Experimental and first-principles DFT study on oxygen vacancies on cerium dioxide and its effect on enhanced photocatalytic hydrogen production

Abstract: Experimental and computational (DFT) approaches were carried out to investigate oxygen vacancies on Cerium dioxide. Computational result indicates oxygen vacancies can shorten the band gap of CeO 2 and enhance the absorption for visible light because Ce (III) created by generation of oxygen vacancies is easier for excitation than Ce (IV) under same irradiation. The order of calculated band gap for Ce 16 O 31 , (111) < (113) < (133), and the absorption data suggests that (111) plane may be the most ideal positi… Show more

“…For GO/Cu 2 O-0.5-af, the contents of C=O and C-O species decrease sharply because some organic groups like carboxyl and carbonyl can be degraded to carbon dioxide or other dissociative composition during visible light irradiation [41], and this decrease also enlarges the atomic percentages of C sp 2 and C sp 3 . But the percentages of C sp 2 are much larger than that of C sp 3 . By comparing the atomic compositions for GO/Cu 2 O-0.5 and GO/Cu 2 O-0.5-af (Table S1), it was found that the ratio of C sp 2 to C sp 3 increase from 0.86 to 1.22 while a part of covered GO was desquamated (Figure 7(D)) and the GO shell was thinner and more smooth (Figure 7(E)), which suggests that a part of sp 3 carbon was degraded during irradiation.…”

“…Neither amounts of Cu (I) nor amounts of Cu (II) sharply decreased with the increasing of GO addition, which suggests that GO was formed on the surface rather than being mixed with the lattices of copper oxides. Meanwhile, both the atomic amount of sp 2 and sp 3 Band gap, conduction band edge and valence band edge are three important parameters for semiconductor photocatalysts, and they can be calculation form the UV-vis absorption spectra. The values of band gaps for Cu 2 O nanosphere and the GO-modified samples are estimated from the plot of the (αhν) 2 versus photon energy (hν) [4,38] as shown in Table 3.…”

“…Solar energy has been caught much attention for global researchers because it is renewable, carbon-free and the largest source available among all the developing renewable energy sources [1]. The common way of utilizing solar energy is to convert it into electricity by photo-voltaic cells [2], while the other routine is to convert it into chemical energy, such as hydrogen [3], methanol [4], or carbon monoxide [5], directly by photocatalysts. Since the first photocatalyst, TiO 2 , used for hydrogen production during the water splitting reaction was reported at 1972 [6], TiO 2 has been explored as a stable, efficient and nontoxic photocatalyst or support.…”

Synthesis of GO-modified Cu2O nanosphere and the photocatalytic mechanism of water splitting for hydrogen production

“…For GO/Cu 2 O-0.5-af, the contents of C=O and C-O species decrease sharply because some organic groups like carboxyl and carbonyl can be degraded to carbon dioxide or other dissociative composition during visible light irradiation [41], and this decrease also enlarges the atomic percentages of C sp 2 and C sp 3 . But the percentages of C sp 2 are much larger than that of C sp 3 . By comparing the atomic compositions for GO/Cu 2 O-0.5 and GO/Cu 2 O-0.5-af (Table S1), it was found that the ratio of C sp 2 to C sp 3 increase from 0.86 to 1.22 while a part of covered GO was desquamated (Figure 7(D)) and the GO shell was thinner and more smooth (Figure 7(E)), which suggests that a part of sp 3 carbon was degraded during irradiation.…”

“…Neither amounts of Cu (I) nor amounts of Cu (II) sharply decreased with the increasing of GO addition, which suggests that GO was formed on the surface rather than being mixed with the lattices of copper oxides. Meanwhile, both the atomic amount of sp 2 and sp 3 Band gap, conduction band edge and valence band edge are three important parameters for semiconductor photocatalysts, and they can be calculation form the UV-vis absorption spectra. The values of band gaps for Cu 2 O nanosphere and the GO-modified samples are estimated from the plot of the (αhν) 2 versus photon energy (hν) [4,38] as shown in Table 3.…”

“…Solar energy has been caught much attention for global researchers because it is renewable, carbon-free and the largest source available among all the developing renewable energy sources [1]. The common way of utilizing solar energy is to convert it into electricity by photo-voltaic cells [2], while the other routine is to convert it into chemical energy, such as hydrogen [3], methanol [4], or carbon monoxide [5], directly by photocatalysts. Since the first photocatalyst, TiO 2 , used for hydrogen production during the water splitting reaction was reported at 1972 [6], TiO 2 has been explored as a stable, efficient and nontoxic photocatalyst or support.…”

Synthesis of GO-modified Cu2O nanosphere and the photocatalytic mechanism of water splitting for hydrogen production

“…Due to these speciality, it is often used as a catalyst in various catalytic application such as solid oxide fuel cells (SOFCs), ultraviolet adsorbents, glass polishing materials, water gas shift reaction, PROX (CO oxidation), oxygen sensors, selective organic transformation, photocatalytic water oxidation and pollutant degradation [27,[39][40][41][42][43]. In addition to it, CeO 2 has other specialities such as cost-effectiveness, high stability, low toxicity and specific physical and chemical characteristics, such as high oxygen storage capacity (OSC), oxygen ion conductivity and fast shuttling of oxidation state (Ce 3+ K Ce 4+ ), which makes it an ideal candidate for photocatalysis [44][45][46][47][48][49][50][51][52][53][54][55][56][57][58][59]. In brief, the rare earth CeO 2 has a crystal structure of triclinic or tetragonal or cubic phase.…”

“…The change is due to the oxygen vacancy, which creates a Ce 3+ state, thus the energy of 4f orbitals shift towards lower potential and hence shorten the bandgap. The density of state (DOS) of Ce4f for Ce(III) is larger than that of Ce(IV) in positive energy range, which indicates Ce(III) is easier for excitation than Ce(IV) under light irradiation, which suggests that oxygen vacancy enhances the visible light absorption [55]. In addition to the optical property, the oxygen vacancy of CeO 2 has also a profound effect on the electrical as well as magnetic character.…”

Crystal facet and surface defect engineered low dimensional CeO₂(0D, 1D, 2D) based photocatalytic materials towards energy generation and pollution abatement

Effect of the Oxygen Vacancies in CeO₂ by the Ce³⁺ Incorporation to Enhance the Photocatalytic Mineralization of Phenol