| Title | Green Diesel Production by Catalytic Hydrodeoxygenation of Vegetables Oils |
|---|---|
| ID_Doc | 64214 |
| Authors | Nolfi, GD; Gallucci, K; Rossi, L |
| Title | Green Diesel Production by Catalytic Hydrodeoxygenation of Vegetables Oils |
| Year | 2021 |
| Published | International Journal Of Environmental Research And Public Health, 18, 24 |
| Abstract | Non-renewable fossil fuels and the air pollution associated with their combustion have made it necessary to develop fuels that are environmentally friendly and produced from renewable sources. In addition, global warming and climate change have brought to the attention of many countries the need to develop programs and reforms, such as the 2030 Agenda of the United Nations and the European Green Deal, that finance and promote the conversion of all socio-economic activities in favor of sustainable and environmentally friendly development. These major projects include the development of non-polluting biofuels derived from renewable sources. Vegetable oils are a renewable source widely used to produce biofuels due to their high energy density and similar chemical composition to petroleum derivatives, making them the perfect feedstock for biofuel production. Green diesel and other hydrocarbon biofuels, obtained by the catalytic deoxygenation of vegetable oils, represent a sustainable alternative to mineral diesel, as they have physico-chemical properties similar to derived oil fuels. The catalyst, temperature, hydrogen pressure, and the type of vegetable oil can influence the type of biofuel obtained and its properties. The main aspects discussed in this review include the influence of the catalyst and reaction conditions on the catalytic deoxygenation reaction. |
| https://www.mdpi.com/1660-4601/18/24/13041/pdf?version=1639140890 |
Similar Articles
| ID | Score | Article |
|---|---|---|
3186
|
Tulashie, SK; Alale, EM; Agudah, PQ; Osei, CA; Munumkum, CA; Gah, BK; Baidoo, EB A review on the production of biodiesel from waste cooking oil: a circular economy approach(2024) | |
| 10536
|
Altalhi, AA; Morsy, SM; Abou Kana, MTH; Negm, NA; Mohamed, EA Pyrolytic conversion of waste edible oil into biofuel using sulphonated modified alumina(2022)Alexandria Engineering Journal, 61, 6 | |
| 7722
|
Menezes, LNB; Suarez, PAZ; Ghesti, GF Diesel-Like Biofuels Production Using Fatty Waste(2022)Journal Of The Brazilian Chemical Society, 33, 6 | |
| 21332
|
Praveena, V; Martin, LJ; Matijosius, J; Aloui, F; Pugazhendhi, A; Varuvel, EG A systematic review on biofuel production and utilization from algae and waste feedstocks- a circular economy approach(2024) | |
| 14411
|
Gonzalez-Quiroga, A; Djokic, MR; Van Geem, KM; Marin, GB Conversion of Solid Waste to Diesel via Catalytic Pressureless Depolymerization: Pilot Scale Production and Detailed Compositional Characterization(2016)Energy & Fuels, 30, 10 | |
| 21971
|
Trirahayu, DA; Abidin, AZ; Putra, RP; Putri, FD; Hidayat, AS; Perdana, MI Process Assessment of Integrated Hydrogen Production from By-Products of Cottonseed Oil-Based Biodiesel as a Circular Economy Approach(2023)Hydrogen, 4.0, 2 | |
| 29768
|
Khodadadi, MR; Malpartida, I; Tsang, CW; Lin, CSK; Len, C Recent advances on the catalytic conversion of waste cooking oil(2020) | |
| 16830
|
Varma, P; Otageri, J; Kandasubramanian, B Biodiesel from fats: Fatty acid feedstock as a circular economy solution(2024)International Journal Of Green Energy, 21, 11 | |
| 22315
|
Nogales-Delgado, S; Encinar, JM; Gonzalez, JF; Kim, J A Review on Biolubricants Based on Vegetable Oils through Transesterification and the Role of Catalysts: Current Status and Future Trends(2023)Catalysts, 13.0, 9 | |
| 27412
|
Di Fraia, S; Massarotti, N; Prati, MV; Vanoli, L A new example of circular economy: Waste vegetable oil for cogeneration in wastewater treatment plants(2020) |