Author: tianli

In organic chemistry, atoms other than carbon and hydrogen are generally referred to as heteroatoms. The most common heteroatoms are nitrogen, oxygen and sulfur. Now I present to you an article called o-Halogenated p-nitroaniline and its derivatives, published in 1914, which mentions a compound: 16588-26-4, mainly applied to , HPLC of Formula: 16588-26-4.

When p-NO2C6H4NH2 is dissolved or suspended in HCl and Cl or Br added a mixture, difficult to sep., of mono- and dihalogenated anilines with the halogen in the o-position is formed. If, however, gaseous Cl (mol. ratio 1 : 1) is passed into the b. HCl solution 2,4-Cl(O2N)C6H3NH2 is almost the sole product. This derivative mixed with some di-Cl derivative is obtained on chlorinating at -o°(Casella & Co., Ger. Pat., 109,189). At room temperature, on adding Cl slowly to the HCl solution, the di-Cl deriv, + quinone are formed. Chlorinating by Noelting’s method, using Ca(ClO)2, gave mixtures Similar results were obtained with Br. These derivatives are obtained by warming 1-nitro-3,4-dibromo (or dichloro) benzene with alc. NH3 in the scaled tube at 190°. The NH2 group substitutes p to NO2. By halogenating these monohalogen derivatives it is possible to get derivatives with 2 different halogens in the same ring. The action of ClI on a glac. AcOH solution of p-NO2C6H4NH2 gives mixtures from which the mono- and di-I derivatives can be separated by EtOH. 1-Nitro-3-chloro-4-aniline, bright yellow needles from hot H2O, m. 104.5°; acetyl derivative, straw-yellow flat prisms from EtOH, m. 139°. Diazotizing in H2SO4 or HNO3 suspension with gaseous HNO2 gives the diazo compound which, by way of the perbromide, goes into 1-nitro-3-chloro-4-bromobenzene, prisms from CHCl2, m. 62°. 1-Nitro-3-chloro-4-iodobenzene, almost colorless needles from EtOH, m. 103°, is obtained similarly, by way of the periodide. 1-Nitro-3-bromo-4-aniline, bright yellow needles, m. 104.5°, which with Ac2O gives the monoacetyl derivative, flat prisms, m. 114°, and the diacetyl derivative, short fat prisms, m. 132°. also from the mono derivative, by the action of Ac2O + traces of POCl3. Diazotizing and halogenating as above gives 1-nitro-3-bromo-4-chlorobenzene, white or colorless prisms, volatil with steam, m. 61°, is identical with the compound similarly obtained from 2,5-Cl(O2N)C6H3NH2. 1-Nitro-3-bromo-4-iodobenzene, prisms from AcOEt, m. 106°, was obtained similarly. 1-Nitro-3-iodo-4-aniline presents 2 forms: (1) stable yellow-red prisms, and (2) the labile forms golden yellow plates in C6H6, below 17°, m. 109°; monoacetyl derivative, bright yellow prisms; diacetyl derivative, more soluble than the mono compound, white needles. The diazo compound, on adding Cl, gives 1-nitro-3-iodo-4-chlorobenzene, needles, m. 78°, identical with the compound obtained similarly with I from 2,5-Cl(O2N)C6H2NH2. 1-Nitro-3,5-dichloro-4-aniline, yellow shining needles, m. 195°, slightly soluble in dilute and concentrate inorganic acids, unchanged by fuming HNO3 in the cold. To diazotize suspend in HNO3 (d. 1.38) and add gaseous HNO2 at o°; on diluting the explosive diazonium nitrate seps., fairly soluble in H2O. Ac2O + traces of POCl3 give the monoacetyl derivative, almost colorless needles, m. 215°, and the diacetyl derivative, monoclinic (Artini, Rend. ist. lombardo sci. lett., [2] 45, 1912), prisms, m. 142.5°, d. 1.565, more soluble than the mono compound In absolute EtOH + some concentrate H2SO4 + EtONO it gives 1-nitro-3,5-dichlorobenzene, plates, m. 65.4°, which on reducing with Sn + HCl gives 3,5-dichloroaniline, needles, m. 51.5°. The latter, by replacing NH3 with Cl, gives 1,3,4-trichlorobenzene, white needles, to. 63.5°, which is also obtained from 2,4,6-Cl3C8H2NH2, m. 77.5°, by replacing NH3, with H. 3,5-Cl2C4H3NH2 by replacing NH2 with Br gave 1-bromo-3,5-dichlorobenzene, needles, m. 75.8°. 1-Iodo-3,5-dichlorobenzene, m. 54°, was obtained similarly and is identical with that prepared similarly from 2,4,6-ICl2C6H2NH2, m. 84°. Anilines containing 3 identical halogen ats. in the 2,4,6-positions may be obtained by direct halogenation of PhNH2 of which they are the end products. The mixed halogenated anilines are made from anilines halogenated in p-position by adding two halogens (Br or ClI) in the o-position in glac. AcOH. o,p- or o,o-dihalogenanilines may even be used, but displacing of weak halogens may take place. All of the theoretically possible trihalogenbenzenes can be obtained by thus substituting halogen for NH2 in anilines. 2,6,4-Cl2(O2N)C6H2NH2 gives 1-nitro-3,4,5-trichlorobenzene, bright yellow prisms, m. 72.5°, volatil with steam; reduction and elimination of NH2 gives 1,2,3-C6H2Cl3, identical with that from 2,6-Cl2C6H3NH2 by the same method. 1-Nitro-3,5-dichloro-4-bromobenzene, from the above aniline, yellow. prisms, m. 88°, volatile with steam; similarly 1-nitro-3,5-dichloro-4-iodobenzene, yellow prisms, m. 154.8°, less volatile; reduction, etc., gives 1,3-dichloro-2-iodobenzene, thin plates, m. 68°, volatile with steam, also from 3,6-C;2C4H3NH2 with I. p-NO3 C4H4NH2 + Br gives 1-nitro-3,5-dibromo-4-aniline, yellow plates, m. 202.5°; Ac2O as above gives the monoacetyl derivative, colorless needles or triclinic prisms, isomorphous with the di-Cl compound, and the diacetyl derivative, prisms, m. 136°, triclinic pinacoidal, a : b : c = 1.0901 : 1 : 0.8325, a = 88° 43′ 4”. β = 70° 49′ 34”. γ = 93° 25′ 39”, d. 1.939.3 Diazotizing the above or 2,4.6-Br2(O2N)C5H2NH3 with EtONO, etc., gives 1-nitro-3,5-dibromobenzene, almost colorless needles, m. 104.5°; on reduction with Sn + HCl, etc., it gives sym.-dibromochlorobenzene, m. 119°, with Cl, or dibromoiodobenzene, m. 124.8°, with 1. Both are easily volatil with steam and may be prepared from the corresponding anilines and the latter also from 2,4,6-IBr2C6H2NH2. 1-Nitro-3,4,5-tribromobenzene, from the o,o-dibromoaniline by replacing NH3 with Br, yellowish prisms, m. 111.9° on reduction, etc., gives 1,2,3-C6H3Br3, m. 87.8°. 1-Nitro-3,5-dibromo-4-chlorobenzene from the same aniline, yellowish prisms, m. 92-7°, on reduction, etc., gives 2,6-Br2C6H3Cl, m. 71°, identical with the compound similarly obtained from 2,6-Br2C6H3NH2 by replacing NH2 with Cl. 1-Nitro-3,5-dibromo-4-iodobenzene, from 2,6,4-Br2(O2N)C6H2NH2, prisms, 135.5°, cannot be reduced to the aniline. The 2,6-Br2C6H2I was obtained from 2,6-Br2C6H3NH2, prisms, m. 72°. 1-Nitro-3,5-diiodo-4-aniline, from p-NO2C6H4NH2 + ClI in AcOH, yellow needles; m. 245°; monoacetyl derivative, yellow needles, m. 249°; diacetyl derivative, paler yellow prisms, m. 171°, triclinic pinacoidal, a : b : c = 0.9682 : 1 : O.7260, α = 83° 6’43”, β = 76°8’29”, γ = 99° 42′ 44”, d. 2.290. 1-Nitro-3,5-diiodobenzene, from the preceding, difficultly volatile with steam, yellowish prisms, m. 104.5°, on reducing with FeSO4 + NH3 gives 3,5-I2C6H2NH3, needles, m. 110°. 2,6,4-I2ClC6H2NH2 gave 1,3-diiodo-5-chlorobenzene, needles, m. 101°, discolors brown in the light. Similarly the 5-bromoaniline gave 1,3-diiodo-5-bromobenzene, m. 140°, slightly volatile with steam. 1,3,5-Triiodobenzene, from 2,4,6-I2C6H2NH2 or 3.5-I2C6H3NH2, opaque needle, m. 184.2°. Decompose of 2,6,4-I2(O2N)C6H2N2NO3 with b. aqueous Cu2Cl2 gave 1-nitro-3,5-diiodo-4-chlorobenzene, needles, m. 110°; reduction with FeSO4 + NH3 gives a poor yield, (NH4)2S gives a better yield of the aniline together with some S-containing compound The aniline gives 2,6-I2C6H3Cl, rhombic plates, m. 82°. 2,6,4-I2(O2N)(C6H2NH2 gives 1-nitro-3,5-diiodo-4-bromobenzene, white needles from EtOH, yellow prisms from CHCl3 m. 125.4°, and 1-nitro-3,4,5-triiodobenzene, yellow prisms from EtOH, contain C6H6 of crystallization when crystallized from C6H6; reduction with FeSO4 + NH3 gives 3,4,5-triiodoaniline with difficulty; (NH4)2S gives sym.-I2C6H2NH2. The I2C6H2NH2 gives 1,2,3-C6H2I2 on changing NH2 for H, m. 116°, which is identical with that from 2,3-I2C6H3NH2. 2,4-Cl(O2N)C6H3NH2 + Br gives 1-nitro-3-chloro-5-bromo-4-aniline, bright Yellow needles, m. 177.4°; monoacetyl derivative, straw-yellow needles, m. 224°; diacetyl derivative, prisms or plates, m. 139°, monoclinic, prismatic, a : b : c = 1.1127 : 1 : 0.8509, β = 70-36°, d. 1-749. 1-Nitro-3-chloro-5-bromobenzene, from the above aniline, plates, m. 81.2°. and this on reducing with Sn + HCl, etc., gives 3-chloro-5-bromoaniline, needles, or prisms. The latter, as well as 2,4,6-BrClIC6H2NH2, m. 110.5°, gives 1-chloro-3-bromo-5-iodobenzene, needles, m. 85.8°. 1-Nitro-3,4-dichloro-5-bromobenzene, yellowish prisms, m. 82.5°, 1-Nitro-3,4-dibromo-5-chlorobenzene, yellowish prisms, m. 99.5°, and 1-nitro-3-chloro-4-iodo-5 bromobenzene, needles, 159°, by replacing NH2 with a halogen in the preceding nitroaniline. 1,2-Dibromo-3-chlorobenzene, by reducing 3,4,5-Br2ClC6H2NO2, rhombic plates. m. 72.6°. 2,4-Cl(O2N)C6H2NH22, in HOAc + ClI gives 1-nitro-3-chloro-5-iodo-4-aniline, bright yellow needles, 195°; monoacetyl derivative, white prisms, m. 207°; diacetyl derivative, prisms, m. 113°, monoclinic, a : b : c = 1.038 :-1 : 0.799, β = 71.44°, d. 1.913. This aniline gives 1-nitro-3-chloro-5-iodobenzene, yellow prisms, m. 70.4° by replacing NH2 with Cl. 1-Nitro-3,4-dichloro-5-iodobenzene, from the aniline with Cl, bright yellow prisms, m. 59°, is not easily reduced by FeSO4 + NH3, but Sn + HCl gives 3,5-CHC6H3NH2, plates, m. 69.8°; with Br the aniline gives 1-nitro-3-chloro-4-bromo-5-iodobenzene, almost colorless needles, m. 95°; and with I it gives 1-nitro-3-chloro-4,5-diiodobenzene, almost colorless needles, m. 146.5°. 3,4,5-Cl2IC6H2NO2 + (NH4)2S in EtOH gives 3,4-Cl2C6H3NH2. 2,4-Br(O2N)C6H3NH2 + CH in HOAc gives 1-nitro-3-bromo-5-iodo-4-aniline, needles, m. 221°; monoacetyl derivative, yellowish prisms, m. 226°; diacetyl derivative, prisms, m. 134°, triclinic pinacoidal, a : b : C = 0.9470 : 1 : 0.7288, α = 83° 59′ 54”, β = 77° 30′ 18”, γ = 99° 6′ 14”, d.2.112. 1-Nitro-3-bromo-5-iodobenzene, by replacing NH2 with H in the preceding aniline, needles, m. 97.5°; 1-nitro-3-bromo-4-chloro-5-iodobenzene, by replacing NH2 with Cl, yellowish prisms or colorless needles, m. 84°.

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Reference:
Alcohol – Wikipedia,
Alcohols – Chemistry LibreTexts

Epoxy compounds usually have stronger nucleophilic ability, because the alkyl group on the oxygen atom makes the bond angle smaller, which makes the lone pair of electrons react more dissimilarly with the electron-deficient system. Compound: Dichloro(1,5-cyclooctadiene)platinum(II), is researched, Molecular C8H12Cl2Pt, CAS is 12080-32-9, about Photocytotoxic Pt(IV) complexes as prospective anticancer agents.COA of Formula: C8H12Cl2Pt.

The use of Pt(IV) complexes as potential anticancer drugs is attractive, because they have higher stability and less side effects than Pt(II) compounds Moreover, some Pt(IV) complexes can also be activated with light, opening an avenue to photochemotherapy. Our purpose is to widen the library of photoactivatable Pt(II)-based prodrugs and here we report on the oxidation of the Pt(II) compound [PtCl(4′-phenyl-2,2′:6′,2”-terpyridine)][CF3SO3] (1) with PhICl2 or H2O2. The synthetic procedure avoids the formation of multiple species: the treatment with PhICl2 produces the Pt(IV) complex with axial chlorides, [PtCl3(4′-phenyl-2,2′:6′,2”-terpyridine)][CF3SO3] (2), while H2O2 oxidation and post-synthesis carboxylation produce [Pt(OCOCH3)2Cl(4′-phenyl-2,2′:6′,2”-terpyridine)][CF3SO3] (3), bearing acetates in the axial positions. 2 and 3 are stable in physiol.-like buffers and in DMSO in the dark, but undergo photoreduction to 1 upon irradiation at 365 nm. Their stability toward reduction is a fundamental parameter to consider: cyclic voltammetry experiments show that the 2 electron reduction Pt(IV) → Pt(II) occurs at a more neg. potential for 3, because of the greater stabilization provided by the acetate axial groups; noteworthily, 3 is stable for hours also in the presence of mM concentration of glutathione. The cytotoxicity of 2 and 3 toward A2780 and A2780cis cell lines reveals that 3 is the least toxic in the dark, but is able to produce cytotoxic effects far higher than cisplatin when irradiated. To shed light on the mechanistic aspects, the interaction with protein and DNA models has been explored through high-resolution mass spectrometry revealing that 2 and 3 behave as prodrugs, but are able to bind to biol. targets only after irradiation

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Reference:
Alcohol – Wikipedia,
Alcohols – Chemistry LibreTexts

The reaction of an aromatic heterocycle with a proton is called a protonation. One of articles about this theory is 《Photochemistry of 1,5-Cyclooctadiene Platinum Complexes for Photoassisted Chemical Vapor Deposition》. Authors are Liu, Hanwen; Brewer, Christopher R.; Walker, Amy V.; McElwee-White, Lisa.The article about the compound:Dichloro(1,5-cyclooctadiene)platinum(II)cas:12080-32-9,SMILESS:C1=CCC/C=CCC/1.[Pt+2].[Cl-].[Cl-]).Recommanded Product: Dichloro(1,5-cyclooctadiene)platinum(II). Through the article, more information about this compound (cas:12080-32-9) is conveyed.

Quantum yields for disappearance of (COD)PtMe2 (1a) and (COD)PtMeCl (1b) were determined at 334 nm in C6D6 solvent. Chain reactions initiated by formation of a Me radical were proposed to be the cause of quantum yields higher than unity (Φ = 5.52 ± 0.40 for 1a) when the reaction mixtures included C4F9I. The chain reactions were suppressed in the presence of the radical trap 2,2,6,6-tetramethyl-1-piperidinyloxy (TEMPO), which resulted in measured disappearance quantum yields of Φ = 0.037 ± 0.003 for (COD)PtMe2 and Φ = 0.44 ± 0.02 for (COD)PtMeCl at 334 nm. Weak luminescence was observed for 1a and 1b, and it was determined that emissive decay is not competitive with Pt-CH3 bond homolysis. DFT studies enabled assignment of both SBLCT and MLCT transitions in the UV/vis spectra of 1a, while 1b only exhibits MLCT transitions. These effects can be attributed to the symmetry of the mol. and its electronic structure.

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Reference:
Alcohol – Wikipedia,
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In general, if the atoms that make up the ring contain heteroatoms, such rings become heterocycles, and organic compounds containing heterocycles are called heterocyclic compounds. An article called The importance of intramolecular conductivity in three dimensional molecular solids, published in 2019, which mentions a compound: 12080-32-9, Name is Dichloro(1,5-cyclooctadiene)platinum(II), Molecular C8H12Cl2Pt, Formula: C8H12Cl2Pt.

Recent years have seen tremendous progress towards understanding the relation between the mol. structure and function of organic field effect transistors. The metrics for organic field effect transistors, which are characterized by mobility and the on/off ratio, are known to be enhanced when the intermol. interaction is strong and the intramol. reorganization energy is low. While these requirements are adequate when describing organic field effect transistors with simple and planar aromatic mol. components, they are insufficient for complex building blocks, which have the potential to localize a carrier on the mol. Here, we show that intramol. conductivity can play a role in controlling device characteristics of organic field effect transistors made with macrocycle building blocks. We use two isomeric macrocyclic semiconductors that consist of perylene diimides linked with bithiophenes and find that the trans-linked macrocycle has a higher mobility than the cis-based device. Through a combination of single mol. junction conductance measurements of the components of the macrocycles, control experiments with acyclic counterparts to the macrocycles, and analyses of each of the materials using spectroscopy, electrochem., and d. functional theory, we attribute the difference in electron mobility of the OFETs created with the two isomers to the difference in intramol. conductivity of the two macrocycles.

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Reference:
Alcohol – Wikipedia,
Alcohols – Chemistry LibreTexts

In general, if the atoms that make up the ring contain heteroatoms, such rings become heterocycles, and organic compounds containing heterocycles are called heterocyclic compounds. An article called Heteroarylquinoxalines as thiabendazole analogs. Part 4: Synthesis of 2-thiazolylquinoxalines, published in 1983, which mentions a compound: 23002-78-0, Name is 1-(2-Methylthiazol-4-yl)ethanone, Molecular C6H7NOS, Recommanded Product: 23002-78-0.

Thiazolylquinoxalines I (R1 = H, Me, Ph, NH2, CO2Et, R2 = H; R1 = H, Ph, NH2, CO2Et, R2 = Me) and II (R1 = Me, Ph) were prepared by 2 methods. In the 1st method, acetylthiazoles III and IV (R3 = Me) were converted to glyoxals III and IV (R3 = CHO), isonitroso ketones IV (R3 = CH:NOH), or bromo ketones IV (R3 = CH2Br) which cyclized with o-(H2N)2C6H4 to I and II. In the 2nd method, acetylquinoxalines V were brominated and the products cyclized with thioamides to I. I (R1 = CO2Et, R2 = H, Me) underwent saponification, ammonolysis, aminolysis, and hydrazinolysis to give I (R1 = CO2K, CO2H, CONR4R5; R4 = H, Me, Et, Bu, NH2, R5 = H; R4 = R5 = Me; NR4R5 = morpholino, piperidino).

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Reference:
Alcohol – Wikipedia,
Alcohols – Chemistry LibreTexts

Category: alcohols-buliding-blocks. The mechanism of aromatic electrophilic substitution of aromatic heterocycles is consistent with that of benzene. Compound: Dichloro(1,5-cyclooctadiene)platinum(II), is researched, Molecular C8H12Cl2Pt, CAS is 12080-32-9, about Platinum(II) Complexes of Tridentate N N- N -Coordinating Ligands Based on Imides, Amides, and Hydrazides: Synthesis and Luminescence Properties. Author is Puttock, Emma V.; Sturala, Jiri; Kistemaker, Jos C. M.; Williams, J. A. Gareth.

Five Pt(II) complexes are described in which the metal ion is bound to anionic N N N-coordinating ligands. The central, deprotonated N atom is derived from an imide Ar-C(:O)-NH-C(:O)-Ar {PtL1-2Cl; Ar = pyridine or pyrimidine}, an amide py-C(:O)-NH-CH2-py {PtL3Cl}, or a hydrazide py-C(:O)-NH-N:CH-py {PtL4Cl}. The imide complexes PtL1-2Cl show no significant emission in solution but are modestly bright green/yellow phosphors in the solid state. PtL3Cl is weakly phosphorescent. PtL4Cl is formed as a mixture of isomers, bound through either the amido or imino nitrogen, the latter converting to the former upon absorption of light. Remarkably, the imino form displays fluorescence in solution, λ0,0=535 nm, whereas the amido shows phosphorescence, λ0,0=624 nm, τ=440 ns. It is highly unusual for two isomeric compounds to display emission from states of different spin multiplicity. The amido-bound PtL4Cl can act as a bidentate O N-coordinating ligand, demonstrated by the formation of bimetallic complexes with iridium(III) or ruthenium(II).

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Reference:
Alcohol – Wikipedia,
Alcohols – Chemistry LibreTexts

The reaction of an aromatic heterocycle with a proton is called a protonation. One of articles about this theory is 《Scope and selectivity in palladium-catalyzed directed C-H bond halogenation reactions》. Authors are Kalyani, Dipannita; Dick, Allison R.; Anani, Waseem Q.; Sanford, Melanie S..The article about the compound:1-(4-Chlorophenyl)pyrrolidin-2-onecas:7661-33-8,SMILESS:O=C1N(C2=CC=C(Cl)C=C2)CCC1).Safety of 1-(4-Chlorophenyl)pyrrolidin-2-one. Through the article, more information about this compound (cas:7661-33-8) is conveyed.

Palladium-catalyzed ligand directed C-H activation/halogenation reactions have been extensively explored. Both the nature of the directing group and the substitution pattern on the arene ring of the substrate lead to different reactivity profiles, and often different and complementary products, in the presence and absence of the catalyst.

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Reference:
Alcohol – Wikipedia,
Alcohols – Chemistry LibreTexts

Category: alcohols-buliding-blocks. The mechanism of aromatic electrophilic substitution of aromatic heterocycles is consistent with that of benzene. Compound: Dichloro(1,5-cyclooctadiene)platinum(II), is researched, Molecular C8H12Cl2Pt, CAS is 12080-32-9, about pH-mediated colorimetric and luminescent sensing of aqueous nitrate anions by a platinum(II) luminophore@mesoporous silica composite. Author is Norton, Amie E.; Sharma, Malvika; Cashen, Christina; Dourges, Marie-Anne; Toupance, Thierry; Krause, Jeanette A.; Motkuri, Radha Kishan; Connick, William B.; Chatterjee, Sayandev.

Increased levels of nitrate (NO3-) in the environment can be detrimental to human health. Herein, we report a robust, cost-effective, and scalable, hybrid material-based colorimetric/luminescent sensor technol. for rapid, selective, sensitive, and interference-free in situ NO3- detection. These hybrid materials are based on a square-planar platinum(II) salt [Pt(tpy)Cl]PF6 (tpy = 2,2′;6′,2′′-terpyridine) supported on mesoporous silica. The platinum salt undergoes a vivid change in color and luminescence upon exposure to aqueous NO3- anions at pH ≤ 0 caused by substitution of the PF6- anions by aqueous NO3-. This change in photophysics of the platinum salt is induced by a rearrangement of its crystal lattice that leads to an extended Pt···Pt···Pt interaction, along with a concomitant change in its electronic structure. Furthermore, incorporating the material into mesoporous silica enhances the surface area and increases the detection sensitivity. A NO3- detection limit of 0.05 mM (3.1 ppm) is achieved, which is sufficiently lower than the ambient water quality limit of 0.16 mM (10 ppm) set by the United States Environmental Protection Agency. The colorimetric/luminescence of the hybrid material is highly selective to aqueous NO3- anions in the presence of other interfering anions, suggesting that this material is a promising candidate for the rapid NO3- detection and quantification in practical samples without separation, concentration, or other pretreatment steps.

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Reference:
Alcohol – Wikipedia,
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The three-dimensional configuration of the ester heterocycle is basically the same as that of the carbocycle. Compound: 3-Bromo-4-chloronitrobenzene(SMILESS: BrC1=C(C=CC(=C1)[N+](=O)[O-])Cl,cas:16588-26-4) is researched.Computed Properties of C38H24F4O4P2. The article 《Synthesis and ultraviolet spectra of nitrodiphenyl-amine disperse dyes. II. Synthesis of some substituted 2- and 4-nitrodiphenylamines》 in relation to this compound, is published in Journal of the Society of Dyers and Colourists. Let’s take a look at the latest research on this compound (cas:16588-26-4).

The synthesis of some substituted 2- and 4-nitrodiphenylamines, yellow dyes for synthetic fibers, is described. Condensation of 0.02 mole 2,5-Cl2C6H3NO2 with 0.04 mole PhNH2 in 50 ml. boiling EtOH containing 3 g. NaOAc gave 52.8% I (R = NO2, R1 = Cl, R2 = R3 = R4 = H), m. 59-60° (75% aqueous alc.). Other I were prepared similarly (R, R1, R2, R3, R4, % yield, and m.p. given): NO2, Cl, OMe, H, H, 50, 100-1°; NO2, Cl, H, OMe, H, 37, 90°; NO2, Cl, H, H, OMe, 48, 118-19°; NO2, Cl, F, H, H, 21, 113-14°; NO2, Cl, H, F, H, 40, 99-100°; NO2, Cl, H, H, F, 38, 80-1°; NO2, Cl, H, H, SO2Me, 15, 210-11°; CF3, NO2, H, H, H, 71, 63-4°; CF3, NO2, OMe, H, H, 16, 106-7°; CF3, NO2, H, OMe, H, 32, 88°; CF3, NO2, H, H, OMe, 74, 87-8°; CF3, NO2, F, H, H, 30, 60-1°; CF3, NO2, H, F, H, 57, 73-4°; CF3, NO2, H, H, F, 20, 74-5°; MeSO2, NO2, H, H, H, 82, 169-70°; Me, NO2, H, H, H, 23, 133-4°; NO2, Me, H, H, H, 79, 34-5°; NO2, OMe, H, H, H, 23, 44-5°. Fusion of 0.02 mole 3,4-Cl2C6H3NO2 (II) with 0.04 mole PhNH2 gave 31.8% I (R = Cl, R1 = NO2, R2 = R3 = R4 = H), m. 112-13°. Other I (R = Cl, R1 = NO2) were prepared similarly (R2, R3, R4, % yield, and m.p. given): OMe, H, H, 36, 108-9°; H, OMe, H, 25, 122-3°; H, H, OMe, 32, 99-100°; H, H, F, 20, 119-20°. Condensation of 0.02 mole 4,3-Cl(O2N)C6H3SO2NH2 (III) and 0.03 mole PhNH2 by fusing for 6 hrs. at 130° gave 71.8% I (R = NO2, R1 = SO2NH2, R2 = R3 = R4 = H), m. 179-80°. Other I (R = NO2, R1 = SO2NH2) were prepared similarly (R2, R3, R4, % yield, and m.p. given): Me, H, H, 84, 195-6°; H, Me, H, 85, 172-3°; H, H, Me, 90, 196-7°; OMe, H, H, 41, 225-6°; H, OMe, H, 91, 181-2°; H, H, OMe, 89, 226-7°; F, H, H, 61, 206-7°; H, F, H, 77, 195-6°; H, H, F, 80, 234-5°; Cl, H, H, 42, 202-3°; H, Cl, H, 80, 201-2°; H, H, Cl, 80, 241-2°; Br, H, H, 60, 200-1°; H, Br, H, 79, 207-8°; H, H, Br, 84, 235-6°; CF3, H, H, 40, 169-70°; H, CF3, H, 82, 210-11°; H, H, CF3, 29, 260-1°; H, H, SO2Me, 59, 253-4°. Condensation of 4.7 g. 2,5-Cl(O2N)C6H3SO2NH2 (IV) with 0.04 mole PhNH2 in 100 ml. boiling PhNO2 for 24 hrs. gave 68.4% I (R = SO2NH2, R1 = NO2, R2 = R3 = R4 = H), m. 175-6°. Other I (R = SO2NH2, R1 = NO2) were prepared similarly (R2, R3, R4, % yield, and m.p. given): OMe, H, H, 62, 205-8°; H, OMe, H, 59, 172-4°; H, H, OMe, 65, 160°; F, H, H, 60, 182-3°; H, F, H, 68, 173-4°; H, H, F, 71, 162-4°. A mixture of 25 g. 4,3-Cl(O2N)C6H3CO2H and 50 ml. SOCl2 was refluxed for 2 hrs., stripped of excess SOCl2, and treated with excess NH4OH to give 86.4% 4,3-Cl(O2N)C6H3CONH2, m. 154-5° (EtOH), which (0.02 mole) was condensed with 0.04 mole PhNH2 in EtOH containing NaOAc to give 34.4% I (R = NO2, R1 = CONH2, R2 = R3 = R4 = H), m. 194-5°. Other I were prepared similarly (R, R1, R2, R3, R4, % yield, and m.p. given): NO2, CONH2, OMe, H, H, 68, 144-5°; NO2, CONH2, H, OMe, H, 72, 170-1°; NO2, CONH2, H, H, OMe, 68, 220-1°; NO2, CONH2, F, H, H, 60, 169-71°; NO2, CONH2, H, F, H, 67, 191-2°; NO2, CONH2, H, H, F, 78, 207-8°; NO2, CONH2, H, H, SO2Me, 10, 244-5°; CONH2, NO2, H, H, H, 25, 184-5°; CONH2, NO2, OMe, H, H, 59, 215-16°; CONH2, NO2, H, OMe, H, 55, 198-9°; CONH2, NO2, H, H, OMe, 79, 216-17°; CONH2, NO2, F, H, H, 49, 184-5°; CONH2, NO2, H, F, H, 43, 233-4°; CONH2, NO2, H, H, F, 82, 231-2°; CONH2, NO2, H, H, SO2Me, 7, 207-8°. Esterification of 4,3-Cl(O2N)C6H3CO2H gave 4,3-Cl(O2N)C6H3CO2Et, m. 60-1° (EtOH), which was condensed with PhNH2 in boiling EtOH to give 92.8% I (R = NO2, R1 = CO2Et, R2 = R3 = R4 = H), m. 114-15°. Other I were prepared similarly (R, R1, R2, R3, R4, % yield, and m.p. given): NO2, CO2Et, OMe, H, H, 72, 116-18°; NO2, CO2Et, H, OMe, H, 70, 105-6°; NO2, CO2Et, H, H, OMe, 63, 128-9°; NO2, CO2Et, F, H, H, 15, 120-2°; NO2, CO2Et, H, F, H, 69, 79-80°; NO2, CO2Et, H, H, F, 52, 138-9°; NO2, CO2Et, H, H, SO2Me, 13, 149-50°; CO2Et, NO2, H, H, H, 29, 111-12°; CO2Et, NO2, OMe, H, H, 41, 112-13°; CO2Et, NO2, H, OMe, H, 46, 81-2°; CO2Et, NO2, H, H, OMe, 56, 120-2°; CO2Et, NO2, F, H, H, 18, 105°; CO2Et, NO2, H, F, H, 59, 119-20°; CO2Et, NO2, H, H, F, 34, 121-2°; CO2Et, NO2, H, H, SO2Me, 10, 189-90°; NO2, CF3, H, H, H, 63, 84°; NO2, CF3, OMe, H, H, 39, 123-4°; NO2, CF3, H, OMe, H, 81, 67-8°; NO2, CF3, H, H, OMe, 80, 85-6°; NO2, CF3, F, H, H, 76, 77-8°; NO2, CF3, H, F, H, 70, 93°; NO2, CF3, H, H, F, 54, 77-8°; NO2, CF3, H, H, SO2Me, 10, 149-50°. Nitration of p-ClC6H4SO2Me with KNO3 in concentrated H2SO4 at 80-5° for 3 hrs. gave 81.7% 4,3-Cl(O2N)C6H3SO2Me, m. 121-2° (20% aqueous alc.), which was condensed with PhNH2 to give 92% I (R = NO2, R1 = SO2Me, R2 = R3 = R4 = H), m. 130-1°. A solution of 15 g. 0-ClC6H4CN in fuming HNO3 was allowed to warm to room temperature from 0-4° in 1 hr., kept for 1 hr. at room temperature, and mixed with 600 ml. ice-water to give 81.8% 2,5-Cl(O2N)C6H3CN, m. 108° (EtOH), which was condensed with PhNH2 in the presence of NaOAc to give 78% I (R = CN, R1 = NO2, R2 = R3 = R4 = H), m. 159-60°. Similarly prepared was I (R = NO2, R1 = CN, R2 = R3 = R4 = H), m. 121-2°. A suspension of 21.7 g. 4,2-Br(O2N)C6H3NH2 in 85 ml. concentrated HCl at 0-4° was diazotized with NaNO2, stirred 1 hr. at 5°, mixed with 15 g. CuCl2 in 50 ml. concentrated HCl, warmed to 70° in 1 hr., and stirred for 30 min. at 70° and overnight at room temperature to give 50% 5,2-Br(Cl)C6H3NO2, m. 70-1° (20% aqueous alc.), which was condensed with PhNH2 to give 80.5% I (R = NO2, R1 = Br, R2 = R3 = R4 = H), m. 54-6°. Similarly prepared were I (R = Br, R1 = NO2, R2 = R3 = R4 = H), m. 111-12°. I (R = NO2, R1 = F, R2 = R3 = R4 = H), m. 120-1°, and I (R = F, R1 = NO2, R2 = R3 = R4 = H), m. 134°. Nitration of 4-ClC6H4CHO gave 80% 4,3-Cl(O2N)C6H3CHO, m. 65-6° (EtOH), which was condensed with PhNH2 in the presence of NaOAc to give a mixture of I (R = NO2, R1 = CHO, R2 = R3 = R4 = H), m. 147-8°, and 4,3-PhNH(O2N)C6H3CH:NPh, m. 108-9°. Similarly prepared was 2,5-PhNH(O2N)C6H3CHO, m. 182° (by-product and m. 132-3°). Attempted conversion of II with 2-, 3-, or 4-FC6H4NH2 or with 3-MeOC6H4NH2 in refluxing HCONMe2 gave 75-85% 2,4-Cl(O2N)C6H3NMe2, m. 78°. Similarly, III and 2- or 4-F3CC6H4NH2 in HCONMe2 gave 4,3-Me2N(O2N)C6H3SO2NH2, m. 133-4°, while IV with all arylamines in HCONMe2 gave 2,5-Me2N(O2N)C6H3SO2NH2, m. 147-8° (EtOH).

As far as I know, this compound(16588-26-4)Application In Synthesis of 3-Bromo-4-chloronitrobenzene can be applied in many ways, which is helpful for the development of experiments. Therefore many people are doing relevant researches.

Reference:
Alcohol – Wikipedia,
Alcohols – Chemistry LibreTexts

The preparation of ester heterocycles mostly uses heteroatoms as nucleophilic sites, which are achieved by intramolecular substitution or addition reactions. Compound: 3-Bromo-4-chloronitrobenzene( cas:16588-26-4 ) is researched.Application of 16588-26-4.Lucas, Simon C. C.; Atkinson, Stephen J.; Bamborough, Paul; Barnett, Heather; Chung, Chun-wa; Gordon, Laurie; Mitchell, Darren J.; Phillipou, Alexander; Prinjha, Rab K.; Sheppard, Robert J.; Tomkinson, Nicholas C. O.; Watson, Robert J.; Demont, Emmanuel H. published the article 《Optimization of Potent ATAD2 and CECR2 Bromodomain Inhibitors with an Atypical Binding Mode》 about this compound( cas:16588-26-4 ) in Journal of Medicinal Chemistry. Keywords: ATAD2 CECR2 inhibitor cat eye syndrome bromodomains. Let’s learn more about this compound (cas:16588-26-4).

Most bromodomain inhibitors mimic the interactions of the natural acetylated lysine (KAc) histone substrate through key interactions with conserved asparagine and tyrosine residues within the binding pocket. Herein we report the optimization of a series of Ph sulfonamides that exhibit a novel mode of binding to non-bromodomain and extra terminal domain (non-BET) bromodomains through displacement of a normally conserved network of four water mols. Starting from an initial hit mol., we report its divergent optimization toward the ATPase family AAA domain containing 2 (ATAD2) and cat eye syndrome chromosome region, candidate 2 (CECR2) domains. This work concludes with the identification of (R)-55 (GSK232)(I), a highly selective, cellularly penetrant CECR2 inhibitor with excellent physicochem. properties.

As far as I know, this compound(16588-26-4)Application of 16588-26-4 can be applied in many ways, which is helpful for the development of experiments. Therefore many people are doing relevant researches.

Reference:
Alcohol – Wikipedia,
Alcohols – Chemistry LibreTexts