143 research outputs found
A water- and sulfurization-free solution route to Cu2-xZn1+xSnS4
Zinc-rich/copper-poor Cu2-xZn1+xSnS4 (x = 0.2, CZTS) has been successfully produced in film and powder form using two non-aqueous solutions (of metal salts and thiourea) without the need for sulfurization during the annealing phase. A reaction route is proposed and the choices of the solvents (water, ethyleneglycol, ethanol, methanol) and of the tin source (tin chloride pentahydrate or anhydrous) discussed and justified. A pure and coarse-grained material is obtained with a mix of metal salts in methanol and thiourea in ethylene glycol. The tin pentahydrate salt seems a better alternative to the commonly used anhydrous chloride
Chloride-based route for monodisperse Cu2ZnSnS4 nanoparticles preparation
A new approach based on hot injection method is proposed to gram-scale Cu2ZnSnS4 nanoparticles production minimizing the use of organic solvents. Nanocrystal synthesis was performed starting from metal chlorides and pure sulphur powder and using Oleylamine as capping agent. As a result, core-shell nanoparticles with a narrow size distribution were obtained. © 2015 AIP Publishing LLC
A simplified expression for optical absorbance in Si solar cells
An expression for optical absorbance in Si is derived, which is a simplification of the expression for the same quantity given by Basore. Unlike the Basore expression, the simplified expression does not require the determination of the front-surface external and internal reflectance prior to be used. For textured solar cells it is equivalent to the Basore expression, if the average ray-path angle with respect to the surface normal is equal at all passes of light across a cell. Unlike the Basore expression, it allows fitting the measured quantum efficiency of planar solar cells with diffuse rear surface. The simplified expression can be easily implemented in the numerical simulation program PC1d. The measured quantum efficiency of a textured solar cell is fitted with both the new and Basore expressions. Overlapping fit-curves are obtained. The measured quantum efficiency of a planar solar cell with not-polished rear surface is fitted by using the new expression. Finally, with the new expression, the maximum absorbance for weakly absorbed light is estimated in solar cells with textured back surface at both flat and textured front surfaces
Electronic structure of Ar+ ion-sputtered thin-film MoS2: A XPS and IPES study
Polycrystalline MoS2 grown by Mo sulphurization was exposed to increasing doses of Ar+ ions at 250 eV starting from 2.2 × 1015 ions/cm2 to 3.92 × 1017 ions/cm2. Electronic structure changes were monitored by X-Ray Photoelectron Spectroscopy (XPS) and Inverse Photolectron Spectroscopy (IPES). No change in the Fermi level position was observed with Ar+ dosing. Ion bombardment resulted in a new visible feature at lower binding energy in the Mo3d core level, while the S2p lineshape showed little changes. The formation of a steady state from 2.49 × 1017 ions/cm2 has been detected. The investigation of the occupied and unoccupied states on the steady-state surface pointed to the simultaneous presence of metallic-like Mo with amorphous MoS2-x. © 2016 Elsevier B.V
Perovskite and a-Si:H/c-Si tandem solar cell
In this work the fabrication of Perovskite/Si tandem-solar cell is reported and discussed. In principle this configuration allows cell efficiency higher than single c-Si junction. While Perovskite cell was used as top cell, a-Si:H/c-Si heterojunction was adopted as a bottom cell. The investigated process starts from Glass/FTO/c-TiO2/n-TiO2/CH3NH3PbI3/ Spiro-OMeTAD/ITO top cell, coupled to an ITO/a-Si:H/c-Si/back reflector/Al heterojunction bottom cell. ITO film is used to join the top and bottom cell. Preliminary results demonstrate the feasibility of the tandem cell, indeed Voc value as high as 1.65mV has been achieved. Numerical simulations is used to evaluate the limit and the potentiality of the proposed tandem structure. © 2015 IEEE
Effect of Hydrogen Gas Dilution on Sputtered Al:ZnO Film
AbstractAl doped zinc oxide (ZnO:Al) is a transparent and conductive oxide used as contact and antireflection layer in solar cell based on Si or chalcogenide. Generally it is grown by magnetron sputtering but the resistivity of our films grown with this technique are still in the order of 10-3Ωcm for layers grown at the temperatures used to produce the solar cells. The doping property of Hydrogen for Al:ZnO grown with two different sputtering techniques, DC magnetron sputtering and Pulsed magnetron sputtering at different growth parameters have been studied and the sample characterized optically, electrically and structurally. The best resistivity is 6.7*10-4Ωcm was obtained using Pulsed magnetron sputtering
Combinatorial study of co-sputtered Cu2ZnSnS4 thin-film stoichiometry for photovoltaic devices
In this work we investigate the role of stoichiometry variations in Cu2ZnSnS4 thin films obtained via sulfurization of precursor grown by co-sputtering of binary sulphides. Combinatorially graded thin-film Cu-Zn-Sn-S library samples spanning a large region of the ternary Cu2S-ZnS-SnS2 phase diagram were deposited at temperatures below 110°C and subsequently sulfurized at 550 °C in a tube furnace using a stoichiometric excess of sulfur. We present some results on the influence of chemical composition, measured by EDX, on the morphological and mechanical properties of the films. The films were also processed to obtain a matrix of small area complete photovoltaic devices. In this way the correlation between the stoichiometry and the device performances can be clarified. Finally, several interesting devices were more completely characterized by measuring J-V characteristic curves, the External Quantum Efficiency (EQE) and by looking at their photoluminescence (PL) spectrum trying to confirm a recently suggested correlation between PL peak energies and photovoltaic performances
- …
