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citrus_latifolia_tanaka [2015/07/21 22:37]
andreas 		citrus_latifolia_tanaka [2017/11/20 16:51]
andreas
Zeile 4: Zeile 4:
  
 The major component of //lime peel oil// is limonene (40-45%), followed by [[http://www.thegoodscentscompany.com/data/rw1017031.html|γ-terpinene]] (17-21%) and β-pinene (11-13%). Minor components are α-thujene (0.4-0.7%), sabinene (1-2%), p-cymene(0.2-5%), α-pinene (1-2%), myrcene (1%), terpinolene (0.7-0.9%), β-bisabolene (1-2%), trans-α-bergamotene (1%), and α-terpineol (0.5%). Among oxygenated compounds, geranial (2-4%), neral (1-2%), neryl acetate (1-2%), geranyl acetate (0.7-2%), and linalool (0.4-0.5%) are found.\\  The major component of //lime peel oil// is limonene (40-45%), followed by [[http://www.thegoodscentscompany.com/data/rw1017031.html|γ-terpinene]] (17-21%) and β-pinene (11-13%). Minor components are α-thujene (0.4-0.7%), sabinene (1-2%), p-cymene(0.2-5%), α-pinene (1-2%), myrcene (1%), terpinolene (0.7-0.9%), β-bisabolene (1-2%), trans-α-bergamotene (1%), and α-terpineol (0.5%). Among oxygenated compounds, geranial (2-4%), neral (1-2%), neryl acetate (1-2%), geranyl acetate (0.7-2%), and linalool (0.4-0.5%) are found.\\ 
-[Volatile Components of Peel and Leaf Oils of Lemon and Lime Species. Marie-Laure Lota, Dominique de Rocca Serra, Felix Tomi, Camille Jaquemond, Joseph Casanova, J. Agric. Food Chem. 2002, 50, 796−805] +[Volatile Components of Peel and Leaf Oils of Lemon and Lime Species. Marie-Laure Lota, Dominique de Rocca Serra, Felix Tomi, Camille Jaquemond, Joseph Casanova, J. Agric. Food Chem. 2002, 50, 796−805] 
 + 
 +|  {{:limonene.jpg| limonene}} \\ limonene | {{:terpinene_gamma.jpg|γ-terpinene}} \\ γ-terpinene | {{:beta_pinene.jpg| β-pinene }} \\ β-pinene |
  
 "Quantitative results showed the superiority of milled material (7.93% w/w for CO2 extraction and 5.45% w/w for "Quantitative results showed the superiority of milled material (7.93% w/w for CO2 extraction and 5.45% w/w for
Zeile 11: Zeile 13:
 CO2 extraction: d-limonene 48.9%, γ-terpinene 17.0%, β-pinene 14.5%, geranial 1.1%, neral 0.7%, α-terpineol 0.4%, β-bisabolene 3.3%, α-pinene 2.7%, sabinene 2.2%, myrcene 1.4%, cis-α-bergamotene 1.2% CO2 extraction: d-limonene 48.9%, γ-terpinene 17.0%, β-pinene 14.5%, geranial 1.1%, neral 0.7%, α-terpineol 0.4%, β-bisabolene 3.3%, α-pinene 2.7%, sabinene 2.2%, myrcene 1.4%, cis-α-bergamotene 1.2%
 \\ \\
-Hydrodistillation gives fewer non-oxygenated compounds (81.2% vs. 93.3%) and more oxygenated (17.0% vs. 3.3%) and more citral (11.1% vs. 1.8%) than CO2 extraction (extracted from table)." [Extraction of Essential Oils from Lime (Citrus latifolia Tanaka) by Hydrodistillation and Supercritical Carbon Dioxide. Ana Cristina Atti-Santos, Marcelo Rossato, Luciana Atti Serafini, Eduardo Cassel, Patrick Moyna, Brazilian Archives of Biology and Technology, Vol.48 (1), 2005, 155-160] [[http://www.scielo.br/pdf/babt/v48n1/a20v48n1.pdf]]+Hydrodistillation gives fewer non-oxygenated compounds (81.2% vs. 93.3%) and more oxygenated (17.0% vs. 3.3%) and more citral (11.1% vs. 1.8%) than CO2 extraction (extracted from table)." \\ 
 +[Extraction of Essential Oils from Lime (Citrus latifolia Tanaka) by Hydrodistillation and Supercritical Carbon Dioxide. Ana Cristina Atti-Santos, Marcelo Rossato, Luciana Atti Serafini, Eduardo Cassel, Patrick Moyna, Brazilian Archives of Biology and Technology, Vol.48 (1), 2005, 155-160] [[http://www.scielo.br/pdf/babt/v48n1/a20v48n1.pdf]]
  
 {{:dsc01294k.jpg|}} {{:dsc01294k.jpg|}}
  
citrus_latifolia_tanaka.txt · Zuletzt geändert: 2024/05/19 17:44 von andreas

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