99-83-2

Basic information

• Product Name: ALPHA-PHELLANDRENE
• Synonyms: P-MENTHA-1,5-DIENE;A-PHELLANDRENE;FEMA 2856;1-ISOPROPYL-4-METHYL-2,4-CYCLOHEXADIENE;ALPHA-PHELLANDRENE;5-ISOPROPYL-2-METHYL-1,3-CYCLOHEXADIENE;ALPHA-PHELLANDRENE FCC;P-MENTHA-1,5-DIENE 70%
• CAS NO: 99-83-2
• Molecular Formula: C10H16
• Molecular Weight: 136.23
• EINECS: 202-792-5
• Product Categories: Alphabetical Listings;Flavors and Fragrances;O-P
• Mol File: 99-83-2.mol
• Article Data: 14

Chemical Properties

• Melting Point: <25 °C
• Boiling Point: 185.55°C (rough estimate)
• Flash Point: 117 °F
• Appearance: /
• Density: 0.85 g/mL at 25 °C(lit.)
• Vapor Pressure: 1.86mmHg at 25°C
• Refractive Index: n20/D 1.474(lit.)
• Storage Temp.: Store below +30°C.
• Merck: 13,7277
• CAS DataBase Reference: ALPHA-PHELLANDRENE(CAS DataBase Reference)
• NIST Chemistry Reference: ALPHA-PHELLANDRENE(99-83-2)
• EPA Substance Registry System: ALPHA-PHELLANDRENE(99-83-2)

Safety Data

• Hazard Codes: Xn,F
• Statements: 10-22-36/37/38-43
• Safety Statements: 16-26-36/37
• RIDADR: UN 2319 3/PG 3
• WGK Germany: 3
• RTECS: OS8080000
• HazardClass: 3.2
• PackingGroup: III
• Hazardous Substances Data: 99-83-2(Hazardous Substances Data)

Usage

Chemical Properties

α-Phellandrene has a pleasant, fresh, citrus, peppery odor with a discrete mint note. This compound is also reported as having a minty, herbaceous odor.

Occurrence

The d-form has been reported found in the essential oils of bitter fennel, Ceylon cinnamon leaves, star anise, Curcuma longa and other essential oils; the l-form has been reported found in various eucalyptus oils, orange peel oil, angelica, Lantana camara and other oils. Reported found in over 100 foods and beverages including apricot, many citrus peel oils and juices, black currants, papaya, raspberry, strawberry, carrot, celery leaves and seed, bell pepper, tomato, cinnamon, cumin seed, ginger, Mentha oils, nutmeg, pepper, mace, parsley, thyme, Gruyere cheese, cured pork, hop oil, beer, tea, pecan, passion fruit, sweet and wild marjoram, mango, parsnip, cardamom, coriander seed, gin, litchi, dill herb and seed, lovage leaf and seed, caraway, juniper berry, laurel, bitter and sweet fennel, myrtle leaf and berry, sage, nectarine, pimento leaf and berry and mastic gum leaf oil.

Uses

α-Phellandrene is an essential oil component, found to have bactericidal activity.

Definition

ChEBI: One of a pair of phellandrene cyclic monoterpene double-bond isomers in which both double bonds are endocyclic (cf. alpha-phellandrene, where one of them is exocyclic).

Aroma threshold values

Detection: 40 to 200 ppb

Taste threshold values

Taste characteristics at 20 ppm: terpenic, citrus-lime with a fresh green note.

General Description

α-Phellandrene is monoterpene reported to be one of the aroma compounds of black (Piper nigrum) and white ‘‘Ashanti pepper′′ (Piper guineense). It also occurs in the leaves of basil.

Safety Profile

Mdly toxic by ingestion. A severe human skin irritant. Incompatible with air. Flammable liquid when exposed to heat, sparks, or flame. When heated to decomposition it emits acrid smoke and irritating fumes.

Synthesis

The l-form by isolation from Eucalyptus numerosa and similar oils; also from the manufacture of synthetic menthol.

InChI:InChI=1/C10H16/c1-8(2)10-6-4-9(3)5-7-10/h4-6,8,10H,7H2,1-3H3/t10-/m0/s1

Upstream product

• 917-64-6 methyl magnesium iodide 
• 2158-59-0 cryptone 
• 89-81-6 piperitone 
• 177698-19-0 Beta-pinene 
• 80-56-8 Pinene 
• 586-62-9 Terpinolene 
• 586-63-0 isoterpinolene 
• 555-10-2 beta-phellandrene 
• 138-86-3 limonene. 
• 67-56-1 methanol 
• 491-04-3 piperitol 
• 71-23-8 propan-1-ol 
• 64-17-5 ethanol 
• 563-34-8 α-thujene 

Downstream Products

• 18465-95-7 7-isopropyl-6-methylbicyclo<2.2.2>oct-5-ene-2,3-dicarboxylic acid anhydride 
• 18465-95-7 (1S)-7anti-isopropyl-5-methyl-bicyclo[2.2.2]oct-5-ene-2endo,3endo-dicarboxylic acid-anhydride 
• 50919-63-6 diethyl 4-methyl-o-phthalate 
• 563-45-1 3-Methyl-1-butene 
• 75600-82-7 (S)-10-Isopropyl-8-methyl-4-((S)-1-phenyl-ethyl)-2,4,6-triaza-tricyclo[5.2.2.0^2,6]undec-8-ene-3,5-dione 
• 75600-82-7 (R)-10-Isopropyl-8-methyl-4-((S)-1-phenyl-ethyl)-2,4,6-triaza-tricyclo[5.2.2.0^2,6]undec-8-ene-3,5-dione 
• 61585-35-1 p-menth-1-ene 
• 99-87-6 4-methylisopropylbenzene 
• 122-03-2 (4-isopropylbenzaldehyde) 
• 99-86-5 1-methyl-4-isopropyl-1,3-cyclohexadiene 
• 52462-29-0 [ruthenium(II)(η⁶-1-methyl-4-isopropyl-benzene)(chloride)(μ-chloride)]₂ 
• 94947-17-8 Ag⁽¹⁺⁾*C₁₀H₁₆={Ag(C₁₀H₁₆)}⁽¹⁺⁾ 
• 1046160-43-3 C₂₆H₃₂O₄ 
• 1046160-41-1 C₂₆H₃₀O₄ 

Relevant articles and documents

High-Throughput Synthesis of (S)-α-Phellandrene through Three-Step Sequential Continuous-Flow Reactions

The combination of continuous-flow processing with heterogeneous catalysts allows for efficient, sustainable, multistep synthesis. Here, we report the continuous-flow synthesis of a valuable terpene product, phellandrene, from a readily available natural feedstock. The protocol consists of selective hydrogenation using a highly active and stable supported platinum catalyst, dehydrative hydrazone formation, followed by the Shapiro reaction. Appropriate design of the reactor allowed for high productivity and space-time yield. Phellandrene was synthesized on a 30-g scale over 6 h, giving high yields, purity, and productivity.

Converting S-limonene synthase to pinene or phellandrene synthases reveals the plasticity of the active site

S-limonene synthase is a model monoterpene synthase that cyclizes geranyl pyrophosphate (GPP) to form S-limonene. It is a relatively specific enzyme as the majority of its products are composed of limonene. In this study, we converted it to pinene or phellandrene synthases after introducing N345A/L423A/S454A or N345I mutations. Further studies on N345 suggest the polarity of this residue plays a critical role in limonene production by stabilizing the terpinyl cation intermediate. If it is mutated to a non-polar residue, further cyclization or hydride shifts occurs so the carbocation migrates towards the pyrophosphate, leading to the production of pinene or phellandrene. On the other hand, mutant enzymes that still possess a polar residue at this position produce limonene as the major product. N345 is not the only polar residue that may stabilize the terpinyl cation because it is not strictly conserved among limonene synthases across species and there are also several other polar residues in this area. These residues could form a “polar pocket” that may collectively play this stabilizing role. Our study provides important insights into the catalytic mechanism of limonene synthases. Furthermore, it also has wider implications on the evolution of terpene synthases.

A 1,6-ring closure mechanism for (+)-δ-cadinene synthase?

Recombinant (+)-δ-cadinene synthase (DCS) from Gossypium arboreum catalyzes the metal-dependent cyclization of (E,E)-farnesyl diphosphate (FDP) to the cadinane sesquiterpene δ-cadinene, the parent hydrocarbon of cotton phytoalexins such as gossypol. In contrast to some other sesquiterpene cyclases, DCS carries out this transformation with >98% fidelity but, as a consequence, leaves no mechanistic traces of its mode of action. The formation of (+)-δ-cadinene has been shown to occur via the enzyme-bound intermediate (3R)-nerolidyl diphosphate (NDP), which in turn has been postulated to be converted to cis-germacradienyl cation after a 1,10-cyclization. A subsequent 1,3-hydride shift would then relocate the carbocation within the transient macrocycle to expedite a second cyclization that yields the cadinenyl cation with the correct cis stereochemistry found in (+)-δ-cadinene. An elegant 1,10-mechanistic pathway that avoids the formation of (3R)-NDP has also been suggested. In this alternative scenario, the final cadinenyl cation is proposed to be formed through the intermediacy of trans, trans-germacradienyl cation and germacrene D. In addition, an alternative 1,6-ring closure mechanism via the bisabolyl cation has previously been envisioned. We report here a detailed investigation of the catalytic mechanism of DCS using a variety of mechanistic probes including, among others, deuterated and fluorinated FDPs. Farnesyl diphosphate analogues with fluorine at C2 and C10 acted as inhibitors of DCS, but intriguingly, after prolonged overnight incubations, they yielded 2F-germacrene(s) and a 10F-humulene, respectively. The observed 1,10-, and to a lesser extent, 1,11-cyclization activity of DCS with these fluorinated substrates is consistent with the postulated macrocyclization mechanism(s) en route to (+)-δ-cadinene. On the other hand, mechanistic results from incubations of DCS with 6F-FPP, (2Z,6E)-FDP, neryl diphosphate, 6,7-dihydro-FDP, and NDP seem to be in better agreement with the potential involvement of the alternative biosynthetic 1,6-ring closure pathway. In particular, the strong inhibition of DCS by 6F-FDP, coupled to the exclusive bisabolyl- and terpinyl-derived product profiles observed for the DCS-catalyzed turnover of (2Z,6E)-farnesyl and neryl diphosphates, suggested the intermediacy of α-bisabolyl cation. DCS incubations with enantiomerically pure [1- 2H1](1R)-FDP revealed that the putative bisabolyl-derived 1,6-pathway proceeds through (3R)-nerolidyl diphosphate (NDP), is consistent with previous deuterium-labeling studies, and accounts for the cis stereochemistry characteristic of cadinenyl-derived sesquiterpenes. While the results reported here do not unambiguously rule in favor of 1,6- or 1,10-cyclization, they demonstrate the mechanistic versatility inherent to DCS and highlight the possible existence of multiple mechanistic pathways.