endocyclic double bonds in rings of eight or more members where cis/trans becomes inadequate due to potential ambiguity; for smaller rings, cis/trans may still be used in general nomenclature, but E/Z is preferred for PINs.^[10] The stereodescriptors take precedence in the full name construction, positioned at the front and separated by hyphens from the locants and base name, as in (2E)-but-2-en-1-ol, where the functional group suffix follows standard priority rules.^[10] The 2013 IUPAC Recommendations (Blue Book) explicitly mandate E/Z for all geometric isomers of alkenes in PINs, superseding prior allowances for cis/trans except in retained names for simple disubstituted cases or specific contexts like retinoids, to promote consistency and clarity across complex structures.^[10] In seniority rules for choosing the parent structure, a "Z" configuration is given higher priority than "E" when comparing alternative naming options.^[10]

Common Examples in Organic Compounds

One of the simplest examples of E/Z notation is found in 1,2-dichloroethene, which exhibits geometric isomerism due to the restricted rotation around the carbon-carbon double bond. In (E)-1,2-dichloroethene, the two chlorine atoms are on opposite sides of the double bond, with each carbon atom also bearing a hydrogen atom on the opposite side; this configuration is determined by assigning higher priority to Cl over H on each carbon using Cahn-Ingold-Prelog rules.^[13] In contrast, (Z)-1,2-dichloroethene has both chlorine atoms on the same side of the double bond, with hydrogens on the other side. In 2D structural representations, (E)-1,2-dichloroethene is often depicted as Cl\H C=C H\Cl, emphasizing the trans arrangement, while (Z)-1,2-dichloroethene appears as Cl/H C=C Cl\H, showing the cis arrangement.^[14] A disubstituted alkene example is 2-pentene, where the double bond between carbons 2 and 3 has one hydrogen on each carbon and alkyl groups of different lengths. In (E)-2-pentene, the higher-priority substituents—methyl (CH₃) on carbon 2 and ethyl (CH₂CH₃) on carbon 3—are positioned on opposite sides of the double bond, with the lower-priority hydrogens on the same side. The Z isomer reverses this, placing the methyl and ethyl groups on the same side. Structural drawings typically illustrate (E)-2-pentene as CH₃-CH=CH-CH₂CH₃ with the CH₃ and CH₂CH₃ trans to each other, often using a zigzag chain to highlight the configuration, whereas the Z form shows them cis.^[15] In natural products, (E)-β-farnesene serves as the primary alarm pheromone for many aphid species, triggering defensive behaviors among conspecifics. This sesquiterpene features a trisubstituted double bond where the E configuration is assigned based on Cahn-Ingold-Prelog priorities of the long isoprenoid chains versus hydrogen and methyl groups. The molecule's extended chain structure requires careful priority assignment to distinguish the higher atomic number paths in the substituents. In 2D depictions, (E)-β-farnesene is shown as a linear chain with the key double bond having the two main carbon chains trans, labeled as (E) to indicate the opposite positioning of the higher-priority groups.^[16]^[17] Pharmaceutical compounds like retinoids demonstrate how E/Z configurations influence biological activity. All-E-retinoic acid, also known as all-trans-retinoic acid, has all four double bonds in the E configuration, which is crucial for its role in cell differentiation and treatment of conditions such as acute promyelocytic leukemia, where deviations to Z isomers can reduce efficacy or alter receptor binding. The polyene chain's configurations are specified to ensure the correct spatial arrangement for biological interactions. Structural representations label each double bond as (E), often shown in a extended chain format with the carboxylic acid at one end and the cyclohexene ring at the other, emphasizing the trans geometries along the chain.^[18]^[19]

Special Cases

Undefined or Unspecified Stereochemistry

In cases where a double bond has two identical substituents attached to at least one of the sp²-hybridized carbon atoms, such as in terminal alkenes like propene (CH₃CH=CH₂), no stereoisomerism exists, and thus the E/Z designation cannot be applied.^[20] Similarly, symmetric disubstituted alkenes like (CH₃)₂C=CH₂ lack distinct configurations, rendering E/Z irrelevant as the substituents on one carbon are indistinguishable by CIP rules.^[20] These structural features prevent the assignment of priorities that would differentiate potential isomers, leading to the omission of any stereodescriptor in the name. For cyclic alkenes, E/Z descriptors are omitted for double bonds in three- to seven-membered rings, as the configuration is fixed as cis (Z); they are required for larger rings, such as (E)-cyclooctene.^[21] For mixtures of E and Z isomers, such as equilibrium mixtures of 2-butene, the stereochemistry is often unspecified in nomenclature unless the composition is detailed, in which case the name is given without an E/Z prefix to indicate the combined form.^[20] Racemic or undefined mixtures are denoted similarly, avoiding assignment to prevent implying a single configuration; for instance, the compound is simply named but-2-ene rather than (E)- or (Z)-but-2-ene.^[20] This approach ensures clarity when the exact stereochemical state is not isolated or relevant. Prior to the introduction of the CIP rules in 1966, the cis/trans notation was commonly applied even to ambiguous cases where substituents lacked clear "high" and "low" priority distinctions, leading to inconsistent descriptions.^[11] The E/Z system addressed these limitations by providing a rigorous priority-based method, reducing reliance on relative descriptors. In modern chemical databases, such as PubChem, unresolved or unspecified E/Z configurations are marked as "undefined," often visualized with a crossed double bond to avoid erroneous assignments.^[22] IUPAC recommends omitting stereodescriptors when configuration is unknown or unassignable, or using notations like the Greek letter ξ (italicized) for partial specification, or explicit phrases such as "stereochemistry unspecified" or "stereochemistry not assigned" in contexts requiring detail.^[20]

Handling Symmetric or Identical Substituents

In cases where at least one of the carbon atoms in a carbon-carbon double bond bears two identical substituents, geometric stereoisomerism is not possible, and thus E/Z notation does not apply. According to IUPAC recommendations, E/Z descriptors are defined only for double bonds where each participating carbon atom has two different substituents (R₁R₂C=CR₃R₄ with R₁ ≠ R₂ and R₃ ≠ R₄), as identical substituents on either carbon eliminate the possibility of distinct configurations. For example, in 2,3-dimethylbut-2-ene, represented as (CH₃)₂C=C(CH₃)₂, each sp²-hybridized carbon is attached to two methyl groups, resulting in a single achiral molecule with no E or Z isomer.^[21] In contrast, cumulated double bond systems like allenes exhibit axial chirality governed by extended CIP rules, where E/Z descriptors are generally not used—instead, (R) and (S) designations apply to the orthogonal planes of the cumulene framework—though simple alkene symmetry cases remain the primary context for nullification in E/Z nomenclature.^[21] Pseudo-asymmetric stereogenic units, though rare in alkenes, may arise in molecules featuring a tetrahedral carbon adjacent to a double bond, where the carbon bears two identical substituents alongside two constitutionally different but enantiomeric ligands. In such scenarios, the double bond retains standard E/Z assignment if stereogenic, while the pseudo-asymmetric center is denoted with lowercase (r) or (s) to indicate relative configuration, as per IUPAC guidelines distinguishing it from true chiral centers. This notation highlights the center's stereogenicity without implying absolute chirality, and its presence does not alter the E/Z rules for the adjacent alkene.^[23] To resolve E/Z assignments in otherwise symmetric or near-symmetric alkenes where standard methods fail due to indistinguishable substituents, researchers employ isotopic labeling to introduce subtle differences. By replacing a hydrogen atom with deuterium (²H) or another isotope on one substituent, the CIP priority sequence can be perturbed, enabling clear distinction between configurations via spectroscopic or crystallographic analysis. This approach has been demonstrated in gas-phase studies of ionic species, where isotopic tags facilitate identification of E and Z isomers in symmetric frameworks.^[24]

References

[1]
[PDF] STEREOCHEMISTRY - iupac
This Section of the IUPAC Rules for Nomenclature of. Organic Chemistry differs from previous Sections in that it is here necessary to legislate for words ...
[2]
E- and Z-nomenclature of alkenes - University of Calgary
The E- and Z- style is more reliable and particularly suited to tri- or tetra-substituted alkenes, and especially when the substituents are not alkyl groups.Missing: notation definition
[3]
50th Anniversary of the Cahn-Ingold-Prelog Rules - ChemistryViews
May 9, 2016 · The CIP method was published in 1956, and the 1966 review consolidated and extended the rules. In the 50 years that have followed, the CIP system has become ...
[4]
Vladimir Prelog – Facts - NobelPrize.org
Vladimir Prelog began researching the connection between the structures of organic molecules and how they react.
[5]
8.5: The E/Z System (when cis/trans does not work)
May 19, 2021 · The rigorous IUPAC system for naming alkene isomers, called the EZ system, is based on the same priority rules.E/Z Nomenclature in Alkenes · E/Z will work -- even when cis...
[6]
The E-Z system for naming alkenes - Chemistry LibreTexts
Jan 22, 2023 · The rigorous IUPAC system for naming alkene isomers, called the EZ system, is based on the same priority rules.
[7]
Cis and Trans Isomers and Cis Trans Practice Problems
The cis and trans designation is not determined based on alkyl groups only. For example, 2-pentene is not a symmetrical molecule thus we cannot have two ...
[8]
E, Z (E01882) - IUPAC Gold Book
The stereoisomer is designated as Z (zusammen = together) if the groups lie on the same side of a reference plane passing through the double bond and ...
[9]
E and Z Notation For Alkenes (+ Cis/Trans) - Master Organic Chemistry
Feb 28, 2025 · E/Z is the preferred, more comprehensive nomenclature since it describes absolute configuration, whereas cis- trans- merely describes relative configuration.
[10]
[PDF] IUPAC Recommendations and Preferred Names 2013
... rules for parent structures with retained names. P-15.2. Functional Class ... Cahn-Ingold-Prelog (CIP) System: General Methodology. P-92.1.1. Stereogenic ...
[11]
Specification of Molecular Chirality - Cahn - Wiley Online Library
The topological analysis of chiral molecular models has provided the framework of a general system for the specification of their chirality.
[12]
https://chem.libretexts.org/Bookshelves/Organic_Chemistry/Organic_Chemistry_(Morsch_et_al.)/07:_Alkenes_-_Structure_and_Reactivity/7.06:_Sequence_Rules_-_The_EZ_Designation
[13]
1,2-Dichloroethylene | ClCH=CHCl | CID 10900 - PubChem
Trans-1,2-dichloroethene (1,2-DCE) is one of two isomers of 1,2-dichloroethene. It is a highly flammable, colorless liquid with a sharp, harsh odor. 1,2-DCE ...
[14]
1,2-Dichloroethylene - the NIST WebBook
Stereoisomers: Ethylene, 1,2-dichloro-, (Z)- · Ethylene, 1,2-dichloro-, (E)-. Other names: 1,2-Dichloroethene,c&t; 1,2-Dichloroethylene,c&t; Ethene, 1,2 ...
[15]
https://webbook.nist.gov/cgi/cbook.cgi?ID=C646048
[16]
beta-Farnesene | C15H24 | CID 5281517 - PubChem - NIH
Trans-beta-farnesene is a beta-farnesene in which the double bond at position 6-7 has E configuration. It is the major or sole alarm pheromone in most species ...
[17]
Does the Aphid Alarm Pheromone (E)-β-farnesene Act as ... - PubMed
Mar 17, 2015 · The aphid alarm pheromone, (E)-β-farnesene (EBF), is believed to be such a cue, because several aphid enemies are able to perceive EBF and show ...
[18]
Retinoic Acid | C20H28O2 | CID 444795 - PubChem - NIH
Retinoic Acid | C20H28O2 | CID 444795 - structure, chemical names ... Tretinoin/All-Trans Retinoic Acid · Acid A Vit (Belgium, Netherlands) · (all-E)- ...
[19]
Preparation and biological activity of 13-substituted retinoic acids
13-Demethyl or 13-substituted all-E- and 9Z-retinoic acids were synthesized using a palladium-catalyzed coupling reaction of enol triflates and ...
[20]
None
Below is a merged and comprehensive summary of E/Z stereodescriptors for double bonds based on sections P-92 and P-93 of the IUPAC Blue Book (2013), consolidating all information from the provided summaries. To retain maximum detail in a dense and organized format, I will use a combination of narrative text and a table in CSV format for key details. The response avoids redundancy while ensuring all unique points are included.
[21]
PubChem chemical structure standardization - PMC - PubMed Central
Aug 10, 2018 · In PubChem, if the E/Z configuration of a double bond cannot be resolved, it is configured as 'undefined' and represented as a 'crossed ...
[22]
[PDF] PDF - IUPAC nomenclature
The omission of stereodescriptors specifying double bonds is recommended in the case of three- through seven- membered unsaturated alicyclic compounds where any ...Missing: 1966 EZ
[23]
pseudo-asymmetric carbon atom (P04921) - IUPAC Gold Book
The traditional name for a tetrahedrally coordinated carbon atom bonded to four different entities, two and only two of which have the same constitution but ...
[24]
Tag effects, isotopic labels, and identification of the E,Z isomer ... - NIH
We report the vibrational spectra of both N- and O-protomers of the cryogenically cooled ions in the gas phase over the spectral range 800–4000 cm −1.