3710-23-4

Basic information

• Product Name: 2-ISOPROPENYLNAPHTHALENE
• Synonyms: 2-ISOPROPENYLNAPHTHALENE;2-(1-methylvinyl)naphthalene;1-(2-Naphthyl)-1-methylethene;2-(1-Methylethenyl)naphthalene;2-(2-Naphthyl)-1-propene;2-(2-Naphthyl)propene
• CAS NO: 3710-23-4
• Molecular Formula: C₁₃H₁₂
• Molecular Weight: 168.23
• EINECS: 223-053-3
• Mol File: 3710-23-4.mol

Chemical Properties

• Melting Point: 55 °C
• Boiling Point: 155 °C / 11mmHg
• Flash Point: 123.5°C
• Appearance: /
• Density: 0.993g/cm³
• Vapor Pressure: 0.00617mmHg at 25°C
• Refractive Index: 1.604
• CAS DataBase Reference: 2-ISOPROPENYLNAPHTHALENE(CAS DataBase Reference)
• NIST Chemistry Reference: 2-ISOPROPENYLNAPHTHALENE(3710-23-4)
• EPA Substance Registry System: 2-ISOPROPENYLNAPHTHALENE(3710-23-4)

Safety Data

• Hazard Codes: N
• Statements: 50/53
• Safety Statements: 60-61
• Hazardous Substances Data: 3710-23-4(Hazardous Substances Data)

Usage

Uses

Used in Fragrance Industry:
2-Isopropylnaphthalene is used as a fragrance ingredient for its distinctive scent, contributing to the creation of various scents in consumer products such as soaps, detergents, and cosmetics.
Used in Chemical Processes:
2-Isopropylnaphthalene is used as a solvent in chemical processes, facilitating reactions and aiding in the production of other chemicals due to its solubility and stability characteristics.
Used in Chemical Synthesis:
2-Isopropylnaphthalene is used as a synthetic intermediate in the production of other chemicals, playing a crucial role in the synthesis of various compounds for different applications.

InChI:InChI=1/C13H12/c1-10(2)12-8-7-11-5-3-4-6-13(11)9-12/h3-9H,1H2,2H3

Upstream product

• 91-58-7 2-chloronaphthalene 
• 67-71-0 dimethylsulfone 
• 7228-47-9 2-(2-naphthyl)ethanol 
• 37827-83-1 naphthalene-2-carbonyl fluoride 
• 75-24-1 trimethylaluminum 
• 2243-83-6 2-naphthaloyl chloride 
• 75-16-1 methylmagnesium bromide 
• 941-98-0 1'-naphthacetophenone 
• 1779-49-3 Methyltriphenylphosphonium bromide 
• 1592-38-7 2-Naphthalenemethanol 
• 1334033-46-3 4-methyl-1H-benzo[h]isothiochromene 2,2-dioxide 
• 17355-89-4 2-(2-hydroperoxy-2-methylethyl)naphthalene 
• 2065-66-9 methyl-triphenylphosphonium iodide 
• 93-08-3 methyl 2-naphthyl ketone 

Downstream Products

• 1420904-72-8 C₂₁H₁₉NO₃ 
• 1308661-36-0 2-(naphthalen-2-yl)-1-tosylpropan-2-ol 

Related news

Synthesis of a water-soluble block copolymer of 2-ISOPROPENYLNAPHTHALENE (cas 3710-23-4) and methacrylic acid bearing a pyrene group107/17/2019

An anionic method for preparation of water-soluble block copolymer of 2-isopropenylnaphthalene and methacrylic acid poly(2-IPN-b-MAA), containing pyrene group as a terminal probe, is described. The polymerization process was carried out by an indirect method employing trimethylsilyl methacrylate...detailed

Anionic polymerization and polymer properties of 2-ISOPROPENYLNAPHTHALENE (cas 3710-23-4) and 2-vinylnaphthalene07/14/2019

2-Isopropenylnaphthalene (2-IPN) and 2-vinylnaphthalene (2-VN) were polymerized in toluene with sec-butyllithium initiator. For 2-IPN, equilibrium monomer concentrations were determined, as well as the enthalpy, entropy and ‘absolute’ ceiling temperature, for its polymerization. Densities of b...detailed

Relevant articles and documents

Molecular Complexation and Kinetics for Diels-Alder Condensation of Naphthylalkenes with Tetracyanoethylene

The charge-transfer spectra of 1:1 molecular complexes of seven 1-alkyl-1-(2-naphthyl)ethenes (where R=alkyl group: H,Me,Et,n-Pr,i-Pr,t-Bu,Neopent) and 1-vinylnaphthalene with TCNE were determined in ClCH2CH2Cl as solvent at 27.1 deg C.Equilibrium constants, K; for these complexes vary with R, as based on two opposing factors, viz. (a) the polar substituent factor ?* and (b) the angle-of-twist θ between the planes of the naphthyl and vinyl groups.For R=Neopent (?* dominant) K is 50 times as large as for R=t-Bu (θ dominant).Except for R=t-Bu, kinetics of reaction conform with the equation D+TCNE (K) D*TCNE (k1/k-1) P, where D is the donor alkene, P is the Diels-Alder 1,4-cycloaddition product, and k1 and k-1 are first-order reaction rate constants.Values of k1 vary from 0.71 min-1 (R=H) to 55.5 min-1 (R=Neopent) and the corresponding relative second-order rate constants k2 (or k1K) from 1 to 4000.The rate constant k-1 was measured only for 1b (R=Me, 0.0017 min-1) in the solvent mixture p-xylene/ClCH2CH2Cl.Formation of 1b*TCNE complex gives ΔH = 10.0 kcal/mol and ΔS = 38.4 eu, and conversion to P shows an Arrhenius activation energy of Ea = 7.24 kcal/mol.It is proposed that the preferred conformation of a naphthylalkene for complexation has the R and vinyl groups projecting outward from opposite sides of the plane of the naphthalene ring.The TCNE molecule then aligns parallel to the naphthalene ring on the vinyl side where (except for R=t-Bu) it can slide into the geometry of the transition state to form P.

METHOD FOR OXIDATIVE CLEAVAGE OF COMPOUNDS WITH UNSATURATED DOUBLE BOND

A method for oxidative cleavage of a compound with an unsaturated double bond is provided. The method includes the steps of: (A) providing a compound (I) with an unsaturated double bond, a trifluoromethyl-containing reagent, and a catalyst; wherein, the catalyst is represented by Formula (II): M(O)mL1yL2z??(II);wherein, M, L1, L2, m, y, z, R1, R2 and R3 are defined in the specification; and(B) mixing the compound with an unsaturated double bond and the trifluoromethyl-containing reagent to perform an oxidative cleavage of the compound with the unsaturated double bond by using the catalyst in air or under oxygen atmosphere condition to obtain a compound represented by Formula (III):

Method for oxidative cracking of compound containing unsaturated double bonds

The invention relates to a method for oxidative cracking of a compound containing unsaturated double bonds. The method comprises the following steps: (A) providing a compound (I) containing unsaturated double bonds, a trifluoromethyl-containing reagent and a catalyst, wherein the catalyst is shown as a formula (II): M(O)mL1yL2z (II), M, L1, L2, m, y, z, R1, R2 and R3 being defined in the specification; and (B) mixing the compound containing the unsaturated double bonds and the trifluoromethyl-containing reagent, and performing an oxidative cracking reaction on the compound containing the unsaturated double bonds in the presence of air or oxygen by using the catalyst to obtain a compound represented by formula (III),.

METHOD FOR OXIDATIVE CLEAVAGE OF COMPOUNDS WITH UNSATURATED DOUBLE BOND

A method for oxidative cleavage of a compound with an unsaturated double bond is provided. The method comprises the following step: (A) providing a compound (I) with an unsaturated double bond, a reagent with trifluoromethyl, and a catalyst; wherein the catalyst is represented by the following formula (II): M(O)mL1yL2z (II); wherein, M, L1, L2, m, y, z, R1, R2 and R3 are defined in the specification; and (B) mixing the compound with an unsaturated double bond and the reagent with a trifluoromethyl to perform an oxidation of the compound with the unsaturated double bond by using the catalyst at air or an oxygen condition to get a compound presented as formula (III):

Copper-Catalyzed Transfer Hydrodeuteration of Aryl Alkenes with Quantitative Isotopomer Purity Analysis by Molecular Rotational Resonance Spectroscopy

A copper-catalyzed alkene transfer hydrodeuteration reaction that selectively incorporates one hydrogen and one deuterium atom across an aryl alkene is described. The transfer hydrodeuteration protocol is selective across a variety of internal and terminal alkenes and is also demonstrated on an alkene-containing complex natural product analog. Beyond using 1H, 2H, and 13C NMR analysis to measure reaction selectivity, six transfer hydrodeuteration products were analyzed by molecular rotational resonance (MRR) spectroscopy. The application of MRR spectroscopy to the analysis of isotopic impurities in deuteration chemistry is further explored through a measurement methodology that is compatible with high-throughput sample analysis. In the first step, the MRR spectroscopy signatures of all isotopic variants accessible in the reaction chemistry are analyzed using a broadband chirped-pulse Fourier transform microwave spectrometer. With the signatures in hand, measurement scripts are created to quantitatively analyze the sample composition using a commercial cavity enhanced MRR spectrometer. The sample consumption is below 10 mg with analysis times on the order of 10 min using this instrument - both representing order-of-magnitude reduction compared to broadband MRR spectroscopy. To date, these measurements represent the most precise spectroscopic determination of selectivity in a transfer hydrodeuteration reaction and confirm that product regioselectivity ratios of >140:1 are achievable under this mild protocol.

Visible-Light-Induced Meerwein Fluoroarylation of Styrenes

An unprecedented approach for assembling a broad range of 1,2-diarylethane derivatives with fluorine-containing fully substituted carbon centers was developed. The protocol features straightforward operation, proceeds under metal-free condition, and accommodates a large variety of synthetically useful functionalities. The critical aspect to the success of this novel transformation lies in using aryldiazonium salts as both aryl radical progenitor and also as single electron acceptor which elegantly enables a radical-polar crossover manifold.

Enantioselective Hydrothiolation: Diverging Cyclopropenes through Ligand Control

In this article, we advance Rh-catalyzed hydrothiolation through the divergent reactivity of cyclopropenes. Cyclopropenes undergo hydrothiolation to provide cyclopropyl sulfides or allylic sulfides. The choice of bisphosphine ligand dictates whether the pathway involves ring-retention or ring-opening. Mechanistic studies reveal the origin for this switchable selectivity. Our results suggest the two pathways share a common cyclopropyl-Rh(III) intermediate. Electron-rich Josiphos ligands promote direct reductive elimination from this intermediate to afford cyclopropyl sulfides in high enantio- A nd diastereoselectivities. Alternatively, atropisomeric ligands (such as DTBM-BINAP) enable ring-opening from the cyclopropyl-Rh(III) intermediate to generate allylic sulfides with high enantio- A nd regiocontrol.

Palladium-Catalyzed Markovnikov Hydroaminocarbonylation of 1,1-Disubstituted and 1,1,2-Trisubstituted Alkenes for Formation of Amides with Quaternary Carbon

Hydroaminocarbonylation of alkenes is one of the most promising yet challenging methods for the synthesis of amides. Herein, we reported the development of a novel and effective Pd-catalyzed Markovnikov hydroaminocarbonylation of 1,1-disubstituted or 1,1,2-trisubstituted alkenes with aniline hydrochloride salts to afford amides bearing an α quaternary carbon. The reaction makes use of readily available starting materials, tolerates a wide range of functional groups, and provides a facile and straightforward approach to a diverse array of amides bearing an α quaternary carbon. Mechanistic investigations suggested that the reaction proceeded through a palladium hydride pathway. The hydropalladation and CO insertion are reversible, and the aminolysis is probably the rate-limiting step.

Ni-Catalyzed Reductive Allylation of α-Chloroboronates to Access Homoallylic Boronates

The transition-metal-catalyzed allylation reaction is an efficient strategy for the construction of new carbon-carbon bonds alongside allyl or homoallylic functionalization. Herein we describe a Ni-catalyzed reductive allylation of α-chloroboronates to efficiently render the corresponding homoallylic boronates, which could be readily converted into valuable homoallylic alcohols or amines or 1,4-diboronates. This reaction features a broad substrate scope with good functional group compatibility that is complementary to the existing methods for the preparation of homoallylic boronates.

Electrochemical fluorosulfonylation of styrenes

An environmentally friendly and efficient electrochemical fluorosulfonylation of styrenes has been developed. With the use of sulfonylhydrazides and triethylamine trihydrofluoride, a diverse array of β-fluorosulfones could be readily obtained. This reaction features mild conditions and a broad substrate scope, which could also be conveniently extended to a gram-scale preparation.