Emerging Trends in Chemical Engineering

Techno-commercial analysis of hydrogen production by water electrolysis using electricity from nuclear power reactors is carried out in this work, using a combination of levelized cost of hydrogen (LCOH) and net present value methods (NPV) which consider time value of money. Codes are developed in-house to estimate project profitability (i.e. profitable sale prices of the hydrogen produced) under baseline, optimistic and pessimistic techno-commercial scenario using simplified financial metrics such as the internal rate of return (IRR). It appears that sale prices of hydrogen will need to be 1.5 to 2 times larger than the production cost for ensuring project profitability during energy transition though it has to be seen whether a market for hydrogen at such price points will be immediately available or not. These studies are essential for scaling up an existing mature technology even further so that wide spread deployment can be carried out for sustainable development while ensuring project profitability.

El-Emam R.S., Dincer I. (2018) Nuclear-Assisted Hydrogen Production. In: Meyers R. (eds) Encyclopedia of Sustainability Science and Technology. Springer, New York, NY. Available at https://link.springer.com/referenceworkentry/10.1007%2F978-1-4939-2493-6_961-1#howtocite (Last accessed on 7.7.2020)

Yildiz B, Kazimi MS. (2006) Efficiency of hydrogen production systems using alternative nuclear energy technologies. International Journal of Hydrogen Energy, Vol 31(1):77-92.

Chisholm G., Cronin L. (2016) Hydrogen From Water Electrolysis. In: Letcher TM (ed) Storing Energy with Special Reference to Renewable Energy Sources, pp. 315-343. Elsevier Inc.

Santos DMF, Sequiera CAC, Figueirido JL. (2013) Hydrogen production by alkaline water electrolysis. Quím. Nova, São Paulo, v.36, n.8, p.1176-1193, 2013. Available at http://www.scielo.br/scielo.php?script=sci_arttext&pid=S0100-40422013000800017&lng=en&nrm=iso. (Last accessed on 7.7.2020)

Balat H, Kirtay E. (2010) Hydrogen from biomass - Present scenario and future prospects. International Journal of Hydrogen Energy, Vol. 35:7416-7426.

Nath K, Das D (2003) Hydrogen from biomass. Current Science, Vol 85(3):265-271.

Shamsul NS, Kamaruddin SK, Rahman NA, Kofli NT (2014). An overview on the production of bio-methanol as potential renewable energy. Renewable and Sustainable Energy Reviews, 33:578-588.

Dahman Y, Syed K, Begum S, Roy P, Mohtasebi B (2019). Biofuels: Their characteristics and analysis. In: Verma D, Fortunati E, Jain S, Zhang X (eds.), Biomass, Biopolymer-Based Materials, and Bioenergy, pp. 277-325, Wood Head Publishing, Elsevier.

Zhang K, Li C, Wu Y (2017). Analysis of Research and Development Trend of the Battery Technology in Electric Vehicle with the Perspective of Patent. Energy Procedia, Vol 105:4274-4280.

Andwari AM, Pesiridis A, Rajoo S, Martinez-Botas R, Esfahanian V (2017). A review of Battery Electric Vehicle Technology and Readiness levels. Renewable and Sustainable Energy Reviews, 78:414-430.

Bhattacharyy R, Misra A, Sandeep KC (2017). Photovoltaic solar energy conversion for hydrogen production by alkaline water electrolysis: Conceptual design and analysis. Energy Conversion and Management, Vol. 133:1-13.

Barbir F (2005). PEM electrolysis for production of hydrogen from renewable energy sources. Solar Energy, Vol. 78(5):661-669.

El-Emam RS, Khamis I (2019) Advances in nuclear hydrogen production: Results from an IAEA international collaborative research project. International Journal of Hydrogen Energy, Vol. 44(35):19080-19088.

El-Emam RS, Khamis I (2017) International collaboration in the IAEA nuclear hydrogen production program for benchmarking of HEEP. International Journal of Hydrogen Energy, Vol. 42(6):3566-3571.

US DOE (2015) DOE Technical Targets for Hydrogen Delivery. Available at https://www.energy.gov/eere/fuelcells/doe-technical-targets-hydrogen-delivery (Last accessed on 8.7.2020)

Seider WD, Seader JD, Lewin DR (2009) Product and Process Design Principles-Synthesis, Analysis and Evaluation, 2nd Ed., Wiley India Pvt. Ltd., New Delhi.

Kuckshinrichs W, Ketelaer T, Koj JC (2017) Economic Analysis of Improved Alkaline Water Electrolysis. Frontiers of Energy Research, Vol. 5(1):1-13.

Bhattacharyya R (2019) Cost analysis and optimization of a nuclear assisted electrolytic hydrogen production and distribution network. International Journal of Chemical Engineering and Processing, Vol. 5(2):23-43.

Reserve Bank of India, “Master Circular on Interest Rates on Rupee Deposits held in Domestic, Ordinary Non-Resident (NRO) and Non-Resident (External) (NRE) Accounts”, available at https://www.rbi.org.in/CommonPerson/english/Scripts/Notification.aspx?Id=895 (last accessed on 8.7.2020)

Bhattacharyya R, Kamath S (2020) Parametric Analysis and Optimization of Nuclear Assisted Electrolytic Hydrogen Production System for On-site Applications. International Journal of Chemical Engineering and Processing, Vol. 6(1):14-26.

Ahmed S (2013) Wind Energy-Theory and Practice, 2nd ed., PHI Learning Pvt. Ltd., New Delhi.

Lymperopoulos N (2018) European Developments in Electrolyser Technology: Technical and Economic Outlook. POWER TO GAS Conference, Antwerp, 7 June 2018. Available at https://www.waterstofnet.eu/_asset/_public/powertogas/Conference/4-Nikolaos-Lymperopoulos_-FCH-JU.pdf (Last accessed on 27.6.2020)

IRENA (2019) Innovation landscape brief: Renewable Power-to-Hydrogen, International Renewable Energy Agency, Abu Dhabi. Available at https://www.irena.org/-/media/Files/IRENA/Agency/Publication/2019/Sep/IRENA_Power-to-Hydrogen_Innovation_2019.pdf?la=en&hash=C166B06F4B4D95AA05C67DAB4DE8E2934C79858D (Last accessed on 27.6.2020)

Amelang Soren. Germany's National Hydrogen Strategy. Clean Energy Wire, June 2020. Available at https://www.cleanenergywire.org/factsheets/germanys-national-hydrogen-strategy (Last accessed on 27.6.2020)

Miha Jensterle, Jana Narita, Raffaele Piria, Sascha Samadi, Magdolna Prantner, Kilian Crone, Stefan Siegemund, Sichao Kan, Tomoko Matsumoto, Yoshiaki Shibata, Jill Thesen. The role of clean hydrogen in the future energy systems of Japan and Germany. adelphi consult GmbH (2019). Available at https://www.adelphi.de/de/system/files/mediathek/bilder/The%20role%20of%20clean%20hydrogen%20in%20the%20future%20energy%20systems%20of%20Japan%20and%20Germany%20-%20Study.pdf (Last accessed on 27.6.2020)