27754-99-0

Basic information

• Product Name: POLY(VINYLPHOSPHONIC ACID)
• Synonyms: POLYETHENYLPHOSPHONIC ACID;POLYVINLYPHOSPHONIC ACID;POLY(VINYLPHOSPHONIC ACID);PVPA;ethenyl-phosphonicacihomopolymer;Phosphonicacid,ethenyl-,homopolymer;Polyvinylphosphonsure (MW ca. 8000);ethenyl-phosphonic acid homopolymer
• CAS NO: 27754-99-0
• Molecular Formula: C2H5O3P
• Molecular Weight: 108.033061
• EINECS: 217-123-2
• Product Categories: Polymer Science;Polymers;Hydrophilic Polymers;Vinyl Acids;Alternative Energy;Materials Science;Membranes
• Mol File: 27754-99-0.mol

Chemical Properties

• Boiling Point: 266.2 °C at 760 mmHg
• Flash Point: 114.8 °C
• Appearance: /
• Density: 1.425 g/cm³
• CAS DataBase Reference: POLY(VINYLPHOSPHONIC ACID)(CAS DataBase Reference)
• NIST Chemistry Reference: POLY(VINYLPHOSPHONIC ACID)(27754-99-0)
• EPA Substance Registry System: POLY(VINYLPHOSPHONIC ACID)(27754-99-0)

Safety Data

• Hazard Codes: Xi:
• WGK Germany: 1
• Hazardous Substances Data: 27754-99-0(Hazardous Substances Data)

Usage

Uses

Used in Energy Industry:
Poly(vinylphosphonic Acid) is used as a proton conductor for fuel cells, contributing to the efficient conversion of chemical energy into electrical energy.
Used in Chemical and Biological Applications:
Poly(vinylphosphonic Acid) is used as a component in chemical and biological sensors, leveraging its ability to interact with various materials and detect specific substances.
Used in Material Science:
Poly(vinylphosphonic Acid) is used as a key component in the development of biocomposite materials, where it enhances the properties of the composite by improving its interaction with biological systems.
Used in Surface Modification and Adhesion:
Poly(vinylphosphonic Acid) is used for surface modification and adhesion purposes, improving the bonding and interaction between different materials, leading to enhanced performance and durability.

Upstream product

• 1438-74-0 vinyldichlorophosphine oxide 
• 18291-41-3 vinylphosphonic acid bis(trimethylsilyl) ester 
• 16672-87-0 2-chloroethylphosphonic acid 
• 53128-14-6 bis(4-methoxyphenyl) vinylphosphonate 
• 50655-62-4 2-Acetoxyethanphosphonseauredichlorid 
• 42152-01-2 disodium 2-chloroethanephosphonate 
• 66224-66-6 adenine 
• 75-77-4 chloro-trimethyl-silane 
• 115-98-0 bis(2-chloroethyl) vinylphosphonate 
• 39118-50-8 2-acetoxyethanephosphonic acid dimethyl ester 
• 1259061-46-5 C₁₄H₂₇O₄P 
• 6294-34-4 bis(2-chloroethyl) 2-chloroethylphosphonate 
• 682-30-4 Diethyl vinylphosphonate 
• 7283-64-9 dibenzyl vinylphosphonate 

Downstream Products

• 58436-39-8 ethenylphosphine 

Relevant articles and documents

METHOD FOR PRODUCING PHOSPHONIC ACID DERIVATIVE

PROBLEM TO BE SOLVED: To provide a method for producing a phosphonic acid derivative, in which the reaction proceeds under relatively mild reaction conditions without using hydrogen halide or a metal catalyst. SOLUTION: Provided is a method for producing a phosphonic acid derivative represented by formula (1), comprising a step in which an ester group-containing phosphonic acid derivative is reacted in a solvent or without a solvent in the presence of a superacid catalyst. (In formula (1), R1 and R2 are each independently a substituted or unsubstituted hydrocarbon group that may contain a heteroatom, n is a natural number of 1 to 3, m is a natural number of 0 to 2, o is a natural number of 0 to 1, and n + m + o = 3.). SELECTED DRAWING: None COPYRIGHT: (C)2021,JPOandINPIT

Wet and dry processes for the selective transformation of phosphonates to phosphonic acids catalyzed by br?nsted acids

A "wet"process and two "dry"processes for converting phosphonate esters to phosphonic acids catalyzed by a Bronsted acid have been developed. Thus, in the presence of water, a range of alkyl-, alkenyl-, and aryl-substituted phosphonates can be generally hydrolyzed to the corresponding phosphonic acids in good yields catalyzed by trifluoromethyl sulfonic acid (TfOH) at 140 °C (the wet process). On the other hand, with specific substituents of the phosphonate esters, the conversion to the corresponding phosphonic acids can be achieved under milder conditions in the absence of water (the dry process). Thus, the conversion of dibenzyl phosphonates to the corresponding phosphonic acids took place smoothly at 80 °C in toluene or benzene in high yields. Moreover, selective conversion of benzyl phosphonates RP(O)(OR′)(OBn) to the corresponding mono phosphonic acids RP(O)(OR′)(OH) can also be achieved under the reaction conditions. The dealkylation via the generation of isobutene of ditert- butyl phosphonate, and the related catalysis by TfOH took place even at room temperature to give the corresponding phosphonic acids in good to high yields. Nafion also shows high catalytic activity for these reactions. By using Nafion as the catalyst, phosphonic acids could be easily prepared on a large scale via a simple process.

Zwitterionic pyrrolidene-phosphonates: Inhibitors of the glycoside hydrolase-like phosphorylase: Streptomyces coelicolor GlgEI-V279S

We synthesized and evaluated new zwitterionic inhibitors against glycoside hydrolase-like phosphorylase Streptomyces coelicolor (Sco) GlgEI-V279S which plays a role in α-glucan biosynthesis. Sco GlgEI-V279S serves as a model enzyme for validated anti-Tuberculosis (TB) target Mycobacterium tuberculosis (Mtb) GlgE. Pyrrolidine inhibitors 5 and 6 were designed based on transition state considerations and incorporate a phosphonate on the pyrrolidine moiety to expand the interaction network between the inhibitor and the enzyme active site. Compounds 5 and 6 inhibited Sco GlgEI-V279S with Ki = 45 ± 4 μM and 95 ± 16 μM, respectively, and crystal structures of Sco GlgE-V279S-5 and Sco GlgE-V279S-6 were obtained at a 3.2 ? and 2.5 ? resolution, respectively.

Joint production method of ethephon and vinylphosphonic acid

The invention discloses a joint production method of ethephon and vinylphosphonic acid. The joint production method comprises the following steps of acylating bis(2-chloroethyl)-2-chloroethyl phosphonate by phosgene or thionyl chloride under the action of a catalyst to obtain a mixture of vinyl phosphonic chloride and 2-chloroethyl phosphonic chloride; separating the vinyl phosphonic chloride from the 2-chloroethyl phosphonic chloride in a reduced pressure distillation mode; hydrolyzing the vinyl phosphonic chloride and the 2-chloroethyl phosphonic chloride to obtain the vinylphosphonic acid and the ethephon. According to the joint production method disclosed by the invention, two products of the ethephon and the vinylphosphonic acid are synthesized by using the bis(2-chloroethyl)-2-chloroethyl phosphonate; a process is simple, and the purities of the two products are improved.

Microwave synthesis of vinylphosphonic acid and its derivatives

Microwave Pyrolysis of β-substituted ethylphosphonic acid derivatives was studied. The resulting mixture of vinylphosphonic acid derivatives is similar to that obtained by convective heating.

Highly selective markovnikov addition of hypervalent H-spirophosphoranes to alkynes mediated by palladium acetate: Generality and mechanism

Palladium acetate efficiently catalyzes the addition of an H-spirophosphorane (pinacolato)2PH to alkynes to give Markovnikov addition products highlyselectively. The addition products can be easily converted to the corresponding alkenylphosphonates and phosphonicacids viasimple hydrolysis or thermal decomposition. This new reaction isa general method for the introduction of phosphorus functionality to the internal carbons of terminal alkynes, resolving the problem of the regioselectivity associated with hydrophosphorylation reactions so far reported. Mechanistic studies confirmed that (a) palladium acetate was reduced to metallic palladium by H-spirophosphorane, (b) the P-H bond of H-spirophosphorane could be activated by zero-valent platinum complexes to give the corresponding hydridoplatinum complexes, and (c) an alkenylpalladium species was identified from the reaction of palladium acetate with H- spirophosphorane and diphenylacetylene. These results support a reaction mechanism that palladium acetate was first reduced by H-spirophosphorane to give zero-valent palladium. This zero-valent palladium might insert into the P-H bond of the H-spirophosphorane to give a hydridopalladium species which then added to alkyne via the addition of H-Pd bond to form an alkenylpalladium species with the hydrogen atom added to the terminal carbon of alkynes. Reductive elimination of the alkenylpalladium affords the addition product.

Process for production of vinylphosphonic acids and silyl esters thereof

A process for preparing vinylphosphonic acid compounds and silyl esters thereof in which a bis(haloalkyl) vinylphosphonate is reacted with an organosilyl halide to produce a silyl ester which can then be converted to the acid by reaction with a proton donor.

Dealkylation of phosphonate esters with chlorotrimethylsilane

Chlorotrimethylsilane completely dealkylates phosphonate esters at elevated temperature in a sealed reaction vessel. These conditions are tolerated by a variety of functional groups and lead to high conversions of dimethyl, diethyl and diisopropyl phosphonates to their corresponding phosphonic acids.

Reactions of phosphonates with organohaloboranes: New route to molecular borophosphonates

Phosphonates RPO(OR′)2 (R = Me, R′ = Et (1); R = CH2Ph, R′ = Et (2); R = CH double bond CH2, R′ = Et (3); R = CH2-CH double bond CH2, R′ = Me (4); R = CH2N3, R′ = Et (5)) react with CyBCl2 (6; Cy = C6H11) in a 1:1 molar ratio in toluene at -30 °C to form the primary adducts CyBCl2·O double bond PR(OR′)2 (7-11). These products undergo a thermally induced bis-chlorodealkylation with the formation of mixtures of oligomers [-O-PR(O-)-O-BCy(O-)]n (22-26) having isovalent P-O-B groupings. Under electron impact mass spectral conditions, the ions [RPO3BCy]4-Cy, which may be attributed to tetramers [RPO3BCy]4 (22′-26′), are detected. Compounds 22′-26′ presumably possess a central cubic M4O12P4 framework that is analogous to those found in alumino- and gallophosphate materials. NMR monitoring shows that [CyBCl(μ2-O)2PR(OR′)]2 (12-16) are formed as intermediates in these reactions. These unstable dimers 12-16 possess a cyclic core analogous to the single-four-ring (4R) secondary building units (SBUs) found in zeolites and phosphate molecular sieves. Hydrolysis of 12-16 and 22-26 with methanol at 30 °C gave respectively RPO(OH)(OR′) (17-21) and RPO(OH)2 (27-31). NMR monitoring reveals that the cyclic dimer [Me2B(μ2-O)2P(CH2Ph)(OEt)]2 (35a) is the primary adduct in the reaction of PhCH2PO(OEt)2 (2) with Me2BBr (34). Heating or prolonged storage at room temperature leads to a mixture of 35a, cyclic borophosphonate Me2BC(μ2-O)2P(CH2Ph)(OEt) (35b), and the mixed anhydride of benzylphosphonic acid and dimethylborinic acid (35c).

MECHANISM OF THE PHOSPHORYLATION REACTION OF 2-HALOALKYLPHOSPHONIC ACIDS

2-Haloalkylphosphonic acids require aqueous solutions of suitable pH to react as phosphorylating agents.Reaction rates are slow at pH1, moderate at pK12 (monoanion) and fast at pH>pK2 (dianion).The end products in water are phosphoric acid (major) and 2-hydroxyalkyl- and vinylphosphonic acids (minor).The dianinon is stable in non-aqueous solutions.The order of reactivity is bromo>chloro>>fluoro.Dehydrohalogenation is the major patway with mono- and diesters.In contrast, 2-chloroethylphosphonothioic acid dianion is stable even at pH 13.These findings are consistent with a mechanism involving a bimolecular process rather than an SN1 pathway via a metaphosphate intermediate.