However, the PEC performance of hematite, especially at low bias, is still severely hindered by three main electron/hole recombination pathways that occur in the bulk, interfaces, and surfaces. [ 1,3 ] As schematically illustrated in Figure 1 a, hematite nanorods (NRs), one of the representative nanostructures adopted for photoanodes, exhibit large bulk recombination owing to its poor majority carrier conductivity, via small polaron hopping conduction with a low electron mobility of 10 −2 cm 2 V −1 s −1 , [ 4 ] and short hole collection depth (≈12 nm = hole diffusion length (≈5 nm) + space charge layer width (≈7 nm). [ 5 ] The low intrinsic conductivity and short hole collection depth greatly limit the charge transport/ separation effi ciency of hematite for PEC water oxidation. In addition to bulk recombination, there are interfacial recombinations between the hematite NRs and the conductive substrate, frequently fl uorinedoped SnO 2 (FTO), and recombination losses due to the electron back-injection into the electrolyte on the exposed areas of FTO. [ 6,7 ] Finally, there are signifi cant surface recombination losses due to the presence of surface states and sluggish oxygen evolution reaction (OER) kinetics of hematite. [ 8 ] As a result, these recombination losses lead to low photocurrent density and large overpotential for hematite based PEC water oxidation.Extensive amount of work has been done to reduce those recombination losses, and most of them normally focuses on reducing one or two recombination losses. For the reduction of bulk recombination, great efforts have been devoted to nanostructuring and/or doping of hematite. To date, a number of nanostructures including nanowires, [ 9 ] nanorods, [10][11][12] nanotubes, [ 13 ] nanosheet, [ 14 ] caulifl ower [ 15 ] and porous structures, [ 16,17 ] and diverse metal dopants including Si, Ti, Sn, Zr, Nb, Ag, Pt, Mn, and Al [ 12,[17][18][19] have been studied to shorten the hole transport distance and to increase the electrical conductivity respectively. Separately, it was shown that adding an under-layer of SiO x , TiO 2 , Nb 2 O 5 , or Ga 2 O 3 suppresses the back electron injection and reduces the interface recombination of hematite. [ 7,20,21 ] For the surface recombination, various approaches including For a hematite (α-Fe 2 O 3 ) photoanode, multiple electron/hole recombination pathways occurring in the bulk, interfaces, and surfaces largely limit its low-bias performance (low photocurrent density at low-bias potential) for photoelectrochemical water splitting. Here, a facile and rapid three-step approach is reported to simultaneously reduce these recombinations for hematite nanorods (NRs) array photoanode, leading to a greatly improved photocurrent density at low bias potential. First, fl ame-doping enables high concentration of Ti doping without hampering the morphology and surface properties of the hematite NRs, which reduces both the bulk and surface recombinations effectively. Second, the addition of a dense-layer between the hematite NRs and fl uo...
