Study of semiconductor features of zinc oxide films modified with cadmium telluride quantum dots

Placed in the context of renewable energy sources, this work consists of the synthesis and characterization of ZnO films modified CdTe quantum dots to be applied in photoelectrochemical cells. ZnO rods are interesting materials because this kind of structure facilitates the charge carriers transport, minimizing the loss of these at grain boundaries and their recombination and annihilation. The ZnO film modification with CdTe nanocrystals should increase the photoconversion efficiency by facilitating charge separation and electron transfer, and it increases the nanocrystals stability, preventing it from anodic corrosion and decomposition. The ZnO film was electrodeposited potenciostatically on ITO surface. SEM and EDX analysis indicated that the ZnO film obtained is homogeneous and it consists of rods with atomic ratio of Zn and O according to 1:1 stoichiometry. XRD result showed three characteristic planes of ZnO in wurtzite crystalline form. The (002) plane is the predominant, indicating the rods orientation in the c-axis vertical to the substrate. The ZnO film also has a thickness of 550 nm, bandgap of 3.27 eV, flat band potential of 0.4 V and density of charge carriers 8,9 x 1019 cm-3. The synthetic procedure of CdTe quantum dots occurred from the dissolution cadmium oxide in tetradecylphosphonic acid and octadecene (ODE) to 300 °C. Subsequently, cadmium precursor solution of was cooled to 260 °C and then the tellurium precursor solution, prepared by dissolving tellurium in tributylphosphine and in ODE was injected. The obtained nanocrystals were dispersed in hexane, precipitated with ethanol and finally the quantum dots were stored in toluene. From UV-Vis and TEM analysis was possible to estimate the quantum dots size of CdTe as 4 nm. The XRD of CdTe nanocrystals presented the main characteristic planes of zinc blend structure. ZnO electrode modified with CdTe quantum dots (ZnO/CdTe) was obtained by 24 h immersion in a solution of acetonitrile containing mecaptopropionic acid and propionic acid. Subsequently, the ZnO film modified with the linker was immersed for 48 h in CdTe quantum dots dispersion. FTIR spectrum reveals the absence of a symmetrical C=O stretching mode at approximately 1700 cm-1. Instead, the spectrum shows the presence of the asymmetric and symmetric vas(CO2-) and vs(CO2-) modes were observed at 1631 and 1417 cm-1, respectively. Kulbeka-Munk transformation of the reflectance spectrum of the ZnO/CdTe electrode presented the band related to CdTe in the same wavelength observed when this was in the dispersion. The ZnO/CdTe electrode showed a photocurrent value of 138 µA, a value 10 times greater than that obtained for ZnO. At IPCE experiments (incident photon-to-current efficiency) an increase of approximately five times was also noticed to the electrode of ZnO/CdTe. Dynamics of charge carriers was investigated by fs and µs TAS (Transient Absorption Spectroscopy) for ZnO and ZnO/CdTe electrodes. TAS analyses indicate a short life time to ZnO/CdTe electrode compared to ZnO film. Clark electrode measurements showed oxygen production by ZnO/CdTe electrode. Thus, ZnO/CdTe proposed electrode is presented as promising material for photoelectrochemical applications. (AU)