705-83-9

Usage

Uses

Used in Organic Synthesis:
3-(3-fluorophenyl)propiolic acid is used as a building block in organic synthesis for the creation of various complex organic molecules. Its ability to undergo nucleophilic addition and substitution reactions makes it a versatile component in the synthesis of new compounds.
Used in Pharmaceutical Development:
In the Pharmaceutical Industry, 3-(3-fluorophenyl)propiolic acid is used as a key intermediate in the development of new drugs. Its unique chemical structure and properties contribute to the design and synthesis of potential therapeutic agents, particularly in medicinal chemistry and drug discovery.
Used in Material Science:
3-(3-fluorophenyl)propiolic acid may also find applications in the field of material science. The specific reactivity and properties conferred by the fluorine atom in the phenyl ring can be harnessed to develop new materials with tailored characteristics for various applications.

Upstream product

• 221148-38-5 methyl 3-(3-fluorophenyl)prop-2-ynoate 
• 1121-86-4 1-Fluoro-3-iodobenzene 
• 471-25-0 Propiolic acid 
• 124-38-9 carbon dioxide 
• 2561-17-3 1-ethynyl-3-fluoro-benzene 

Downstream Products

• 52112-24-0 1-fluoro-3-(prop-1-yn-1-yl)benzene 
• 1174916-26-7 diethyl ((3-fluorophenyl)ethynyl)phosphonate 
• 1431960-65-4 C₁₆H₁₉FN₂O₃ 
• 406687-60-3 {[3-(3-fluoro-phenyl)-propynoyl]-methyl-amino}-acetic acid ethyl ester 

Relevant academic research and scientific papers

N-Heterocyclic carbene-nitrogen molybdenum catalysts for utilization of CO2

Three new N-heterocyclic carbene-nitrogen molybdenum complex was synthesized, and its catalytic activity was evaluated in the cycloaddition of epoxides with CO2. The molybdenum complex combined with tetrabutyl ammonium iodide (TBAI) resulted in a catalytic system for efficient conversion of a wide range of terminal and internal epoxides under 80 °C and 5–7 bar pressure for CO2. The cooperative catalysis mechanism between molybdenum complex and TBAI was elucidated, in which molybdenum complex was used as Lewis acid, and TBAI was employed as nucleophilic reagent. In addition, the NHC-Mo catalytic system was also successfully applied for the direct carboxylation of terminal alkynes with CO2.

Organocatalytic Strategy for the Fixation of CO2via Carboxylation of Terminal Alkynes

An organocatalytic strategy for the direct carboxylation of terminal alkynes with CO2 has been developed. The combined use of a bifunctional organocatalyst and Cs2CO3 resulted in a robust catalytic system for the preparation of a range of propiolic acid derivatives in high yields with broad substrate scope using CO2 at atmospheric pressure under mild temperatures (60 °C). This work has demonstrated that this organocatalytic method offers a competitive alternative to metal catalysis for the carboxylation of terminal alkynes and CO2. In addition, this protocol was suitable for the three-component carboxylation of terminal alkynes, alkyl halides, and CO2.

Microwave-assisted fabrication of a mixed-ligand [Cu4(μ3-OH)2]-cluster-based metal–organic framework with coordinatively unsaturated metal sites for carboxylation of terminal alkynes with carbon dioxide

The development of efficient and stable metal–organic framework (MOF) catalysts with coordinatively unsaturated metal sites for modern organic synthesis is greatly important. Herein, a robust [Cu4(μ3-OH)2]-cluster-based MOF (Cu-MOF) with a mixed-ligand system was successfully fabricated by a microwave-assisted method under mild conditions. The as-prepared Cu-MOF catalyst possessing unsaturated Cu (II) sites exhibited excellent catalytic activity toward the direct carboxylation of 1-ethynylbenzene with CO2, and various propiolic acid derivatives were synthesized in moderate to good yields under optimized reaction conditions. Furthermore, the catalyst remained stable and could be easily recycled for five sequential runs without incredible decrease in catalytic efficiency.

Oxidant- and additive-free simple synthesis of 1,1,2-triiodostyrenes by one-pot decaroboxylative iodination of propiolic acids

A metal- and oxidant-free facile synthesis of a range of 1,1,2-triiodostryrene derivatives has been developed which utilizes a simple decarboxylative triiodination of propiolic acids using molecular iodine and sodium acetate in a one-pot manner. Electron-

Visible light induced 3-position-selective addition of arylpropiolic acids with ethersviaC(sp3)-H functionalization

Although the 2-position-selective decarboxylative coupling or addition of arylpropiolic acids with cyclic ethers has been intensively investigated, selective functionalization of arylpropiolic acids at the 3-position is still a big challenge. Herein, an i

Rhodium(III)-catalysed cascade [3 + 2] annulation of: N -aryloxyacetamides with 3-(hetero)arylpropiolic acids: Synthesis of benzofuran-2(3 H)-ones

Herein, a cascade [3 + 2] annulation of N-aryloxyacetamides with 3-(hetero)arylpropiolic acids affording benzofuran-2(3H)-ones via rhodium(iii)-catalyzed redox-neutral C-H functionalization/isomerization/lactonization using an internal oxidative directing group O-NHAc was achieved. This catalytic system provides a regio- and stereoselective approach to synthesize (Z)-3-(amino(aryl)methylene)benzofuran-2(3H)-ones with exclusive Z configuration selectivity, acceptable yields and good functional group tolerance. Preliminary investigations on ultraviolet-visible and fluorescence behaviors reveal that the annulation products may be applied as a promising fluorescent probe for sensing metal cations, especially for cerium (Ce3+).

Carboxylation of terminal alkynes promoted by silver carbamate at ambient pressure

Transition metal carbamates constitute a class of compounds with unique properties, however their catalytic potential has been sparingly explored so far. The easily available silver N,N-dimethylcarbamate, Ag(O2CNMe2), worked as a catalyst in the carboxylation reaction of terminal alkynes with CO2 at atmospheric pressure. Different reaction parameters (solvent, base, temperature, time and the amount of catalyst) were investigated in order to establish the optimal conditions.

Method for preparing propiolic acid and derivatives thereof under mild condition

The invention provides a novel method for preparing propiolic acid compounds through a domino reaction. The method comprises a step of subjecting terminal alkyne compounds, hydrosilane and CO2 to thedomino reaction under the catalysis action of Lewis base so as to obtain propiolic acid compounds. According to the invention, common Lewis base is used as a promoter, and corresponding propiolic acidcompounds containing different function groups can be efficiently produced through a reaction of the terminal alkyne compounds with hydrosilane and normal-pressure CO2 under a mild condition (a temperature of 40 DEG D). According to the method, CO2 is used as a raw material; the cheap Lewis base is used as the promoter; usage of precious metals is avoided; the domino reaction is employed; purification and separation of intermediates are not needed; and reaction conditions are mild. Thus, the method is an efficient cheap green synthetic method and has good industrial application value.

3 - Aryl methylacetylene acid and 3 - aryl methylacetylene ester preparation method of compound (by machine translation)

The invention relates to a 3 - aryl methylacetylene acid compound preparation method: formula (I) shown phenylacetylene compound with carbon dioxide under the action of alkali, in solvent dimethyl sulfoxide in 40 - 70 °C under reaction, as shown in formula (II) of the 3 - aryl methylacetylene acid compounds, more than normal pressure of the body reaction in water-free, oxygen-free inert atmosphere, the reaction route is as follows: Wherein R1 Selected from hydrogen, alkyl, alkoxy, phenyl, nitro or halogen. The invention further provides a 3 - aryl methylacetylene ester preparation method of compound: adopting the above-mentioned method of the formula (II) is shown in the 3 - aryl methylacetylene acid compound, then adding the halogenated hydrocarbon or tosylates, after the in-situ reaction of the formula (III) is shown in the 3 - aryl methylacetylene ester compound: Wherein R2 Is selected from alkyl, benzyl or allyl. The method of the invention does not need to transition metal or rare earth metal catalyst, normal pressure reaction, mild condition, pervasive good substrate. (by machine translation)

Sequential protocol for C(sp)–H carboxylation with CO2: KOtBu-catalyzed C(sp)–H silylation and KOtBu-mediated carboxylation

CO2 incorporation into C–H bonds is an important and interesting topic. Herein a sequential protocol for C(sp)–H carboxylation by employing a metal-free C–H activation/catalytic silylation reaction in conjunction with KOtBu-mediated carboxylation with CO2 was established, in which KOtBu catalyzes silylation of terminal alkynes to form alkynylsilanes at low temperature, and simultaneously mediates carboxylation of the alkynesilanes with atmospheric CO2. Importantly, the carboxylation further promotes the silylation, which makes the whole reaction proceed very rapidly. Moreover, this methodology is simple and scalable, which is characterized by short reaction time, wide substrate scope, excellent functional-group tolerance and mild reaction conditions, affording a range of corresponding propiolic acid products in excellent yields in most cases. In addition, it also allows for a convenient 13C-labeling through the use of 13CO2.