This work is licensed under the Creative Commons Attribution-NonCommercial-NoDerivatives 3.0 License.
ABDELGHAFFAR A.W. 2010. Spark ignition engine fueled by Hydrogen: Comparative analysis. European Journal of Scientific Research 44: 13–28.ABDELGHAFFARA.W.2010Spark ignition engine fueled by Hydrogen: Comparative analysis441328Search in Google Scholar
AL-BAGHDADI M. 2020. An overview of hydrogen as an alternative fuel. Encyclopedia 2020. https://encyclopedia.pub/revision/9798/v1 (accessed on 12 June 2021).AL-BAGHDADIM.2020An overview of hydrogen as an alternative fuelhttps://encyclopedia.pub/revision/9798/v1 (accessed on 12 June 2021).Search in Google Scholar
BARAŃSKA K., PETELSKI Ł. 2022. Czy wodór zastąpi w przyszłości benzynę? Nowa Energia nr 1(82).BARAŃSKAK.PETELSKIŁ.2022Czy wodór zastąpi w przyszłości benzynę?nr 1(82).Search in Google Scholar
BOGUCKA M., PIKOŃ K. Współczesne problemy ochrony środowiska i energetyki 2019. Politechnika Śląska 2020.BOGUCKAM.PIKOŃK.Współczesne problemy ochrony środowiska i energetyki 2019Search in Google Scholar
BORETTI A. 2019. Transient positive ignition internal combustion engines have now surpassed the 50% fuel conversion efficiency barrier. Int. J. Hydrogen Energy 44: 7051–7052.BORETTIA.2019Transient positive ignition internal combustion engines have now surpassed the 50% fuel conversion efficiency barrier4470517052Search in Google Scholar
BRZEŻAŃSKI M., CISEK J., MAREK W., PAPUGA T. 2013. Investigation of the combustion engine fuelled with hydrogen. Combustion Engines 154(3): 1042–1048. ISSN 0138-0346.BRZEŻAŃSKIM.CISEKJ.MAREKW.PAPUGAT.2013Investigation of the combustion engine fuelled with hydrogen154310421048ISSN 0138-0346.Search in Google Scholar
BRZEŻAŃSKI M., RODAK L. 2019. Influence of the method of creating a hydrogen-air mixture on the emission of nitrogen oxides in a spark-ignition engine. Combustion Engines 178(3): 224–227. doi: 10.19206/CE-2019-339BRZEŻAŃSKIM.RODAKL.2019Influence of the method of creating a hydrogen-air mixture on the emission of nitrogen oxides in a spark-ignition engine178322422710.19206/CE-2019-339Open DOISearch in Google Scholar
BRZEŻAŃSKI M., RODAK L. 2019. Investigation of a new concept of hydrogen supply for a spark ignition engine. Combustion Engines 178(3): 140–143. doi: 10.19206/CE-2019-324BRZEŻAŃSKIM.RODAKL.2019Investigation of a new concept of hydrogen supply for a spark ignition engine178314014310.19206/CE-2019-324Open DOISearch in Google Scholar
CINIVIZ M., KOSE H. 2012. Hydrogen use in internal combustion engine: a review. International Journal of Automotive Engineering and Technologies 1: 1–15. 7CINIVIZM.KOSEH.2012Hydrogen use in internal combustion engine: a review1115. 7Search in Google Scholar
DAS M. L. 2002. Hydrogen engine: research and development (R&D) programmers in Indian Institute of Technology (IIT), Delhi. International Journal of Hydrogen Energy 27: 953–965.DASM. L.2002Hydrogen engine: research and development (R&D) programmers in Indian Institute of Technology (IIT), Delhi27953965Search in Google Scholar
DASZKIEWICZ P., IDZIOR M., BAJERLEIN M., KARPIUK W. 2013. Perspektywa progresu wskaźników ekologicznych silnika badawczego zasilanego olejem napędowym z domieszką wodoru. TTS 10.DASZKIEWICZP.IDZIORM.BAJERLEINM.KARPIUKW.2013Search in Google Scholar
DIMITRIOU P., TSUJIMURA T. 2017. A review of hydrogen as a compression ignition engine fuel. Int. J. Hydrogen Energy 42: 24470–24486.DIMITRIOUP.TSUJIMURAT.2017A review of hydrogen as a compression ignition engine fuel422447024486Search in Google Scholar
EICHLSEDER H., WALLNER T., FREYMANN R., RINGLER J. 2003. The potential of hydrogen internal combustion engines in a future mobility scenario. Warrendale, PA, USA: SAE International.EICHLSEDERH.WALLNERT.FREYMANNR.RINGLERJ.2003Warrendale, PA, USASAE InternationalSearch in Google Scholar
FAIZAL M., CHUAH L.S., LEE C., HAMEED A., LEE J., SHANKAR M. 2019. Review of hydrogen fuel for internal combustion engines. J. Mech. Eng. Res. Dev. (JMERD) 42: 35–46.FAIZALM.CHUAHL.S.LEEC.HAMEEDA.LEEJ.SHANKARM.2019Review of hydrogen fuel for internal combustion engines423546Search in Google Scholar
FOLENTARSKA A., KULAWIK D., CIESIELSKI W., PAVLYUK V. 2016. Nowoczesne materiały do przechowywania wodoru jako paliwa przyszłości. Częstochowa 2016r.FOLENTARSKAA.KULAWIKD.CIESIELSKIW.PAVLYUKV.2016Nowoczesne materiały do przechowywania wodoru jako paliwa przyszłościSearch in Google Scholar
GRAFF M. 2020. Wodór jako paliwo – zalety i wady, TTS Technika Transportu Szynowego, Instytut Naukowo-Wydawniczy „TTS” Sp. z o.o, 2020, s. 18; Auto Świat. https://www.auto-swiat.pl/wiadomosci/aktualnosci/wodor-paliwo-przyszlosci-bez-przyszlosci/nt6jx7h.GRAFFM.2020https://www.auto-swiat.pl/wiadomosci/aktualnosci/wodor-paliwo-przyszlosci-bez-przyszlosci/nt6jx7h.Search in Google Scholar
GUPTA B. R 2008. Hydrogen fuel production, transport and storage. CRC Press: 1–603. ISBN 978-1-4200-4575-8.GUPTAB. R2008CRC Press1603ISBN 978-1-4200-4575-8.Search in Google Scholar
HEINDL R., EICHLSEDER H., SPULLER C., GERBIG F., HELLER K. 2009. New and innovative combustion systems for the H2-ICE: compression ignition and combined processes. Warrendale, PA, USA: SAE International; SAE paper no. 2009-01-1421.HEINDLR.EICHLSEDERH.SPULLERC.GERBIGF.HELLERK.2009Warrendale, PA, USASAE InternationalSAE paper no. 2009-01-1421.Search in Google Scholar
HORVÁTH J., SZEMESOVÁ J. 2023. Is a carbon-neutral pathway in road transport possible? A case study from Slovakia. Sustainability 15(16): 12246. https://doi.org/10.3390/su151612246HORVÁTHJ.SZEMESOVÁJ.2023Is a carbon-neutral pathway in road transport possible? A case study from Slovakia151612246https://doi.org/10.3390/su151612246Search in Google Scholar
HUANG Z., WANG J., LIU B., ZENG K., YU J., JIANG D. 2006. Combustion characteristics of a direct-injection engine fueled with natural gas-hydrogen mixtures. Energy & Fuels 20: 540–546.HUANGZ.WANGJ.LIUB.ZENGK.YUJ.JIANGD.2006Combustion characteristics of a direct-injection engine fueled with natural gas-hydrogen mixtures20540546Search in Google Scholar
IDZIOR M., BAJERLEIN M., BIELIŃSKI M., DASZKIEWICZ M., STOBNICKI P. 2013r. Badanie wpływu dodatku wodoru do kolektora dolotowego na emisję zanieczyszczeń stacjonarnego silnika spalinowego z bezpośrednim wtryskiem. PTNSS–2013r–SC–133.IDZIORM.BAJERLEINM.BIELIŃSKIM.DASZKIEWICZM.STOBNICKIP.2013rPTNSS–2013r–SC–133.Search in Google Scholar
KAWAMURA A., SATO Y., NAGANUMA K., YAMANE K., TAKAGI Y. 2010. Development project of a multi-cylinder DISI hydrogen ICE System for heavy duty vehicles. Warrendale, PA, USA: SAE International; SAE paper no. 2010-01-2175.KAWAMURAA.SATOY.NAGANUMAK.YAMANEK.TAKAGIY.2010Warrendale, PA, USASAE InternationalSAE paper no. 2010-01-2175.Search in Google Scholar
KAWAMURA A., YANAI T., SATO Y., NAGANUMA K., YAMANE K., TAKAGI Y. 2009. Summary and progress of the hydrogen ICE truck development project. Warrendale, PA, USA: SAE International; SAE paper no. 2009-01-1922.KAWAMURAA.YANAIT.SATOY.NAGANUMAK.YAMANEK.TAKAGIY.2009Warrendale, PA, USASAE InternationalSAE paper no. 2009-01-1922.Search in Google Scholar
KORAKIANITIS T., NAMASIVAYAM M. A., CROOKES J. R. 2010. Hydrogen dual-fuelling of compression ignition engines with emulsified biodiesel as pilot fuel. International Journal Of Hydrogen Energy 35: 13329–13344KORAKIANITIST.NAMASIVAYAMM. A.CROOKESJ. R.2010Hydrogen dual-fuelling of compression ignition engines with emulsified biodiesel as pilot fuel351332913344Search in Google Scholar
KRUCZYŃSKI A., ŚLIĘZAK M., GIS W., ORLIŃSKI P. Ocena wpływu spalania dodatku wodoru na własności eksploatacyjne silnika o zapłonie samoczynnym. Instytut Pojazdów Politechniki Warszawskiej, Instytut Transportu Samochodowego.KRUCZYŃSKIA.ŚLIĘZAKM.GISW.ORLIŃSKIP.Instytut Pojazdów Politechniki Warszawskiej, Instytut Transportu SamochodowegoSearch in Google Scholar
LEVCHENKO R. 2021. Technologie przyszłości – wodór. Archiwum Wiedzy Inżynierskiej. Tom 6(6): 43–47.LEVCHENKOR.2021Technologie przyszłości – wodór. Archiwum Wiedzy Inżynierskiej664347Search in Google Scholar
MARSZAŁEK N. 2019. Wodór jako paliwo alternatywne dla transportu lotniczego. Autobusy 12.MARSZAŁEKN.2019Wodór jako paliwo alternatywne dla transportu lotniczego12Search in Google Scholar
MINISTRY OF CLIMATE AND ENVIRONMENT. 2021. Polish hydrogen strategy until 2030 with an outlook until 2040. 21 Warsaw. https://www.gov.pl/web/klimat/polska-strategia-wodorowa-do-roku-2030MINISTRY OF CLIMATE AND ENVIRONMENT202121 Warsaw. https://www.gov.pl/web/klimat/polska-strategia-wodorowa-do-roku-2030Search in Google Scholar
SARAVANAN N., NAGARAJAN G. 2010. Performance and emission studies on port injection of hydrogen with varied flow rates with Diesel as an ignition source. Applied Energy 87: 2218–2229SARAVANANN.NAGARAJANG.2010Performance and emission studies on port injection of hydrogen with varied flow rates with Diesel as an ignition source8722182229Search in Google Scholar
SARAVANAN N., NAGARAJAN G. 2009. Performance and emission study in manifold hydrogen injection with diesel as an ignition source for different start of injection, Renewable Energy 34: 328–334.SARAVANANN.NAGARAJANG.2009Performance and emission study in manifold hydrogen injection with diesel as an ignition source for different start of injection34328334Search in Google Scholar
SARAVANAN N., NAGARAJAN G., SANJAY G., DHANASEKARAN C., KALAISELVAN M.K. 2008. Combustion analysis on a DI diesel engine with hydrogen in dual fuel mode. Fuel 87: 3591–3599.SARAVANANN.NAGARAJANG.SANJAYG.DHANASEKARANC.KALAISELVANM.K.2008Combustion analysis on a DI diesel engine with hydrogen in dual fuel mode8735913599Search in Google Scholar
STĘPIEŃ Z. 2021. A comprehensive overview of hydrogen-fueled internal combustion engines: achievements and future challenges. Energies 14(20): 6504. https://doi.org/10.3390/en14206504STĘPIEŃZ.2021A comprehensive overview of hydrogen-fueled internal combustion engines: achievements and future challenges14206504https://doi.org/10.3390/en14206504Search in Google Scholar
STĘPIEŃ Z., URZĘDOWSKA W. 2021. Tłokowe silniki spalinowe zasilane wodorem – wyzwania. Nafta-Gaz 2021r 12, s.: 830–840.STĘPIEŃZ.URZĘDOWSKAW.2021Nafta-Gaz 2021r 12, s.:830840Search in Google Scholar
SZAŁEK A., PIELECHA I., CIESLIK W. 2021. Fuel cell electric vehicle (FCEV) energy flow analysis in real driving conditions (RDC). Energies 14(16): 5018. https://doi.org/10.3390/en14165018SZAŁEKA.PIELECHAI.CIESLIKW.2021Fuel cell electric vehicle (FCEV) energy flow analysis in real driving conditions (RDC)14165018https://doi.org/10.3390/en14165018Search in Google Scholar
SZWAJA S., GRAB-ROGALINSKI K. 2009. Hydrogen combustion in a compression ignition diesel engine. International Journal of Hydrogen Energy 34: 4413–4421.SZWAJAS.GRAB-ROGALINSKIK.2009Hydrogen combustion in a compression ignition diesel engine3444134421Search in Google Scholar
TATAREWICZ I., SKWIERZ S., LEWARSKI M., JESZKE R., PYRKA M., SEKUŁA, M. 2023. Mapping the future of green hydrogen: Integrated analysis of Poland and the EU's development pathways to 2050. Energies 16: 6261. https://doi.org/10.3390/en16176261TATAREWICZI.SKWIERZS.LEWARSKIM.JESZKER.PYRKAM.SEKUŁAM.2023Mapping the future of green hydrogen: Integrated analysis of Poland and the EU's development pathways to 2050166261https://doi.org/10.3390/en16176261Search in Google Scholar
WAHAB ABD BIN ASWAD M. 2009. Addition of hydrogen to gasoline-fuelled 4 stroke SI engine using 1-dımensıonal analysis. Faculty of Mechanical Engineering University Malaysia Pahang: 1–68.WAHAB ABD BIN ASWAD M2009Faculty of Mechanical Engineering University Malaysia Pahang168Search in Google Scholar
WIĄCEK D. 2011r. Wodór jako paliwo przyszłości. Autobusy 10.WIĄCEKD.2011rAutobusy 10.Search in Google Scholar
EUROPEAN COMMISSION. 2020. A hydrogen strategy for climate-neutral Europe. Brussels. p. 8. https://knowledge4policy.ec.europa.eu/publication/communication-com2020301-hydrogen-strategy-climate-neutral-europe_enEUROPEAN COMMISSION2020Brussels8https://knowledge4policy.ec.europa.eu/publication/communication-com2020301-hydrogen-strategy-climate-neutral-europe_enSearch in Google Scholar
EUROPEAN COMMISSION. 2019. Clean energy for all Europeans package. https://energy.ec.europa.eu/topics/energy-strategy/clean-energy-all-europeans-package_enEUROPEAN COMMISSION2019https://energy.ec.europa.eu/topics/energy-strategy/clean-energy-all-europeans-package_enSearch in Google Scholar
EUROPEAN COMMISSION. 2021. Fit for 55. https://eur-lex.europa.eu/legal-content/EN/TXT/PDF/?uri=CELEX:52021DC0550EUROPEAN COMMISSION2021https://eur-lex.europa.eu/legal-content/EN/TXT/PDF/?uri=CELEX:52021DC0550Search in Google Scholar
EUROPEAN COMMISSION. 2021. Fit for 55: Delivering the EU's 2030 climate target on the way to climate neutrality. Brussels. https://eur-lex.europa.eu/legal-content/EN/TXT/?uri=CELEX%3A52021DC0550EUROPEAN COMMISSION2021Brusselshttps://eur-lex.europa.eu/legal-content/EN/TXT/?uri=CELEX%3A52021DC0550Search in Google Scholar
EUROPEAN COMMISSION. 2020. Powering a climate-neutral economy: An EU strategy for energy system integration. Brussels. Com(2020) 299 Final. 2020, 9. https://eur-lex.europa.eu/legal-content/EN/ALL/?uri=CELEX%3A52020DC0299EUROPEAN COMMISSION2020BrusselsCom(2020) 299 Final. 2020, 9. https://eur-lex.europa.eu/legal-content/EN/ALL/?uri=CELEX%3A52020DC0299Search in Google Scholar
EUROPEAN COMMISSION. 2022. REPowerEU: A plan to rapidly reduce dependence on Russian fossil fuels and fast forward the green transition. Brussels. p. 7. https://eur-lex.europa.eu/legal-content/EN/TXT/?uri=COM%3A2022%3A230%3AFINEUROPEAN COMMISSION2022Brussels7https://eur-lex.europa.eu/legal-content/EN/TXT/?uri=COM%3A2022%3A230%3AFINSearch in Google Scholar