6922-89-0

Usage

Uses

Used in Pharmaceutical Industry:
(4-chlorophenyl)(diphenyl)methanol is used as a key intermediate in the synthesis of various pharmaceuticals, contributing to the development of new drugs and medicines. Its unique structure allows for the creation of a wide range of therapeutic agents.
Used in Agrochemical Industry:
In the agrochemical sector, (4-chlorophenyl)(diphenyl)methanol is employed as a precursor in the production of agrochemicals, which are essential for enhancing crop protection and yield.
Used in Fine Chemicals Production:
(4-chlorophenyl)(diphenyl)methanol is utilized as a building block in the synthesis of fine chemicals, which are high-purity chemicals used in various applications, including fragrances, dyes, and other specialty products.
Used in Antimicrobial Applications:
(4-chlorophenyl)(diphenyl)methanol has been studied for its potential as an antimicrobial agent, indicating its use in applications where the control of microbial growth is necessary, such as in medical and industrial settings.
Used in Polymer and Plastics Industry:
As an intermediate in the production of polymers and plastics, (4-chlorophenyl)(diphenyl)methanol plays a role in the development of new materials with specific properties tailored for various applications.
It is important to handle (4-chlorophenyl)(diphenyl)methanol with care due to its potential harmful effects if ingested, inhaled, or absorbed through the skin, ensuring safety in its applications across different industries.

Upstream product

• 119-61-9 benzophenone 
• 7270-47-5 4-chlorophenylmagnesium iodide 
• 64-17-5 ethanol 
• 7335-27-5 ethyl 4-chlorobenzoate 
• 27023-37-6 4-chlorotrityl chloride 
• 134-85-0 4-chlorobenzophenone 
• 106-39-8 bromochlorobenzene 
• 38994-76-2 p-Chlorphenyl-diphenylmethyliumion 
• 7664-93-9 sulfuric acid 
• 98-88-4 benzoyl chloride 
• 108-90-7 chlorobenzene 
• 5216-25-1 4-chlorotrichloromethylbenzene 
• 71-43-2 benzene 

Downstream Products

• 856204-48-3 4-chloro-trityl bromide 
• 69361-54-2 ((4-chlorophenyl)methylene)dibenzene 
• 13189-73-6 4-chloro-trityl azide 
• 27023-37-6 4-chlorotrityl chloride 
• 13561-39-2 N--benzolsulfonamid 
• 27446-90-8 NSC123138 
• 137003-26-0 4-chlorotriphenylacetonitrile oxide 
• 82361-63-5 di-p-biphenylylphenylmethane 
• 119-61-9 benzophenone 
• 134-85-0 4-chlorobenzophenone 
• 23593-71-7 CDD3532 

Relevant academic research and scientific papers

Triaryl methane derivatives as antiproliferative agents

Clotrimazole (CLT) 1, a synthetic anti-fungal imidazole derivative, inhibits tumor cell proliferation and angiogenesis. In the current study, flow cytometric analysis demonstrated that the decrease in tumor cell growth by CLT 1 was associated with inhibition of cell cycle progression at the G 1-S phase transition, resulting in G0-G1 arrest. A series of CLT 1 analogues has been generated in order to develop CLT 1 derivatives that are devoid of the imidazole moiety which is responsible for the hepatoxicity associated with CLT 1 while retaining CLT 1 efficacy. The majority of these analogues demonstrate in vitro antiproliferative activity ranging from submicromolar to micromolar concentrations.

Tritylamino aromatic heterocycles and related carbinols as blockers of Ca2+-activated potassium ion channels underlying neuronal hyperpolarization

A series of novel aromatic tritylamino heterocycles has been synthesized and the compounds have been tested in comparison with clotrimazole for their ability to inhibit the slow afterhyperpolarization current (SlAHP) in cultured rat hippocampal pyramidal neurones. Some analogues of the clotrimazole metabolite, 2-chlorophenyl-diphenyl methanol, having different chlorination substitution in the triphenyl group have also been examined. Two compounds in particular, 3-[(2-chlorophenyl)diphenylmethylamino]pyridine (3a, UCL 1880) and 2-tritylaminothiazole (6, UCL 2027), are of special interest; they are effective blockers of the SlAHP (IC50 = 1.1-1.2 μM) and are much more selective than clotrimazole since they have less effect on the high voltage-activated Ca2+ current.

Reactivities of triarylmethyl and diarylmethyl cations with azide ion investigated by laser flash photolysis. Diffusion-controlled reactions

By use of the technique of laser flash photolysis, rate constants kAz and ks have been directly measured for the reactions at 20 °C in acetonitrile-water (AN-W) solutions of varying composition of 18 triarylmethyl and 10 diarylmethyl cations with azide and solvent. The cations have ks that depend on substituent and vary from ～101 to ～107 s-1. For the more stable ions kAz also varies, increasing with decreased electron donation and also increasing by as much as 103 with increasing acetonitrile content. For less stable cations, however, the rate constant becomes independent of substituent. The break occurs when ks has reached ～105 s-1. The limiting rate constants have magnitudes in the vicinity of 1010 M-1 s-1; these do depend on solvent and type of cation, with diarylmethyl cations reacting at the limit 1.6 ± 0.2 times faster than triarylmethyl. The data can be fit by a model where there is diffusional encounter of the cation and azide to form an ion pair, with the combination within the ion pair rate-limiting for the more stable cations and the diffusion step rate-limiting for the less stable ones. The limiting rate constants represent the latter, diffusional encounter of the cation and azide. The Debye-Smoluchowski equation for diffusion-controlled reactions predicts rate constants that are larger than observed by factors of 2-2.5 for diarylmethyl and 4 for triarylmethyl. Deviations can be attributed to nonproductive encounters where the anion has approached the cation in the plane of one of the rings and thus cannot form a proper reacting configuration. The difference between the two types of cations is explained by the greater difficulty of achieving this configuration with the more sterically congested triarylmethyl cation. Ratios kAz/ks obtained from product analysis (competition kinetics) have previously been found to show adherence to the reactivity-selectivity principle. This has been interpreted (Rappoport, Jencks) in terms of the reaction with azide having reached the diffusion limit. The directly measured kAz establish that this is indeed the case. This study also validates the use of azide as a "clock" (Jencks, Richard) for converting such ratios to absolute rate constants through use of a value of 5 × 109 M-1 s-1 for kAz. The directly measured diffusion-limited kAz are somewhat larger than this, but the differences are small, at most a factor of 4.

A Kinetic Study of the Rearrangement of Triarylacetonitrile Oxides

The thermal rearrangement of triphenylacetonitrile oxide (1a) to triphenylmethyl isocyanate (2) is a first-order process.Rate constants at five temperatures between 116 and 190 deg C were determined giving ΔH(excit.) = 9.3 +/- 1.1 kcal/mol and ΔS(excit.) = -58.2 +/- 2.4 cal/mol*K.The rearrangement of substituted triarylacetonitrile oxides (1b-d) occur only slightly faster than that of 1a.These results are interpreted in terms of a concerted single-step rearrangement in which the highly ordered transition state (6c) has a degree of radical character.