The Limonene Biorefinery: From Extractive Technologies to Its Catalytic Upgrading into p-Cymene

Satira, Antonella; Espro, Claudia; Paone, Emilia; Calabrò, Paolo S.; Pagliaro, Mario; Ciriminna, Rosaria; Mauriello, Francesco

doi:10.3390/catal11030387

Cited by 15 publications

(16 citation statements)

References 88 publications

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“…The distribution of products depends on the process conditions and on the feedstock used, but in general 50-80% of the original biomass is present in the solid product, 5-20% in the aqueous phase which contains inorganic and organic matter, and 2-5% in the gas phase which is mainly composed of CO 2 [12]. Hydrothermal methods are largely used in petroleum-based refineries and are getting more and more attention from both scientific and industrial researchers since their process parameters can be easily translated into modern biorefineries aimed at the upgrading of lignocellulosic residues and wastes [13]. With respect to other (bio)refinery processes, HT protocols present several advantages in terms of sustainability since they generally adopt mild reaction conditions (e.g., temperature and pressure) without any homogeneous or heterogeneous catalysts and in the presence of water as a green reaction solvent (used as such or in combination with simple aliphatic alcohols) [13].…”

Section: Introductionmentioning

confidence: 99%

Hydrothermal Carbonization as Sustainable Process for the Complete Upgrading of Orange Peel Waste into Value-Added Chemicals and Bio-Carbon Materials

et al. 2021

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In this study, a simple and green protocol to obtain hydrochar and high-added value products, mainly 5-hydroxymethylfurfural (5-HMF), furfural (FU), levulinic acid (LA) and alkyl levulinates, by using the hydrothermal carbonization (HTC) of orange peel waste (OPW) is presented. Process variables, such as reaction temperature (180–300 °C), reaction time (60–300 min), biomass:water ratio and initial pH were investigated in order to find the optimum conditions that maximize both the yields of solid hydrochar and 5-HMF and levulinates in the bio-oil. Data obtained evidence that the highest yield of hydrochar is obtained at a 210 °C reaction temperature, 180 min residence time, 6/1 w/w orange peel waste to water ratio and a 3.6 initial pH. The bio-products distribution strongly depends on the applied reaction conditions. Overall, 180 °C was found to be the best reaction temperature that maximizes the production of furfural and 5-HMF in the presence of pure water as a reaction medium.

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Section: Introductionmentioning

confidence: 99%

Hydrothermal Carbonization as Sustainable Process for the Complete Upgrading of Orange Peel Waste into Value-Added Chemicals and Bio-Carbon Materials

et al. 2021

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“…Dehydroisomerisation of limonene to p-cymene. p-Cymene can also be produced by dehydroisomerisation of limonene occurring through double bond migration on acid sites followed by dehydrogenation on metal or oxo-metal sites (Scheme 2), the latter probably being the rate-limiting step [20][21][22][23][24][25]. This reaction occurs easier than the α-pinene-to-p-Cymene conversion because it does not include C-C bond breaking.…”

Section: Introductionmentioning

confidence: 99%

“…This reaction occurs easier than the α-pinene-to-p-Cymene conversion because it does not include C-C bond breaking. A number of heterogeneous catalysts have been reported for this reaction in liquid and gas phases [20][21][22][23][24][25], including Ti/SBA-15 (liquid phase, 160 • C, 56% p-Cymene yield) [21], Pd/HZSM-5 (liquid phase, 260 • C, 8 bar pressure, 82% yield) [22], Pd/Al 2 O 3 (supercritical EtOH, 300 • C, 65 bar pressure, 80% yield) [23], TiO 2 (gas phase, 300 • C, 90% yield) [24], Pd/SiO 2 (gas phase, 300 • C, in H 2 flow, 99% yield) [25] and others [20]. Pd/SiO 2 gives the highest yield of p-Cymene in the gas phase, however, it requires continuous H 2 supply to prevent catalyst deactivation [25] as in the case of α-pinene dehydroisomerisation [1].…”

Section: Introductionmentioning

confidence: 99%

Dehydroisomerisation of α-Pinene and Limonene to p-Cymene over Silica-Supported ZnO in the Gas Phase

2021

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Silica-supported zinc oxide possessing acid and dehydrogenation functions is an efficient, noble-metal-free bifunctional catalyst for the environment-friendly synthesis of p-Cymene from renewable monoterpene feedstock by gas-phase dehydroisomerisation of α-pinene and limonene in a fixed-bed reactor. The reaction involves acid-catalysed terpene isomerisation to p-menthadienes followed by dehydrogenation to form p-Cymene. Dehydroisomerisation of α-pinene produces p-Cymene with 90% yield at 100% conversion at 370 °C and WHSV = 0.01–0.020 h−1. The reaction with limonene gives a 100% p-Cymene yield at 325 °C and WHSV = 0.080 h−1. ZnO/SiO2 catalyst shows stable performance for over 70 h without co-feeding hydrogen.

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“…[3] It has been also recommended as alternative solvent to petroleum-based solvents. [4] Its antiviral property was also observed in disease-causing pathogenic microbes such as Herpes simplex and influenza virus (Gupta et al, 2021). Its action against Covid-19 also demonstrates that it might be a candidate antiviral agent if confirmed by further studies.…”

Section: Introductionmentioning

confidence: 90%

Development of an Optimized Method to Obtain a Limonene‐Rich Concentrate from the Discarded Lemon Peels

Balci-Torun

Toprakçı

Deniz

et al. 2023

Chemistry & Biodiversity

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In this study, lemon peels were used as volatile component source. Automatic solvent extraction has been used for the recovery of limonene rich citrus volatile extract for the first time. The process parameters (amount of raw material, immersion time and washing time) were analyzed to optimize the process by means of Box‐Behnken design via response surface methodology. The optimum conditions were achieved by ~10 g fresh lemon peel, and ~15 min immersion time and ~13 min washing time. The difference between the actual (89.37 mg/g limonene) and predicted (90.85 mg/g limonene) results was satisfactory (<2 %). α‐Terpinene, β‐pinene, citral, ɣ‐terpinene and linalool were determined as other major volatiles in the peel extract. FT‐IR and 1H‐ and 13C‐NMR spectroscopies were applied to verify the identified volatile compounds.

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The Limonene Biorefinery: From Extractive Technologies to Its Catalytic Upgrading into p-Cymene

Cited by 15 publications

References 88 publications

Hydrothermal Carbonization as Sustainable Process for the Complete Upgrading of Orange Peel Waste into Value-Added Chemicals and Bio-Carbon Materials

Hydrothermal Carbonization as Sustainable Process for the Complete Upgrading of Orange Peel Waste into Value-Added Chemicals and Bio-Carbon Materials

Dehydroisomerisation of α-Pinene and Limonene to p-Cymene over Silica-Supported ZnO in the Gas Phase

Development of an Optimized Method to Obtain a Limonene‐Rich Concentrate from the Discarded Lemon Peels

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