Although various water splitting systems using oxide semiconductor photoanodes have been investigated, almost all these systems focused solely on production and recovery of H₂ energy; there has been little focus on the recovery of oxidation products such as O₂, which is simultaneously evolved during water splitting. We prepared a porous and thick photoelectrode of WO₃ or BiVO₄ to realize the recovery of H₂ and high-value-added oxidation reagents with efficient solar energy conversion. The WO₃ photoelectrode enabled the production and accumulation of O₂, S₂O₈^2-, Ce⁴⁺ or IO₄^- as oxidation products. Most notably, S₂O₈^2-, which possesses the highest oxidizability among all peroxides, was generated with high applied bias photon-to-current efficiency (ABPE H₂ S₂O₈^2- = 2.2%) and Faraday efficiency (ca. 100%) on irradiation from the back side of the photoelectrode. Designs of tandem photoelectrode system combining dye-sensitized solar cell (DSSC) were also challenged for realization of stand-alone system. A high solar energy conversion efficiency (5.2%) was achieved in the tandem system comprising the WO₃ photoelectrode connected to two DSSCs with a near-IR-utilizing dye in series for production of H₂ and S₂O₈^2-. Furthermore, we investigated oxidative H₂O₂ production from water on a WO₃/BiVO₄ photoanode simultaneously with production of hydrogen on a Pt cathode in bicarbonate electrolyte even at a voltage far lower than the theoretical electrolysis voltage (1.77 V) under simulated solar light. An unprecedentedly efficient simultaneous production and accumulation of H₂O₂ was achieved in 2.0 M KHCO₃ at low temperature, and the maximum selectivity, accumulated concentration and turnover number (TON) of H₂O₂ generated reached ca. 54%, 2 mM and 108, respectively. The role of bicarbonate ion for H₂O₂ production is investigated.