eprintid: 14659 rev_number: 2 eprint_status: archive userid: 1 dir: disk0/00/01/46/59 datestamp: 2023-11-10 03:29:15 lastmod: 2023-11-10 03:29:15 status_changed: 2023-11-10 01:57:29 type: article metadata_visibility: show creators_name: Ng, K.H. creators_name: Lai, S.Y. creators_name: Cheng, C.K. creators_name: Cheng, Y.W. creators_name: Chong, C.C. title: Photocatalytic water splitting for solving energy crisis: Myth, Fact or Busted? ispublished: pub keywords: Energy dissipation; Energy policy; Free energy; Hydrogen production; Solar power generation; Structural design, Back reaction; Carbon-free; Charge recombinations; Energy; Energy crisis; H-2/ production; Hydrogen Energy; Infeasible for energy generation; Intrinsic limitation; Photocatalytic water splitting, Solar energy note: cited By 86 abstract: Reaping hydrogen energy by utilising eternal sunlight offers a good fit to the theme of popularly-hype sustainable and carbon-free energy future. Contrary to that belief, this review unveils the impracticality of photocatalytic water splitting (solar energy for H2 energy) to fuel global advancement. Despite some success with idealized laboratory-scale studies, the past research works also mutually evinced an extreme low solar-to-hydrogen efficiency (STH < 1.0). Hitherto, multifarious endeavours, such as advanced reactor design, facilities to eliminate diffusional restrictions, advanced photocatalyst design and an inclusion of sacrificial reagents, are incapable to raise STH efficiency to the practical threshold of STH > 10. Regardless of the epitome and modifications of photocatalysts, the intrinsic limitation of charges recombination remains a sturdy obstacle, leading to an appreciable energy losses and low STH. For consequential solar-driven H2 production, the bandgap energy of photocatalyst employed must stay below 2.36 eV. Meanwhile, most photocatalysts are capped by the theoretical maximum STH of 18, even with the assumption of 100 quantum yield of corresponding spectrum. Nonetheless, the theoretical maximum STH is unattainable at this juncture due to the inevitable solar energy dissipation associated to the scattering effects of reactor and water. From economy standpoint, H2 production via photocatalytic water splitting is pricey at 10.36 /kg with exorbitant upfront costs, which is far beyond the practicable price range of 2 � 4 /kg. In conclusion, we assert that the H2 production from solar-driven photocatalytic water splitting is an industrially impractical pathway for solar energy harnessing, despite technically-feasible. © 2021 Elsevier B.V. date: 2021 publisher: Elsevier B.V. official_url: https://www.scopus.com/inward/record.uri?eid=2-s2.0-85102536518&doi=10.1016%2fj.cej.2021.128847&partnerID=40&md5=fa678e87c005248e610f9c4c6879907a id_number: 10.1016/j.cej.2021.128847 full_text_status: none publication: Chemical Engineering Journal volume: 417 refereed: TRUE issn: 13858947 citation: Ng, K.H. and Lai, S.Y. and Cheng, C.K. and Cheng, Y.W. and Chong, C.C. (2021) Photocatalytic water splitting for solving energy crisis: Myth, Fact or Busted? Chemical Engineering Journal, 417. ISSN 13858947