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• W4384069632 abstract "Free Access Frontmatter Book Editor(s):Martin Bajus, Martin Bajus Slovak University of TechnologySearch for more papers by this author First published: 12 July 2023 https://doi.org/10.1002/9781394185771.fmatter AboutPDFPDF ToolsRequest permissionExport citationAdd to favoritesTrack citation ShareShareShare a linkShare onEmailFacebookTwitterLinkedInRedditWechat General Literature Aadnoy , B. and Looye , R. ( 2019 ). Petroleum Rock Mechanics Drilling Operations and Well Design . Gulf Professional Publishing . Abdel-Aal , H.K. and Alsahlawi , M.A. ( 2013 ). Petroleum Economics and Engineering , 3e . CRC Press . Aguado , J. and Serrano , D. ( 1999 ). Feedstock Recycling of Plastic Wastes (ed. J.H. Clark ). RSC Clean Technology Monographs, Royal Society of Chemistry, Cambridge, UK. Albright , L.F. , Crynes , B.L. , and Corcoran , W.H. ( 1983 ). Pyrolysis: Theory and Industrial Practice . New York : Academic Press . Arpe , H. ( 2010 ). Industrial Organic Chemicals , 5e . New York : Wiley . Arpentinier , P. , Cavani , F. , and Trifiro , F. ( 2001 ). The Technology of Catalytic Oxidation, 1. Chemical, Catalytic & Engineering Aspects . Paris : Editions TECHNIP . Arpentinier , P. , Cavani , F. , and Trifiro , F. ( 2001 ). The Technology of Catalytic Oxidation, 2. Safety Aspects . Paris : Editions TECHNIP . Austin , G.T. ( 1984 ). Shreve's Chemical Process Industries , 5e . New York : McGraw Hill Book Company . Bajus , M. ( 1987 ). Thermal conversion of petroleum hydrocarbons into petrochemicals . D.Sc Thesis, Slovak University of Technology in Bratislava, Faculty of Chemical and Food Technology , Bratislava, Slovak Republic . Bajus , M. ( 1989 ). Sulfur Reports, Volume 9 (1), Sulfur Compounds in Hydrocarbon Pyrolysis . Glasgow, UK : Harwood Academic Publishers , 25 – 71 . Bajus , M. ( 1996 ). Alternatívne palivá, interné skripá Katedry technológie ropy a petrochémie . Bratislava : FCHPT-STU . Bajus , M. ( 2002a ). Organická technológia a petrochémia, Uhľovodíkové technológie . Vydavateľstvo STU , 178 s., Bratislava . Bajus , M. ( 2002b ). Organická technológia a petrochémia, Uhľovodíkové technológie . Elektronická CD učebnica, Vydavateľstvo DIVYD , Bratislava . Bajus , M. ( 2017 ). Petrochemistry: Hydrocarbon Technology . Editions, Slovak University of Technology, Faculty of Chemical & Food Technology, Slovak Chemical Library . Bajus , M. ( 2019 ). Chemické procesy v organickej technológii a petrochémii, e-Učebnica, Vydavateľsto Spektrum STU , Bratislava . Bajus , M. ( 2020 ). Petrochemistry: Petrochemical Processing, Hydrocarbon Technology, and Green Engineering . Chichester : Wiley . Bajus , M. , Buláková , Ľ. et al. ( 2006 ). 150 rokov plynárenstva na Slovensku . Vydal Slovenský plynárenský a naftový zväz , Bratislava . Bajus , M. , Lederer , J. , and Bělohlav , Z. ( 2016 ). Plenary lecture: hydrocarbon technology, trends and outlook in petrochemistry. 4th International Conference on Chemical Technology , 87 . Mikulov, Czech Republic . Banerjee , D. ( 2020 ). Thermal Processing of Hydrocarbons to Petrochemicals . PennWell Books . Bazzanella , A.M. and Ausfelder , F. ( 2017 ). Technology study: low carbon energy and feedstock for the European chemical industry . Dechema Gesellschaft fur Chemische Technik und Biotechnology e.V., Cefic . A. Bisio and S. Boots (eds.) ( 1995 ). Encyclopaedia of Energy Technology and the Environment, Volume 1–4 . Chichester : Wiley . K. Boodhoo and A. Harvey (eds.) ( 2013 ). Process Intensification Technologies for Green Chemistry: Engineering Solutions for Sustainable Chemical Processing . Wiley . BP statistical review of world energy . ( 2022 ). 1922–2018. bp.com/statisticalreview . R.C. Braun (ed.) ( 2011 ). Thermochemical Processing of Biomass, Conversion into Fuels, Chemicals and Power . Chichester : Wiley . Burnham , A.K. ( 2017 ). Global Chemical Kinetics of Fossil Fuels . Springer . Cenka , M. et al. ( 2001 ). Obnovitelné zdroje energie . Praha : FCC Public . Centi , G. , Cavani , F. , and Trifiró , F. ( 2001 ). Fundamental and applied catalysis . In: Selective Oxidation by Heterogeneous Catalysis (ed. M.V. Twigg and M. Spencer ). New York : Kluwer Academic/Plenum Publishers . Červený , L. , a koklektív . ( 1995 ). Zakladní pochody prumyslové organickej syntézy . Bratislava : STU . Comyns , A.E. ( 1999 ). Encyclopedic Dictionary of Named Processes in Chemical Technology , 2e . Boca Raton, London : CRC Press . Corma , A. and Martinez , A. ( 2002 ). Catalysis on Porous Solids . In: Handbook of Porous Solids (ed. F. Schutz , K.S.W. Sing , and J. Wetkamp ). Weinheim : Wiley-VCH . Cutler , J.C. (Editor-in-Chief) ( 2004 ). Encyclopaedia of Energy, Volume 1-6 . San Diego, CA : Elsevier Inc., Academic Press . R.A. Dawe (ed.) ( 2000 ). Modern Petroleum Technology, Vol. 1, Upstream , 6e . Chichester : Wiley . Devins , D. ( 1982 ). Energy, Its Physical Impact on the Environment . New York : Wiley . Ehrfeld , W. , Hessel , V. , and Loewe , H. ( 2000 ). Microreactors-New Technology for Modern Chemistry . Weinheim : Wiley-VCH , 9 . El-Gendy , L.S. ( 2018 ). Biodesulfurization in Petroleum Refining . Scrivener Publishing/Wiley . J.P. Favennec (ed.) ( 2001 ). Petroleum Refining, 5. Refinery Operation and Management . Paris : Editions TECHNIP . Fink , J. ( 2015 ). Petroleum Engineer's Guide to Oil and Fluids , 2e . Oxford : Gulf Professional Publishing, Elsevier . Furimsky , E. ( 2020 ). CO 2 hydrogenation to methanol and methane over carbon-supported catalysts . Ind. Eng. Chem. Res . 59 ( 35 ): 15393–15423 . Germain , J.E. ( 1969 ). Catalytic Conversion of Hydrocarbons . London and New York : Academic Press . Goyal , M.R. , Kumar , A. , and Gupta , A.K. ( 2018 ). Novel Dairy Processing Technologies: Techniques, Management, and Energy Conservation . Oakville, Canada : Apple Academic Press, Inc . Harker , J.H. and Backhurst , J.R. ( 1981 ). Fuel and Energy . London : Academic Press . Hoogers , G. ( 2003 ). Fuel Cell Technology Handbook . New York : CRC Press . Hougen , O.A. and Watson , K.M. ( 1947 ). Chemical Process Principles , vol. 3 . New York : Wiley . Ch. Hsu and P.R. Robinson (eds.) ( 2017 ). Springer Handbook of Petroleum Technology . Cham : Springer International Publishing AG . Hsu , C.S. and Robinson , P.R. ( 2019 ). Petroleum Science and Technology . Cham : Springer . Humphrey , J.L. and Keller , G.L. ( 1997 ). Separation Process Technology . New York : McGraw-Hill . Iglesia , E. , Spivey , J.J. , and Fleisch , T.H. ( 2001 ). Natural Gas Conversion VI , vol. 136, Amsterdam : Elsevier . Ince , A.C. , Colpan , C.O. , Hagen , A. , and Serincan , M.F. ( 2021 ). Modelling and Simulation of Power-to-X systems: a review . Fuel 304 : 121354 . D.S.J. Jones and P. Pujado (eds.) ( 2006 ). Handbook of Chemical Processing . Dordrecht : Springer . Ke , L. , Chunshan , S. , and Velu , S. ( 2010 ). Hydrogen and Syngas Production and Purification Technologies . Hoboken, New York : AIChe, Wiley . Kelland , M.A. ( 2014 ). Production Chemicals from the Oil and Gas Industry . Boca Raton : CRC Press . Kiss , A.A. ( 2014 ). Process Intensification Technologies for Biodiesel Production: Reactive Separation Processes . Springer Briefs in Applied Sciences and Technology, Cham : Springer . Kizlink , J. ( 2011 ). Technologie chemických látek a jejich použití , 4. přepracované a doplneněné vydání, vydavatelství: VUTIUM . Lee , S. ( 2012 ). Biofuels and Bioenergy . Boca Raton : CRC Press . P. Leprince (ed.) ( 1995 ). Petroleum Refining, 3. Conversion Process . Paris : Editions TECHNIP . (1995). A.G. Lucas (ed.) ( 2000 ). Modern Petroleum Technology, Vol. 2, Downstream , 6e . Chichester : Wiley . Luque , R. and Balu , A.M. (eds.) ( 2013 ). Producing Fuels and Fine Chemicals from Biomass Using Nanomaterials . Boca Raton : CRC Press . Luque , R. and Leung-Yuk Lam , F. ( 2018 ). Substainable Catalysis: Energy-Efficient Reactions and Applications . Weinheim : Wiley-VCH . Maxwell , I.E. and Stork , W.H.J. ( 2001 ). Hydrocarbon processing with zeolites . In: Introduction to Zeolite Science and Practise , vol. 137 , 2e (eds. H. Bekkum , E.M. Flamigen , P.A. Jacobs , and J.C. Jansen ). Amsterdam : Elsevier . Marko , Š. , a ďalší . ( 1988 ). Energetické zdroje a premeny . Bratislava : Alfa . Meyers , R.A. ( 2005 ). Handbook of Petrochemicals Production Processes . New York : McGraw-Hill . Meyers , R.A. ( 2018 ). Handbook of Petrochemicals Production , 2e . New York : McGraw Hill . Minteer , S. ( 2006 ). Alcoholic Fuels . Boca Raton : CRC Press . Moulijn , J.A. , Makkee , M. , and Van Diepen , A. ( 2005 ). Chemical Process Technology . Chichester : Wiley . Noronha , F.B. , Schmal , M. , and Sousa-Aguiar , E.F. ( 2007 ). Natural Gas Conversion VIII , vol. 167 . Amsterdam : Elsevier . Olah , G.A. and Molnar , A. ( 1995 ). Hydrocarbons Chemistry . New York : Wiley . Olivé , G.H. and Olivé , S. ( 1984 ). The Chemistry of the Catalyzed Hydrogenation of Carbon Monoxide . Berlin, Heidelberg : Springer-Verlag . A. Parmaliana , D. Sanfilippo , F. Frusteri , A. Vaccari and F. Arena (eds.) ( 1998 ). Natural Gas Conversion V , vol. 119, Amsterdam : Elsevier . Pašek , J. ( 1996 ). Uhlíkaté suroviny . Praha : VŠCHT . Pastorek , Z. , Kára , J. , and Jevič , P. ( 2004 ). Biomasa obnovitelný zdroj energie . Praha : FCC Public . Pasupathi , S. , Gomez , J.C.C. , Su , H. et al. ( 2016 ). Recent Advances in High-temperature PEM Fuel Cells . London : Academic Press . Pines , H. ( 1981 ). The Chemistry of Catalytic Hydrocarbon Reactios . London : Academic Press . Roberts , P. ( 2019 ). A Dictionary of Oil & Gas Industry Terms . Oxford : Oxford University Press . Rojey , A. , Jaffret , C. , Cornot-Gandolphe , S. , and Durand , B. ( 1997 ). Natural Gas Production Processing Transport . Paris : Editions TECHNIP . F. Rossillo-Calle , P. Groot , and S.L. Hemstock (eds.) ( 2007 ). The Biomass Assessment Handbook, Bioenergy for a Sustainable Environment . London : Earthscan . Sabu , T. ( 2014 ). Biomaterial Applications: Micro to Nanoscales . Boca Raton : CRC Press . Sánchez-Bastardo , N. , Schlögl , R. , and Holger Ruland , H. ( 2021 ). Methane pyrolysis for zero-emission hydrogen production: a potential bridge technology from fossil fuels to a renewable and sustainable hydrogen economy . Ind. Eng. Chem. Res . 60 ( 32 ): 11855 – 11881 . Shah , Y.T. ( 2014 ). Water for Energy and Fuel Production . Boca Raton : CRC Press . Sheldon , R.A. ( 1982 ). Chemicals from Synthesis Gas . Dordrecht : D. Reidel Publishing Company . F. Shi (ed.) ( 2014 ). Reactor and Process Design in Sustainable Energy Technology . Amsterdam : Elsevier . Shukla , A.K. and Marchesini , F.H. ( 2017 ). Analytical Characterization Methods for Crude and Relative Products . Weinheim : Wiley-VCH . Skrzypek , J. , Sloczynski , J. , and Ledakowicz , S. ( 1994 ). Methanol Synthesis . Waszawa : Polish Scientific Publishers PWN . Smil , V. ( 2003 ). Energy at the Crossroads . Cambridge (MA) : The MIT Press . Soni , V.K. , Singh , G. , Vijayan , B.K. et al. ( 2021 ). Thermochemical recycling of waste plastics by pyrolysis: a review . Energy Fuels 35 : 12763 – 12808 . Sorensen , B. ( 2000 ). Renewable Energy . Boston : Academic Press . Sorensen , B. ( 2005 ). Hydrogen and Fuel Cells, Emerging Technologies and Applications . London : Academic Press . Spath , P.L. and Dayton , D.C. ( 2003 ). Prelimanary screening – technical and economic assessment of synthesis gas to fuels and chemicals with emphasis on the potential for biomas – derived syngas . ADA 436529/NREL/tp-510 – 34929. Speight , J.G. ( 2011 ). Handbook of Industrial Hydrocarbon Processes , 1e . Burlington : Elsevier . Speight , J.G. ( 2014 ). The Chemistry and Technology of Petroleum , 5e . Boca Raton : CRC Press . Speight , J.G. ( 2017 ). Rules of Thumb for Petroleum Engineers . Hoboken : Scrivener Publishing/Wiley . Spitz , H.P. ( 1988 ). Petrochemicals, The Rise of an Industry . Hoboken : Wiley . Stocchi , E. ( 1999 ). Industrial Chemistry , vol. 1 . New York : Ellis Horwood Limited . Stolten , D. and Emonts , B. ( 2016 ). Hydrogen Science and Engineering: Materials, Processes, Systems and Technology . Weinheim : Wiley-VCH . Surový , J. ( 1991 ). Chemicko-inžinierska termodynamika . Bratislava : Alfa . Syad , A.M. ( 2015 ). Fundamentals of Heat Exchanger Design . London : LAP Lambert Academic Publishing . Sylvester , E. ( 2010 ). Course: chemical technology (organic) . Module VII., Lecture 2. https://www.academia.edu/33302746/Course_Chemical_Technology_Organic_Module_VII_Lecture_7_Aromatic_Production . P. Trambouze (ed.) ( 2000 ). Petroleum Refining, 4. Materials and Equipment . Paris : Editions TECHNIP . S.A. Treese , P.R. Pujado , and D.S. Janes (eds.) ( 2015 ). Handbook of Petroleum Processing , 2e . Berlin : Springer-Verlag . Uner , D. ( 2017 ). Advances in Refining Catalysis, (Chemical Industries) , 1e . Boca Raton : CRC Press . R.A. Santen , P.W.N.M. Leeuwen , J.A. Mouljin and B.A. Averill (eds.) ( 1999 ). Catalysis: An Integrated Approach Vol. 123 , 2e . Elsevier . Varfolomeev , S.D. ( 2014 ). Chemical and Biochemical Technology: Material and Processing . Boca Raton : CRC Press . Vasconcelos , B.R. and Lavoie , J.-M. ( 2019 ). Recent advances in power-to-X technology for the production of fuels and chemicals . Front. Chem . 7 . A.A. Vertes , N. Qureshi , H.P. Blaschek , and H. Yukawa (eds.) ( 2010 ). Biomass to Biofuels, Strategies for Global Industries . Chichester : Wiley . Veselý , V. , Mostecký , J. , Bajus , M. et al. ( 1989 ). Petrochémia, Alfa Bratislava , 678 . Vision 2050 ( 2018 ). A pathway for the evolution of the refining industry and liquid fuels . Fuels Europe. J.-P. Wauquier (ed.) ( 1995 ). Petroleum Refining, 1. Crude Oil, Petroleum Process Flowsheets . Paris : Editions TECHNIP . J.-P. Wauquier (ed.) ( 2000 ). Petroleum Refining, 2. Separation Processes . Paris : Editions TECHNIP . Wikipedia, The Free Encyclopedia . https://en.wikipedia.org/wiki/Petrochemical . F. Winter , A. Avinash , J. Hrdlička , and S. Varjani (eds.) ( 2019 ). CO 2 Separation, Purification to Chemicals and Fuels . Singapore : Springer Nature . Wittcoff , H.A. and Reuben , B.G. ( 1980 ). Industrial Organic Chemicals in Perspective, Part One: Raw Materials and Manufacture . New York : Wiley . Wittcoff , H.A. and Reuben , B.G. ( 1996 ). Industrial Organic Chemicals . New York : Wiley . Wittcoff , H.A. , Reuben , B.G. , and Plotkin , J.S. ( 2013 ). Industrial Organic Chemicals , 3e . New York : Wiley . Wohlleben , W. ( 2015 ). Safety of Nanomaterials along Their Lifecycle . Boca Raton : CRC Press . Zangeneh , F.T. , Sahebdelfar , S. , and Ravanchi , M.R. ( 2011 ). Conversion of carbon dioxide to valuable petrochemicals: an approach to clean development mechanism . J. Nat. Gas Chem . 20 : 219 – 231 . Zhu , F. (Xin X.). ( 2019 ). Efficient Petrochemical Processes, Technology, Design and Operation . Hoboken : Wiley . Converting Power into Chemicals and Fuels: Power‐to‐X Technology for a Sustainable Future ReferencesRelatedInformation" @default.
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