Simulation of structural and electrical parameters of СdS thin films

Based on the calculations from the first principles, we obtained the distributions of valence electron densities and electron energy spectra for a CdS film with different oxygen concentrations. According to the results of calculations, it is established that during the adsorption of oxygen atoms on the surface of CdS, oxygen taking electrons from the surface atoms of the CdS film, increases its catalytic activity. The oxygen concentration should not exceed 12.5%.

Fabrication and photosensitivity of ZnO/CdS/Silica nanopillars based photoresistor

A kind of Zinc oxide (ZnO)/Cadmium sulfide (CdS)/Silica nanopillars structure is fabricated to photoresistor for the first time. The silica wafer with countless nanopillars is used as the substrate for photoresistor. CdS and ZnO film are deposited by frequency (RF) magnetron sputtering onto the silica nanopillars surface to form ZnO/CdS/Silica nanopillars structure. The ZnO nanowires also can grow on the CdS surface by the hydrothermal reaction to ZnO nanowires/CdS/Silica nanopillars structures. The X-ray diffraction curves show that the ZnO and CdS film both on the planar silica and nanopillar silica surface are well-crystallized. The ZnO film deposition can reduce the reflection and increase the absorption of the incoming light, especially for the light with a wavelength less than 350 nm. And the ZnO/CdS heterojunction structure can retard the recombination probability of the photon-generated carries and prolong the lifetime of the photon-generated carriers, which lending to a remarkable photocurrent improvement. The photosensitivity property testing results show that the ZnO nanowires/CdS/Silica nanopillars structure has the best photosensitivity response of 135 for the white light with 10 mW/cm2 illumination.

Незаполненные электронные состояния ультратонких пленок кватерфенила на поверхностях послойно сформированного CdS и окисленного кремния

The results of a study of unoccupied electronic states and the formation of a boundary potential barrier during thermal vacuum deposition of ultrathin films of 4-quaterphenyl oligophenylene on the surface of CdS and on the surface of oxidized silicon are presented. Using X-ray photoelectron spectroscopy (XPS) it was determined, that the atomic concentrations of Cd and S were equal in the surface layer of a 75-nm-thick CdS film formed by atomic layer deposition (ALD). The electronic properties of 4-quaterphenyl films up to 8 nm thick were studied during their deposition on the surface of the CdS layer and on the surface of oxidized silicon using total current spectroscopy (TCS) in the energy range from 5 eV to 20 eV above EF. The energetic position of the main maxima of the fine structure of the total current spectra (FSTCS) of 4-quaterphenyl films was determined. The location of the maxima was reproducible when two selected substrate materials were used. A minor decrease in the work function, from 4.2 eV to 4.1 eV, was registered during the thermal deposition of 4-quaterphenyl onto the CdS surface. During the deposition of a 4-quaterphenyl film on the oxidized silicon surface, an increase in the work function from 4.2 eV to 4.5 eV was found. Possible mechanisms of the physicochemical interaction between the 4-quaterphenyl film and the surface of the investigated substrates, which lead to a difference in the observed values of the work function of the films on these substrates, are discussed.

Physical Properties of Screen-Printed Polycrystalline Cadmium Sulphide Films for Solar Cells

In the present work Cadmium sulphide (CdS) nanopowder was synthesized by chemical coprecipitation route and films were synthesized by non-vacuum based and cost feasible screen-coating route. Most favorable conditions for synthesis of good quality screen-coating films were obtained. Deposited CdS films were investigated by XRD, FESEM, EDAX, UV-vis and two probes methods for microstructural, morphological, elemental, optical and electrical properties. The XRD studies reveals that the films have polycrystalline nature showing hexagonal structure with preferred orientation of grains along (002) plane for powder & (101) plane for CdS film. The morphological analysis showed the films are homogeneous with nearly spherical clusters. Elemental analysis confirmed the existence of Cd and S elements in the films with Cd/S ratio is 0.74. The optical properties of the films were investigated through absorbance & transmittance measurement. The optical direct band gap value was found to be 2.34 eV. The electrical studies revealed the semiconducting nature of CdS films with electrical resistivity in the order of 105 Ωcm and activation energy 0.4 eV.

Sustainable Development of Enhanced Luminescence Polymer-Carbon Dots Composite Film for Rapid Cd2+ Removal from Wastewater

As a remedy for environmental pollution, a versatile synthetic approach has been developed to prepare polyvinyl alcohol (PVA)/nitrogen-doped carbon dots (CDs) composite film (PVA-CDs) for removal of toxic cadmium ions. The CDs were first synthesized using carboxymethylcellulose (CMC) of oil palms empty fruit bunch wastes with the addition of polyethyleneimine (PEI) and then the CDs were embedded with PVA. The PVA-CDs film possess synergistic functionalities through increasing the content of hydrogen bonds for chemisorption compared to the pure CDs. Optical analysis of PVA-CDs film was performed by ultraviolet-visible and fluorescence spectroscopy. Compared to the pure CDs, the solid-state PVA-CDs displayed a bright blue color with a quantum yield (QY) of 47%; they possess excitation-independent emission and a higher Cd2+ removal efficiency of 91.1%. The equilibrium state was achieved within 10 min. It was found that adsorption data fit well with the pseudo-second-order kinetic and Langmuir isotherm models. The maximum adsorption uptake was 113.6 mg g−1 at an optimal pH of 7. Desorption experiments showhe that adsorbent can be reused fruitfully for five adsorption-desorption cycles using 0.1 HCl elution. The film was successfully applied to real water samples with a removal efficiency of 95.34% and 90.9% for tap and drinking water, respectively. The fabricated membrane is biodegradable and its preparation follows an ecofriendly green route.