Dr. José Miguel Hidalgo Herrador
- josemiguel.hidalgoherrador@upce.cz
- 466 037 128
-
Fakulta chemicko-technologická
Oddělení chemického inženýrství (30351)Odborný asistent -
- Výuka, rozvrh, termíny
- Odborný profil
Vzdělání a akademická kvalifikace
Přehled zaměstnání
Členství
Doplňující informace
José Miguel Hidalgo Herrador (0000-0002-5397-1578) - ORC
Publications from 2020 to 2024
1. Frątczak J, Górska J, Babor M, Gholami Z, Hidalgo Herrador JM, de Paz Carmona H. Production of Transportation Fuels from Fischer–Tropsch Waxes: Distillation, Blending, and Hydrocracking. Applied Sciences. 2024 May;14(11):4656.
2. Hidalgo Herrador JM, Babor M, Tomar R, Tišler Z, Hubáček J, de Paz Carmona H, et al. Polypropylene and rendering fat degrading to value-added chemicals by direct liquefaction and fast-pyrolysis. Biomass Conv Bioref. 2024 Jan 1;14(1):1027–36.
3. de Paz Carmona H, Kocík J, Hidalgo Herrador JM, Vráblík A. Effectiveness of Mo, NiMo, and CoMo catalysts for co-hydroprocessing furfural-acetone aldol condensation adducts with atmospheric gas oil to produce biofuels. Fuel. 2024 Jan;355:129489.
4. Babor M, Tišler Z, Matějíčková R, Peroutková K, Hidalgo Herrador JM. Liquefaction of Waste Rendering Fat Using Iron-Containing Catalysts. Chemical Engineering & Technology. 2023;46(6):1089–97.
5. Herrador JMH, Babor M, Brablíková M, Moghaddam MA, Vráblík A. Industrial sewage sludge direct liquefaction co-processing with tetralin or light cycle oil. Molecular Catalysis. 2022 Nov;532:112697.
6. Vráblík A, Schlehofer D, Jaklová KD, Herrador JMH, Černý R. Comparative Study of Light Cycle Oil and Naphthalene as an Adequate Additive to Improve the Stability of Marine Fuels. ACS Omega [Internet]. 2022 Jan; Available from: https://doi.org/10.1021%2Facsomega.1c05660
7. Hidalgo Herrador JM, Murat M, Tišler Z, Frątczak J, de Paz Carmona H. Direct Polypropylene and Polyethylene Liquefaction in CO2 and N2 Atmospheres Using MgO Light and CaO as Catalysts. Materials. 2022 Jan;15(3):844.
8. de Paz Carmona H, Frątczak J, Tišler Z, Hidalgo Herrador JM. Phonolite Material as Catalyst Support for the Hydrotreatment of Gas Oil and Vegetable Oil Type Feedstocks. Materials. 2022 Jan;15(1):386.
9. Frątczak J, Sharkov N, De Paz Carmona H, Tišler Z, Hidalgo-Herrador JM. Cleaner Fuel Production via Co-Processing of Vacuum Gas Oil with Rapeseed Oil Using a Novel NiW/Acid-Modified Phonolite Catalyst. Energies. 2021 Dec;14(24):8497.
10. Frątczak J, de Paz Carmona H, Tišler Z, Hidalgo Herrador JM, Gholami Z. Hydrocracking of Heavy Fischer–Tropsch Wax Distillation Residues and Its Blends with Vacuum Gas Oil Using Phonolite-Based Catalysts. Molecules. 2021 Nov;26(23):7172.
11. Herrador JMH, Tišler Z, Kocík J, Fratcząk J, Hradecká I, Velvarská R, et al. Mesityl Oxide Reduction by Using Acid-Modified Phonolite Supported NiW, NiMo, and CoMo Catalysts. Catalysts. 2021 Sep;11(9):1101.
12. Gómez-López P, Murat M, Hidalgo-Herrador JM, Carrillo-Carrión C, Balu AM, Luque R, et al. Mechanochemical Synthesis of Nickel-Modified Metal–Organic Frameworks for Reduction Reactions. Catalysts. 2021 Apr;11(5):526.
13. Murat M, Gholami Z, Šimek J, Rodríguez-Padrón D, Hidalgo-Herrador JM. Rendering Fat and Heavy Fischer-Tropsch Waxes Mixtures (0–100%) Fast Pyrolysis Tests for the Production of Ethylene and Propylene. Processes. 2021 Feb;9(2):367.
14. Carmona H de P, Vráblík A, Herrador JMH, Velvarská R, Černý R. Animal fats as a suitable feedstock for co-processing with atmospheric gas oil. Sustainable Energy & Fuels [Internet]. 2021; Available from: https://doi.org/10.1039%2Fd1se00917f
15. Velvarská R, Vráblík A, Hidalgo-Herrador JM, Černý R. Near-infrared spectroscopy to determine cold-flow improver concentrations in diesel fuel. Infrared Physics & Technology. 2020 Nov;110:103445.
16. Velvarská R, Tišler Z, Raichlová V, Hidalgo-Herrador JM. Raman Spectroscopy as Molybdenum and Tungsten Content Analysis Tool for Mesoporous Silica and Beta Zeolite Catalysts. Molecules. 2020 Oct;25(21):4918.
17. Huang Y, Rolfe A, Rezvani S, Herrador JMH, Franco F, Pinto F, et al. Converting brown coal to synthetic liquid fuels through direct coal liquefaction technology: <scp>Techno‐economic</scp> evaluation. International Journal of Energy Research. 2020 Aug;44(14):11827–39.
18. Hidalgo-Herrador JM, Frątczak J, Velvarská R, de Paz Carmona H. Oxalic acid-mediated catalytic transfer hydrodeoxygenation of waste cooking oil. Molecular Catalysis. 2020 Aug;491:110973.
19. Herrador JMH, Fratczak J, Tišler Z, Carmona H de P, Velvarská R. Oxalic Acid as a Hydrogen Donor for the Hydrodesulfurization of Gas Oil and Deoxygenation of Rapeseed Oil Using Phonolite-Based Catalysts. Molecules. 2020 Aug;25(16):3732.
20. Murat M, Tišler Z, Šimek J, Hidalgo-Herrador JM. Highly Active Catalysts for the Dehydration of Isopropanol. Catalysts. 2020 Jun;10(6):719.
21. Murat M, Lederer J, Rodová A, Hidalgo Herrador JM. Hydrodeoxygenation and pyrolysis of free fatty acids obtained from waste rendering fat. Eclética Química Journal. 2020 Jun;45(3):28–36.
22. Pinto F, Hidalgo-Herrador JM, Paradela F, Costa P, André R, Fratczak J, et al. Coal and waste direct liquefaction, using glycerol, polyethylene waste and waste tyres pyrolysis oil. Optimisation of liquids yield by response surface methodology. Journal of Cleaner Production. 2020 May;255:120192.
23. Hidalgo JM, Paz Carmona H de, Fratczak J. 7. Bio-waste and petroleum fractions coprocessing to fuels. In: Biomass and Biowaste [Internet]. De Gruyter; 2020. p. 167–78. Available from: http://dx.doi.org/10.1515/9783110538151-007
24. Velvarská R, Vráblík A, Hidalgo-Herrador JM, ?ern? R. Near-infrared spectroscopy to determine cold-flow improver concentrations in diesel fuel. Infrared Physics and Technology. 2020;110.