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Chloroacetate is a group of organic compounds derived from acetic acid, where one or more hydrogen atoms are replaced by chlorine atoms. These compounds are highly reactive and serve as valuable intermediates in the synthesis of various chemicals, including pharmaceuticals, herbicides, and insecticides. Their reactivity allows for the introduction of the chloroacetyl functional group into organic molecules, making them essential building blocks in organic synthesis. However, due to their toxic nature, chloroacetate compounds necessitate careful handling and disposal to minimize adverse effects on the environment and human health.

14526-03-5

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14526-03-5 Usage

Uses

Used in Pharmaceutical Industry:
Chloroacetate is used as a chemical intermediate for the synthesis of various pharmaceuticals. Its reactivity enables the introduction of the chloroacetyl functional group into organic molecules, facilitating the development of new drugs with improved therapeutic properties.
Used in Agrochemical Industry:
Chloroacetate is utilized as a precursor in the production of herbicides and insecticides. Its ability to introduce the chloroacetyl functional group into organic molecules contributes to the creation of effective crop protection agents that help control weeds and pests, ensuring higher crop yields and food security.
Used in Organic Synthesis:
Chloroacetate is employed as a versatile building block in organic synthesis. Its high reactivity allows for the formation of various organic compounds through chemical reactions, making it an essential component in the synthesis of complex organic molecules for various applications, including materials science, fragrances, and dyes.

Check Digit Verification of cas no

The CAS Registry Mumber 14526-03-5 includes 8 digits separated into 3 groups by hyphens. The first part of the number,starting from the left, has 5 digits, 1,4,5,2 and 6 respectively; the second part has 2 digits, 0 and 3 respectively.
Calculate Digit Verification of CAS Registry Number 14526-03:
(7*1)+(6*4)+(5*5)+(4*2)+(3*6)+(2*0)+(1*3)=85
85 % 10 = 5
So 14526-03-5 is a valid CAS Registry Number.

14526-03-5SDS

SAFETY DATA SHEETS

According to Globally Harmonized System of Classification and Labelling of Chemicals (GHS) - Sixth revised edition

Version: 1.0

Creation Date: Aug 16, 2017

Revision Date: Aug 16, 2017

1.Identification

1.1 GHS Product identifier

Product name chloroacetate

1.2 Other means of identification

Product number -
Other names CHLOROACETIC-ACID

1.3 Recommended use of the chemical and restrictions on use

Identified uses For industry use only.
Uses advised against no data available

1.4 Supplier's details

1.5 Emergency phone number

Emergency phone number -
Service hours Monday to Friday, 9am-5pm (Standard time zone: UTC/GMT +8 hours).

More Details:14526-03-5 SDS

14526-03-5Relevant academic research and scientific papers

How the sustainable solvent water unleashes the photoredox catalytic potential of ruthenium polypyridyl complexes for pinacol couplings

Naumann, Robert,Goez, Martin

supporting information, p. 4470 - 4474 (2019/08/21)

By complementing laser flash photolysis with product studies in visible-LED driven syntheses, we show that the one-electron reduced forms OER of tris(2,2′-bipyridine)ruthenium(ii) and its more reactive derivative with 4,4′-dimethylated ligands exhibit a reductive power greater by 0.2 eV in water than in acetonitrile; and that this difference allows the reduction of carbonyl compounds, and thus pinacol couplings, in aqueous medium via ruthenium-based photoredox catalysis as an alternative to using more expensive and less photostable higher-energy complexes (e.g., of iridium). Ascorbate serves as sacrificial donor to access OER. SDS micelles or cyclodextrins as carriers help overcome solubility problems of less hydrophilic substrates, and more reactive water-soluble substrates can even be coupled at neutral pH, such that the mild conditions make the process fully sustainable.

Solvolytic Behavior of Aliphatic Carboxylates

Matic, Mirela,Denegri, Bernard,Kronja, Olga

supporting information, p. 1477 - 1486 (2015/10/05)

The leaving group abilities (nucleofugalities) of a series of aliphatic carboxylates have been obtained by determining the nucleofuge-specific parameters (Nf and sf) from solvolysis rate constants of X,Y-substituted benzhydryl carboxylates in a series of aqueous ethanol mixtures by applyication of the linear free energy relationship (LFER) equation: log k = sf (Ef + Nf). These values can be employed to compare reactivities of carboxylates with those of other leaving groups previously included in the nucleofugality scale, and also to estimate the solvolysis rates of various carboxylates. It is confirmed that the inductive effect is the most important variable governing the reactivities of halogenated carboxylates in solution. Moreover, both the Hammett correlation and the solvolytic activation parameters have revealed a strong influence of the inductive effect on the nucleofugality of alkyl-substituted carboxylates. The reaction constants (sf) indicate that carboxylate substrates with weaker leaving groups solvolyze via later, more carbocation-like, transition states, which is in accord with the Hammond postulate. In addition, due to the weaker demand for solvation of transition states that produce more strongly stabilized benzhydrylium ions, in which more efficient charge delocalization occurs, the reaction constants (sf) obtained with most of the leaving groups investigated here increase as the polarity of the solvent decreases.

The Ever-surprising chemistry of boron: Enhanced acidity of phosphine·boranes

Hurtado, Marcela,Yanez, Manuel,Herrero, Rebeca,Guerrero, Andres,Juan Z. Davalos,Jose-Luis, M. Abboud,Khater, Brahim,Guillemin, Jean-Claude

supporting information; experimental part, p. 4622 - 4629 (2009/12/29)

The gas-phase acidity of a series of phosphines and their corresponding phosphine·borane derivatives was measured by FT-ICR techniques. BH 3 attachment leads to a substantial increase of the intrinsic acidity of the system (from 80 to 110 kJ mol-1). This acidity-enhancing effect of BH3 is enormous, between 13 and 18 orders of magnitude in terms of ionization constants. This indicates that the enhancement of the acidity of protic acids by Lewis acids usually observed in solution also occurs in the gas phase. High- level DFT calculations reveal that this acidity enhancement is essentially due to stronger stabilization of the anion with respect to the neutral species on BH3 association, due to a stronger electron donor ability of P in the anion and better dispersion of the negative charge in the system when the BH3 group is present. Our study also shows that deprotonation of ClCH2PH2 and ClCH 2PH2·BH3 is followed by chloride departure. For the latter compound deprotonation at the BH3 group is found to be more favorable than PH2 deprotonation, and the subsequent loss of Cl- is kinetically favored with respect to loss of Cl - in a typical SN2 process. Hence, ClCH2PH 2·BH3 is the only phosphine·borane adduct included in this study which behaves as a boron acid rather than as a phosphorus acid.

Kinetics of reversible carbon deprotonation of 2-nitroethanol and 2-nitro-1,3-propanediol by hydroxide ion, water, amines, and carboxylate ions. A normal br?nsted α despite an imbalanced transition state

Bernasconi, Claude F.,Panda, Markandeswar,Stronach, Michael W.

, p. 9206 - 9212 (2007/10/03)

Rates of reversible carbon deprotonation of 2-nitroethanol (2) and 2-nitro-1,3-propanediol (3) by hydroxide ion, water, amines, and carboxylate ions and pKa values for the ionization at carbon (pKaCH) and oxygen (pKaOH) and ionization of the aci-forms (pKaNOH) were determined in aqueous solution at 25 °C. The pKaCH values for 2 and 3 are 8.60 and 7.68, respectively, as compared to 10.22 for CH3NO2. The acidifying effect of the CH2OH groups is attributed to a combination of inductive electron withdrawal and hyperconjugative stabilization of the respective nitronate ions, possibly coupled with intramolecular hydrogen bonding stabilization of this ion. The higher acidity of 2-nitroethanol compared to nitromethane is reflected in higher rates of proton transfer from 2-nitroethanol, implying a "normal" Br?nsted α between 0 and 1. This contrasts with the negative α value based on the reaction of OH- with nitromethane, nitroethane, and 2-nitropropane (Kresge, A. J. Can. J. Chem. 1974, 52, 1897). Reasons why a normal α value is observed in the current system are discussed.

Structure-Activity Relationships in the Esterase-catalysed Hydrolysis and Transesterification of Esters and Lactones

Barton, Patrick,Laws, Andrew P.,Page, Michael I.

, p. 2021 - 2030 (2007/10/02)

The Broensted exponents for the alkaline hydrolysis of alkyl esters are 1.3 and 0.4 for substitution in the acyl and alcohol portions, respectively, which is indicative of a transition state which resembles the anionic tetrahedral intermediate with a localised negative charge.By contrast, the rate of the pig liver esterase (PLE)-catalysed hydrolysis shows little dependence upon the electron-withdrawing power of substituents.The values of kcat are independent of the pKa of the leaving group alcohol suggesting rate-limiting deacylation.There is a small steric effect of α-substitution in both the alcohol and carboxylic acid residues for the enzyme-catalysed reactions but the enzyme rate enhancement factor remains high for most esters.There is no substantial ee observed for the hydrolysis of racemic esters although the kinetic data can be used for determining the regioselective hydrolysis of diesters.Unsubstituted lactones are poor substrates for PLE but derivatives with hydrophobic substituents show kcat/Km values similar to those for acyclic esters.Dihydrocoumarin undergoes transesterification catalysed by PLE, kcat increases with increasing alcohol concentration indicative of rate-limiting deacylation.There is enantioselectivity in the PLE-catalysed hydrolysis of some racemic lactones but little or none in the transesterification of racemic alcohols with dihydrocoumarin.

PHYSICOCHEMICAL ANALYSIS AND THERMODYNAMICS OF THE EQUILIBRIA OF DIMETHYL SULFOXIDE-CARBOXYLIC ACID BINARY LIQUID SYSTEMS

Fialkov, Yu. Ya.,Bondarenko, E. S.

, p. 735 - 739 (2007/10/02)

Density, viscosity, electric-conductivity, and dielectric-constant measurements were made over the temperature range 298.15 - 323.15 K on binary liquid systems formed by DMSO with acetic acid and monochloro-, dichloro-, trichloro-, and trifluoro-acetic acids.The formation of the addition products DMSO*(HA)2 and DMSO*HA was established; in the system with trifluoroacetic acid the adducts DMSO*(HA)2 and DMSO*2(HA)2 are formed (HA = the acid).By the method of seeking the minimum of the function of least squares with the variation of the variables sought over the whole range of concentrations and of values of the molar volume we determined the equilibrium constants and thermodynamic characteristics of the process of the formation of adducts and also the densities of the latter.It was shown that between the enthalpies and entropies of the processes studied a compensation effect is observed.

Formation and Stability of Ring-Substituted 1-Phenylethyl Carbocations

Richard, John P.,Rothenberg, Marc E.,Jencks, William P.

, p. 1361 - 1372 (2007/10/02)

The solvolysis of 1-phenylethyl derivatives with electron-donating 4-substituents in 50:50 trifluoroethanol:water(v:v) occurs at a rate that is independent of azide concentration but gives yields of the corresponding azide adducts of up to 98percent by trapping a carbocation intermediate.Rate constants for reactions of the cations with solvent range from 2 x 103 s-1 (4-Me2N) to 4 x 109 s-1 (4-Me), assuming a diffusion-controlled rate constant of 5 x 109 M-1 s-1 for their reactions with azide and thiol anions.Correlation of the rate constants following the Yukawa-Tsuno treatment gives ρn = 2.5, ρr = 5.2, and r+ = 2.1 for the reaction with trifluoroethanol, and ρn = 2.7, ρr = 4.9, and r+ = 1.8 for the reaction with water.The reverse reaction, acid-catalyzed cleavage of substituted 1-phenylethyl alcohols to give the corresponding carbocation, follows ρn = -4.9, ρr = -4.4, and r+ = 0.9.This gives values of ρn = -7.6, ρr = -9.3, and r+ = 1.2 for formation of the cations at equilibrium.There is an imbalance in the development of resonance delocalization, analogous to the "nitroalkane anomaly", that is consistent with a dependence of the fraction of maximal resonance delocalization on the fraction of rehybridization or C-X bond cleavage.Solvent effects on carbocation stability in aqueous-organic mixtures are relatively small.They depend mainly on the nucleophilicity of the solvent components and a specific solvent effect of trifluoroethanol on the reactivity of hydroxylic nucleophiles, including trifluoroethanol itself.The "ionizing power" of the solvent has only a small effect on cation stability, and there is little effect of the concentration or nature of added salts.

Determination of Chemical Reaction Rate Constants Preceding or Following Electron Transfer by Mechanical Square Wave Polarography

Sin-rhu, Lin,Qiang-sheng, Feng

, p. 1362 - 1367 (2007/10/02)

A simple and convenient method for determining the chemical reaction rate constants of chemical reaction followed by electron transfer (CE) and electron transfer followed by chemical reaction (EC) processes has been developed by means of mechanical square wave polarography.To test the theory, we studied the dissociation of SbIIIEDTA complex and monochloroacetic acid and the benzidine rearrangement of hydrazobenzene produced by the electrode reduction of azobenzene.The results were shown to be compatible with data of other investigators.

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