18979-50-5

Basic information

• Product Name: 4-Propoxyphenol
• Synonyms: HYDROQUINONE MONO-N-PROPYL ETHER;HYDROQUINONE MONOPROPYL ETHER;4-PROPYLOXYPHENOL;4-PROPOXYPHENOL;4-N-PROPOXYPHENOL;4-N-PROPYLOXYPHENOL;P-PROPOXYPHENOL;4-propoxy-pheno
• CAS NO: 18979-50-5
• Molecular Formula: C₉H₁₂O₂
• Molecular Weight: 152.19
• Product Categories: Liquid Crystal intermediates;Aromatic Phenols;API intermediates;Building Blocks for Liquid Crystals;Functional Materials;Phenols (Building Blocks for Liquid Crystals)
• Mol File: 18979-50-5.mol

Chemical Properties

• Melting Point: 54-56 °C(lit.)
• Boiling Point: 234.66°C (rough estimate)
• Flash Point: >230 °F
• Appearance: Beige crystalline powder
• Density: 1.0505 (rough estimate)
• Vapor Pressure: 0.00684mmHg at 25°C
• Refractive Index: 1.4910 (estimate)
• Storage Temp.: Inert atmosphere,Room Temperature
• Solubility: DMSO (Slightly), Methanol (Slightly)
• PKA: 10.34±0.15(Predicted)
• CAS DataBase Reference: 4-Propoxyphenol(CAS DataBase Reference)
• NIST Chemistry Reference: 4-Propoxyphenol(18979-50-5)
• EPA Substance Registry System: 4-Propoxyphenol(18979-50-5)

Safety Data

• Hazard Codes: Xi,Xn
• Statements: 36/37/38-22
• Safety Statements: 22-24/25-37/39-26
• WGK Germany: 3
• TSCA: Yes
• Hazardous Substances Data: 18979-50-5(Hazardous Substances Data)

Usage

Chemical Properties

BEIGE CRYSTALLINE POWDER

Uses

Intermediates of Liquid Crystals

InChI:InChI=1/C9H12O2/c1-2-7-11-9-5-3-8(10)4-6-9/h3-6,10H,2,7H2,1H3

Upstream product

• 106-94-5 propyl bromide 
• 123-31-9 hydroquinone 
• 104307-29-1 [4-(1-phenyl-ethyl)-phenyl]-propyl ether 
• 71-23-8 propan-1-ol 
• 106-51-4 p-benzoquinone 
• 6411-34-3 4-allyloxyphenol 
• 1467782-94-0 1-methoxy-4-((4-propoxyphenoxy)methyl)benzene 
• 622-85-5 propoxybenzene 
• 103-16-2 4-Benzyloxyphenol 
• 5736-85-6 4-propoxybenzaldehyde 
• 258513-95-0 4-n-propoxyphenyl benzyl ether 
• 73083-35-9 4-n-Propyloxy-2,4,6-tri-t-butyl-2,5-cyclohexadienon 
• 540-54-5 1-Chloropropane 

Downstream Products

• 671779-00-3 2-chloro-4-propoxy-phenol 
• 61733-32-2 4-(4-n-pentylphenyl)-benzoic acid 4'-n-propyloxyphenyl ester 
• 61733-34-4 4'-Hexyl-biphenyl-4-carboxylic acid 4-propoxy-phenyl ester 
• 61733-38-8 4'-Heptyl-biphenyl-4-carboxylic acid 4-propoxy-phenyl ester 
• 102101-72-4 C₃₇H₄₀O₈ 
• 537-14-4 dichlorophenolindophenol 
• 138946-75-5 (E)-3-(4-Methoxy-phenyl)-acrylic acid 4-propoxy-phenyl ester 
• 138946-76-6 (E)-3-(4-Ethoxy-phenyl)-acrylic acid 4-propoxy-phenyl ester 
• 138946-77-7 (E)-3-(4-Propoxy-phenyl)-acrylic acid 4-propoxy-phenyl ester 
• 138946-78-8 (E)-3-(4-Butoxy-phenyl)-acrylic acid 4-propoxy-phenyl ester 
• 138946-79-9 (E)-3-(4-Pentyloxy-phenyl)-acrylic acid 4-propoxy-phenyl ester 
• 138946-80-2 (E)-3-(4-Hexyloxy-phenyl)-acrylic acid 4-propoxy-phenyl ester 
• 138946-81-3 (E)-3-(4-Heptyloxy-phenyl)-acrylic acid 4-propoxy-phenyl ester 
• 186134-20-3 1-propyloxy-4-(tetrahydropyran-2-yloxy)benzene 

Relevant articles and documents

Synthetic method 4 - alkoxyphenol compounds

The invention discloses a synthetic method of 4 - alkoxyphenol compounds, and belongs to the field of organic chemical synthesis. The method is as follows: An aryl alkyl ether compound is added to the sealing tube. The catalyst dimerization acetic acid rhodium and the oxidizing agent iodobenzene diethyl ester are added, a solvent trifluoroacetic anhydride is added, and the 4 -alkoxyphenol compound is prepared by heating reaction. To the invention, high regioselectivity direct hydroxylation of the aryl alkyl ether compound is realized, the application range of the substrate is wide, the yield is high, the activity after amplification reaction does not significantly decay, and higher yield is still obtained. The utility model has good practicability and industrial application prospect.

Para -Selective hydroxylation of alkyl aryl ethers

para-Selective hydroxylation of alkyl aryl ethers is established, which proceeds with a ruthenium(ii) catalyst, hypervalent iodine(iii) and trifluoroacetic anhydride via a radical mechanism. This protocol tolerates a wide scope of substrates and provides a facile and efficient method for preparing clinical drugs monobenzone and pramocaine on a gram scale.

Nano-NiFe2O4 as an efficient catalyst for regio- and chemoselective transfer hydrogenation of olefins/alkynes and dehydrogenation of alcohols under Pd-/Ru-free conditions

Here, we have demonstrated the magnetic nano-NiFe2O4 catalyzed transfer hydrogenation of olefins/alkynes using isopropyl alcohol as a source of hydrogen under ligand/base/Pd-/Ru-metal-free conditions, and dehydrogenation of alcohols under oxidant-free conditions.

Facile conversion of para-benzoquinones to para-alkoxyphenols with primary/secondary alcohols and amberlyst-15: A process showing novel reducing property of such alcohols

A new efficient methodology has been developed for the synthesis of para-alkoxyphenols, an important group of anti-melanoma compounds, by heating alcoholic solutions of para-benzoquinones in the presence of amberlyst-15. The most notable feature here is the behaviour of the used primary or secondary alcohol as an effective reducing agent.

A convenient approach for the deprotection and scavenging of the PMB group using POCl3

A convenient and high yielding approach for the deprotection and scavenging of the p-methoxybenzyl (PMB) group in PMB ethers and PMB esters was developed using POCl3 as the reagent. 4-Methoxybenzyl chloride, a starting material used for the preparation of PMB ethers and esters was regenerated in the deprotection step. This mild and selective procedure tolerates several acid sensitive functional groups. The Royal Society of Chemistry 2013.

Dialkoxybenzene and dialkoxyallylbenzene feeding and oviposition deterrents against the cabbage looper, trichoplusia ni: Potential insect behavior control agents

The antifeedant, oviposition deterrent, and toxic effects of individual dialkoxybenzene compounds/sets and of hydroxy- or alkoxy-substituted allylbenzenes, obtained through Claisen rearrangement of substituted allyloxybenzenes, were assessed against the cabbage looper, Trichoplusia ni, in laboratory bioassays. Most of the compounds/sets strongly deterred larval feeding, with some exhibiting mild toxic and oviposition deterrent effects as well. Some of the compounds/sets were more active than the commercial insect repellent, DEET (N,N-diethyl-m-toluamide), as both feeding and oviposition deterrents against the cabbage looper. On the basis of the obtained oviposition data a general hypothesis was proposed regarding the oviposition sites: one binding mode with the alkyl and allyl groups on the same side of the benzene ring resulted in deterrence, the other with alkyl and allyl groups on opposite sides of the benzene ring resulted in stimulation. The results suggest some structure-activity relationships useful in improving the efficacy of the compounds and designing new, nontoxic insect control agents for agriculture.

Screening of dialkoxybenzenes and disubstituted cyclopentene derivatives against the cabbage looper, Trichoplusia ni, for the discovery of new feeding and oviposition deterrents

The antifeedant, oviposition deterrent, and toxic effects of dialkoxybenzene minilibraries and of disubstituted cyclopentene minilibraries (i.e., consisting of four to five compounds) along with their pure constituent compounds were assessed against third instar larvae and adults of the cabbage looper, Trichoplusia ni, in laboratory bioassays in a search for new insect control agents. These compounds mimic naturally occurring bioactive odorants and tastants and are relatively easily prepared from commodity chemicals. Most of these libraries strongly deterred larval feeding, with some exhibiting strong toxic and oviposition deterrent effects as well. Our results suggest some structure-function relationships within these libraries. Replacement of a methyl group with larger alkyl substituents increased the feeding deterrent effects in most cases. The presence of a free hydroxyl group, irrespective of the carbon framework or alkyl substituent, served to reduce feeding deterrent effects in all series of compounds. Further, exceeding a certain group size also generally had a detrimental effect. This information will be useful in designing new insect control agents for agriculture. Some of these libraries and compounds may have potential for development as commercial insecticides.

Palladium charcoal-catalyzed deprotection of O-allylphenols

Allyl aryl ethers can be easily cleaved by the use of 10% Pd/C under mild and basic conditions. The present reaction would involve a SET process rather than a π-allyl-palladium complex. The scope and limitation of this new deprotective methodology is also described.

One-pot synthesis of phenols from aromatic aldehydes by Baeyer-Villiger oxidation with H2O2 using water-tolerant Lewis acids in molecular sieves

The heterogeneous oxidation systems Sn-Beta/H2O2 and Al-Beta/H2O2 were both active for the Baeyer-Villiger oxidation of aromatic aldehydes. With alkoxy substituents in ortho and especially in para position, the corresponding formate ester was the primary reaction product with excellent selectivity. The highest selectivity toward the ester was obtained with the Sn-Beta catalyst in dioxane as solvent. High selectivities of the corresponding phenol could be obtained by employing ethanol or aqueous acetonitrile as solvent with Sn-Beta. Al-Beta was more efficient as catalyst for both Baeyer-Villiger oxidation and ester hydrolysis and, thus achieved high yields for the corresponding alcohol. However, this was a less selective catalyst than Sn-Beta zeolite. Sn-Beta was a chemoselective catalyst when the aldehyde reactant contained olefinic groups in an alkyl chain. With these reactants, the Al-zeolite gave no activity. Other classical BV oxidants, e.g., peracids, also yielded the epoxidation products. Thus, Sn-Beta catalysts open a new entry to aromatic phenols with unsaturated alkyl substituents that are interesting intermediates in the chemical industry.

ALDEHYDE CONVERSION METHOD USING A MOLECULAR SIEVE AND THE USE OF THE MOLECULAR SIEVE AS A CATALYST IN SAID METHOD

The inversion relates to an aldehyde conversion method comprising putting an aldehyde into contact with oxygenated water and with a catalyst, under oxidation conditions, wherein the catalyst is a molecular sieve with pores of a diameter of at least 0.52 nm and has an empirical formula in a calcined and dehydrated form of(SnxTiySi1-x-y-zGez) O2 wherein x is a molar fraction of the tin and has a value between 0.001 and 0.1; y is a molar fraction of titanium and has a value from zero to 0.1; and z is the molar fraction molar of the germanium and has a value from zero to 0.08.