Effects of electrochemical synthetic conditions on surface property and photocatalytic performance of copper and iron-mixed p-type oxide electrodes

doi:10.1016/j.jmst.2017.11.055

Abstract

Abstract:

Earth-abundant copper and iron-mixed oxide (CuO/CuFeO₂; CFO) film electrodes are synthesized using an electrochemical deposition (ED) technique at two different ED potentials (-0.36 and -0.66 V vs saturated calomel electrode (SCE); denoted as ED-1 and ED-2, respectively). Then, their surface morphologies are compared, and the photo(electro)catalytic activities for the reduction of Cr(VI) are examined in aqueous solutions at pH 7 under simulated sunlight (AM 1.5G; 100 mW cm^-2). The degree of the electrical potential applied to the ED process significantly affects the thickness of the synthesized electrode film and the intensity ratio of the diffraction peaks of CuO (111) and CuFeO₂ (012). A 200 μm thick ED-2 sample with a distinct stacking of CuO on CuFeO₂ exhibits a larger broadband absorption spectrum than the 50-μm thick ED-1 with less separate stacking. Furthermore, the ED-2 sample has a higher intensity ratio of the diffraction peaks of CuO (111) and CuFeO₂ (012) than ED-1. As-synthesized ED-2 samples produce larger photocurrents, leading to faster Cr(VI) reduction on the surface under given potential bias (-0.5 V vs SCE) or bias-free conditions. The energy levels (i.e., flatband potential) for the two samples are almost the same (only 10 mV difference), presumably supposing that the enhanced photoactivity of the ED-2 sample for Cr(VI) reduction is due to the facilitated charge transfer. The time-resolved photoluminescence emission spectra analysis reveal that the lifetime (τ) of the charge carriers in the ED-1 sample is 0.103 ns, which decreases to 0.0876 ns in the ED-2. The ED-2 sample synthesized at a high negative potential is expected to contribute greatly to the application of other solar-to-fuel energy conversion fields as a highly efficient electrode material.

Key words: Artificial photosynthesis, Solar fuel, Delafossites, Morphology, Charge transfer

Sun Hee Yoon, Dong Suk Han, Unseock Kang, Seung Yo Choi, Wubulikasimu Yiming, Ahmed Abdel-Wahab, Hyunwoong Park. Effects of electrochemical synthetic conditions on surface property and photocatalytic performance of copper and iron-mixed p-type oxide electrodes[J]. J. Mater. Sci. Technol., 2018, 34(9): 1503-1510.

Figures/Tables 8

Fig. 1. XRD spectra of mixed CFO samples deposited onto FTO layers at different electrochemical deposition (ED) potentials of -0.36 and -0.66 V vs SCE (denoted as ED-1 and ED-2, respectively).

Fig. 2. XPS profiles of (a, b) Cu 2p and (c, d) Fe 2p in (a, c) ED-1 and (b, d) ED-2 samples. The spectra were obtained after every 1 min period of sputtering. Among the total of 30 sputtered spectra, the first 5 spectra are shown because of insignificant changes from the 6th spectrum.

Fig. 4. Cross-sectional (a-c, f-h) SEM and (d, e, i, j) EDS images of (a-e) ED-1 and (f-j) ED-2 samples.

Fig. 3. Comparison of top-view (a, b, e, f) SEM images and (c, d, g, h) EDS images of (a-d) ED-1 and (e-h) ED-2 samples. The inset shows photos of the ED-1 and ED-2 samples before and after annealing.

Fig. 5. AFM analysis results for (a-c) ED-1 and (d-f) ED-2 samples: (a, d) top-view of 2D topography; (b, e) phase-images; (c, f) 3D topography. In c and f, each unit on the x and y axes corresponds to 5 μm, and 2 μm on the z axis.

Fig. 6. Light-chopped linear sweep voltammograms of (a) ED-1 and (b) ED-2 samples in aqueous NaCl solution and (c) PEC and PC conversion of Cr(VI) (C0 = 6.8 μM) using ED-1 and ED-2 samples (Held at -0.5 V vs SCE for PEC and bias-free for PC) in aqueous NaCl solution (E: potential; I: current density). The inset shows a photo of the PEC Cr(VI) concentration change.

Fig. 7. XPS deconvolution for Cr spectra after PEC Cr(VI) reduction: (a) ED-1; (b) ED-2.

Fig. 8. TRPL emission (λ > 500 nm) decay spectra (original data and fitted curves) of ED-1 and ED-2 samples excited at 379 nm. The inset shows 2D images of the ED-1 (left) and ED-2 (right) samples. The average lifetime (τ) of the charge carriers is shown in the table.

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