Interesting facts
Interesting Facts About Diphenylphosphorylbenzene
Diphenylphosphorylbenzene is a fascinating compound with a unique structure and important applications in the field of chemistry. Here are some interesting aspects to consider:
- Structural Significance: This compound consists of a central phosphorus atom bonded to two phenyl groups and one oxygen atom. Its structure facilitates various interactions in chemical reactions, particularly in organic synthesis.
- Reagent in Synthesis: Diphenylphosphorylbenzene is valued as a reagent in synthetic organic chemistry. It is often utilized in the formation of phosphine oxide derivatives, which are critical intermediates in pharmaceuticals and agrochemicals.
- Catalytic Properties: The presence of the phosphoryl group makes this compound a useful catalyst in various reactions, enhancing reaction rates and selectivity.
- Versatile Applications: Beyond catalysis, it plays a role in materials science, especially in the development of polymers and other advanced materials.
- Research Interest: Researchers are actively exploring the use of diphenylphosphorylbenzene in more efficient pathways for drug synthesis, showcasing its potential for innovation in medicinal chemistry.
As one delves into the properties and reactions involving diphenylphosphorylbenzene, it becomes clear that this compound serves not only as a building block but also as a critical player in advancing chemical research and industrial applications. It exemplifies how simple molecular modifications can lead to vastly different functionalities.
In the words of a seasoned chemist, "The beauty of organic synthesis lies in the subtlety of the molecular dance, where each bond formed or broken can lead to a new frontier of possibilities."
Synonyms
TRIPHENYLPHOSPHINE OXIDE
791-28-6
Phosphine oxide, triphenyl-
triphenylphosphane oxide
Triphenylphosphineoxide
NSC 398
EINECS 212-338-8
UNII-Z69161FKI3
phosphorane, triphenyl-, oxide
DTXSID2022121
CHEBI:36601
triphenylphisphine oxide
NSC-398
TRIPHENYLPHOSPHINE MONOXIDE
Z69161FKI3
DTXCID402121
ALPROSTADIL IMPURITY K [EP IMPURITY]
triphenyl-lambda(5)-phosphanone
(C6H5)3PO
EC 212-338-8
(C6H5)3P=O
ALPROSTADIL IMPURITY K (EP IMPURITY)
Phosphine oxide, triphenyl
212-338-8
fiqmhbfvraxmop-uhfffaoysa-n
inchi=1/c18h15op/c19-20(16-10-4-1-5-11-16,17-12-6-2-7-13-17)18-14-8-3-9-15-18/h1-15
Triphenyl phosphine oxide
Triphenyl phosphorus oxide
diphenylphosphorylbenzene
(diphenylphosphoroso)benzene
TPPO
MFCD00002080
Triphenylphosphanoxid
Triphenylphosphanoxide
PH3PO
Triphenylphosphine oxide; Triphenyl phosphine oxide; Orlistat Related Compound C; Alprostadil Impurity K
triphenylphosphinoxide
triphenylphospine oxide
triphenyphosphine oxide
POPh3
triphenylphosphine-oxide
tri-phenylphosphine oxide
triphenyl-phosphine oxide
diphenyl-phosphoryl-benzene
SCHEMBL3949
Triphenylphosphine oxide, 98%
CHEMBL482091
NSC398
SCHEMBL1835805
BCP19260
CS-Z0018
Tox21_302054
STK123697
AKOS000494984
NCGC00255292-01
AC-19038
BP-20684
CAS-791-28-6
DB-009890
NS00010696
T0625
Triphenylphosphine oxide, analytical standard
D70900
EN300-134404
Q421154
Z56757699
F3145-4424
Solubility of Diphenylphosphorylbenzene
Diphenylphosphorylbenzene, with the chemical formula C13H11O
2
P, exhibits unique solubility properties that are influenced by its molecular structure. Understanding its solubility behavior is crucial for various applications in both laboratory settings and industrial processes. Here are some key points regarding its solubility:In summary, the solubility of diphenylphosphorylbenzene is predominantly seen in nonpolar environments, with minimal interaction in polar solvents such as water. Understanding these solubility parameters is essential for maximizing its potential in various chemical applications.