555-08-8

Basic information

• Product Name: DL-Limonene
• Synonyms: Cyclohexene, 1-methyl-4-(1-methylethenyl)-; (4S)-1-methyl-4-(prop-1-en-2-yl)cyclohexene
• CAS NO: 555-08-8
• Molecular Formula: C₁₀H₁₆
• Molecular Weight: 136.234
• EINECS: 231-732-0
• Mol File: 555-08-8.mol
• Article Data: 180

Chemical Properties

• Melting Point: -97℃
• Boiling Point: 175.4°C at 760 mmHg
• Flash Point: 42.8°C
• Density: 0.834g/cm³
• Vapor Pressure: 1.54mmHg at 25°C
• Refractive Index: 1.467
• Water Solubility: <1 g/100mL
• CAS DataBase Reference: DL-Limonene(CAS DataBase Reference)
• NIST Chemistry Reference: DL-Limonene(555-08-8)
• EPA Substance Registry System: DL-Limonene(555-08-8)

Safety Data

• Hazard Codes: Xi:Irritant;; <
• Statements: R10:; R38:; R43:; R50/53:
• Safety Statements: S24:; S37:; S60:; S61:
• Hazardous Substances Data: 555-08-8(Hazardous Substances Data)

Upstream product

• 64-18-6 formic acid 
• 98-55-5 terpineol 
• 18172-67-3 beta-pinene 
• 80-56-8 rac-α-pinene 
• 565-48-0 cis-1,8-terpine 
• 144-62-7 oxalic acid 
• 7785-70-8 (+)-α-pinene 
• 67-64-1 acetone 
• 65-85-0 benzoic acid 
• 623-26-7 terephthalonitrile 
• 67-56-1 methanol 
• 7785-26-4 (-)-α-pinene 
• 104715-14-2 geranyl pyrophosphate 
• 22679-02-3 dimethylallyl pyrophosphate 

Downstream Products

• 4497-96-5 1-Chloro-4-(1-chloro-1-methyl-ethyl)-1-methyl-cyclohexane 
• 1126-35-8 α-terpinyl bromide 
• 71305-95-8 6-chloro-p-mentha-1,8-diene 
• 25580-61-4 1,8-dichloro-cis-p-menthane 
• 112358-23-3 8-iodo-p-menth-1-ene 
• 66271-32-7 2,6,9-trimethyl-phenanthrene 
• 90454-98-1 1,1,1-trichloro-4-(4-methylcyclohex-3-enyl)pent-3-en-2-ol 
• 25580-64-7 1,8-dibromo-trans-p-menthane 
• 4764-54-9 (1RS,2RS,4SR,8RS)-1,2,8,9-tetrabromo-p-menthane 
• 78925-96-9 2-Acetoxy-2-[2-(4-methyl-cyclohex-3-enyl)-allyl]-malonic acid diethyl ester 
• 58506-22-2 p-menthane-1,2,8-triol 
• 5989-27-5 D-limonene 
• 5989-54-8 (-)-(S)-limonene 

Relevant articles and documents

Fine particulate matter (PM) and organic speciation of fireplace emissions

This paper presents a summary of fireplace particle size and organic speciation data gathered to date in an ongoing project. Tests are being conducted in a residential wood combustion (RWC) laboratory on three factory- built fireplaces. RWC wood smoke particles 10 μm (PM10) consist primarily of a mixture of organic compounds that have condensed into droplets; therefore, the size distribution and total mass are influenced by temperature of the sample during its collection. During the series 1 tests (15 tests), the dilution tunnel used to cool and dilute the stack gases gave an average mixed gas temperature of 47.3 °C and an average dilution ratio of 4.3. Averages for the PM2.5 (particles 2.5 μm) and PM10 fractions were 74 and 84%, respectively. For the series 2 tests, the dilution tunnel was modified, reducing the average mixed gas temperatures to 33.8 °C and increasing the average dilution ratio to 11.0 in tests completed to date. PM2.5 and PM10 fractions were 83 and 91%, respectively. Since typical winter time mixed gas temperatures would usually be less than 10 °C, these size fraction results (even from the series 2 tests) probably represent the lower bound; the PM10 and PM2.5 size fractions might be higher at typical winter temperatures. The particles collected on the first stage (cutpoint ? 11.7 μm) were light gray and appeared to include inorganic ash. Particles collected on the remainder of the stages were black and appeared to be condensed organics because there was noticeable lateral bleeding of the collected materials into the filter substrate. Total particulate emission rates ranged from 10.3 to 58.4 g/h; corresponding emission factors ranged from 3.3 to 14.9 g/kg of dry wood burned. A wide range of Environmental Protection Agency (EPA) Method 8270 semivolatile organic compounds were found in the emissions; of the 17 target compounds quantified, major constituents are phenol, 2-methylphenol, 4- methylphenol, 2,4-dimethylphenol, and naphthalene. An account is given on fireplace particle size and organic speciation data gathered to date in an ongoing project. Total particulate matter emission rates and the results of analyses for semivolatile organics in the emissions are discussed.

Acidic functionalized ionic liquids as catalyst for the isomerization of α-pinene to camphene

An acidic functionalized ionic liquids (ILs) [HSO3-(CH2)3-NEt3]Cl-ZnCl2 was synthesized and used to catalyze the isomerization of α-pinene in a homogeneous system. The optimum conditions for isomerization were obtained as follows: n(α-pinene):n(ILs) = 9:1, reaction temperature 140 °C, and reaction time 4 h, α-pinene 0.04 mol. Under the optimal conditions, the conversion of α-pinene was 97.6 % and the selectivity for camphene could reach 64.8 %. In addition, the catalyst could be easily separated by centrifugation after the isomerization completely finished. When the ILs were repeatedly used for four times, the conversion of α-pinene and the selectivity for camphene were still excellent, indicating the superb recycle ability of the acidic functionalized ILs catalyst.

Synthesis of Terpineol from Alpha-Pinene Catalyzed by α-Hydroxy Acids

We report the use of five alpha-hydroxy acids (citric, tartaric, mandelic, lactic and glycolic acids) as catalysts in the synthesis of terpineol from alpha-pinene. The study found that the hydration rate of pinene was slow when only catalyzed by alpha-hydroxyl acids. Ternary composite catalysts, composed of AHAs, phosphoric acid, and acetic acid, had a good catalytic performance. The reaction step was hydrolysis of the intermediate terpinyl acetate, which yielded terpineol. The optimal reaction conditions were as follows: alpha-pinene, acetic acid, water, citric acid, and phosphoric acid, at a mass ratio of 1:2.5:1:(0.1–0.05):0.05, a reaction temperature of 70? C, and a reaction time of 12–15 h. The conversion of alpha-pinene was 96%, the content of alpha-terpineol was 46.9%, and the selectivity of alpha-terpineol was 48.1%. In addition, the catalytic performance of monolayer graphene oxide and its composite catalyst with citric acid was studied, with acetic acid used as an additive.

Method and Means for Releasing a Terpene Mixture to a Cannabis Flower During Storage

A method and means for releasing a terpene mixture to a Cannabis flower during storage with may be from a cotton pulp card or a two-way humidity pack with an additional terpene blend for keeping a Cannabis flower fresh while naturally increasing the desired terpene levels. The product is a blend of humidity regulating agents infused with terpenes (plant derived) which allows for the product to be paired with herbal material to increase and maintain the relative humidity, while transferring the flavor/aroma/taste terpenes from the package into the herbal material. There are two embodiments, the first is a Terp Pack+Humidity (“Terp Pack+RH”) which contains a herban material to increase and maintain relative humidity, while releasing the infused terenes, and the second is more simply a Terp Pack (“Terp Pack”) which contains no humidity enhancing material and is only a carrier for releasing the terpene mixture.

Monoterpenes etherification reactions with alkyl alcohols over cesium partially exchanged Keggin heteropoly salts: effects of catalyst composition

In this work, cesium partially exchanged Keggin heteropolyacid (HPA) salts were prepared, characterized, and evaluated as solid catalysts in monoterpenes etherification reactions with alkyl alcohols. A comparison of the activity of soluble HPAs and their insoluble cesium salts showed that among three different Keggin anions the phosphotungstate was the most efficient catalyst. Assessments on the effects of the level of the protons exchange by cesium cations demonstrated that Cs2.5H0.5PW12O40 solid salt was the most active and selective phosphotungstate catalyst, converting β-pinene to α-terpinyl methyl ether. The influences of the main reaction parameters such as reaction temperature, time, catalyst load, substrate nature (i.e., alcohols and monoterpenes) were investigated. We have demonstrated that the simultaneous presence of the cesium ions and protons in the catalyst plays an essential role, being the 2.5–0.5 the optimum molar ratio. The Cs2.5H0.5PW12O40 salt was efficiently recovered and reused without loss of catalytic activity. Graphic abstract: [Figure not available: see fulltext.]