dc.description.abstract |
Development of economical and highly proficient solar cells is crucial to gratify the rising global call.
Solar energy generation is a technologically feasible method, though primarily it’s expensive. Copperzinc-tin-sulfide
(CZTS) is another alternative compound that fascinates all soalr cell material
researchers. To date, the best CZTS solar cell converts only 11% (for CZTSe, it’s 12.6% for ACZTSSe,
13.8%.) of light into electricity, paralleled to above 27.6% for single crystal silicon concentrator type
solar cells. As the theoretical efficiency of CZTS is about 30%, therefore, it can be said that CZTS solar
cells are still in a premature enquiry stage where much of the area is yet to be explored. The rapid
advancements in the efficiency of CZTS solar cells are accredited to a trial-and-error methodology to
module assembly. This has led to a fundamental knowledge gap of CZTS. This thesis aimed to reduce
this knowledge gap to its best. Throughout the study, the ability to regulate the composition, crystallinity
and stoichiometry of CZTS thin films has been demonstrated and preliminary efforts in pre and post
annealing treatment towards crystalline films are promising indeed. In the context of this project,
tunable band gap absorber material, specifically, Cu
2
ZnSnS
4
(CZTS) is fabricated by three different
methods to find out better morphology, composition, stoichimetry and other opto electronic properties
for photovoltaic application. Kesterite CZTS is collection of plentiful fundamentals and non-toxic
substantial, with necessary attributes for photovoltaic (PV) uses, for example, high absorption
coefficient ~10
-4
cm
-1
and a band gap energy (E
g
) adjacent to 1.5 eV. The effect of various deposition
techniques and annealing parameters on film growth was explored using optical, morphological, and
structural material characterizations along with composition analyses. The sputtered kesterite which
reveals best quality thin film for this study, must be annealed to produce device-grade films. Moreover,
sputter system provides the facilities achieving a desired thickness of the film. The prepared film is
undergoing post-annealing treatment with different temperatures (250-560° C) and pressure (150- 450
Torr). XRD pattern shows preferential characteristics peak along (112), (220), and (312) and phase
purity is inveterate by Raman studies. The granules are compact, and as the annealing temperature rises,
agglomeration increases, boosting the absorption coefficient. The band gap energy (E
g
) differs between
1.47-1.51 eV which is compatible with optimum values. Sputtered films have uniform surface
topography and thickness. As a result, the film has significantly better covering than the sol
deposited film. RMS roughness increases with annealing heat and base pressure. The chemical
composition of the fabricated sample shows good atomic stoichiometry of the film. The elemental
composition is observed as Cu and S enriched Zn and Sn deficient without sulfurization. SnS loss occurs
at temperatures of above 500 °C which results cavities on film surface and affects the stoichiometry of
the film. The current study shows that sputter deposition may be used to produce CZTS thin films on
soda lime glass (SLG) with molybdenum (Mo) back contact for prospective solar cell applications. In
addition, impurity doped ZnO ( ZnO: Al or AZO), which has been examined for this thesis, is currently
the best indium-free contender for an alternative TCO compound. In particular, the study is
concentrated on the consequence of depositions factors and techniques with extensive analysis of AZO
fabrication to find an equally transparent, efficient, cheap, more readily available, and electrically
conductive alternate to Indium. The findings of the research work encompasses a range of significant
contributions, from discovering empirical evidence to optimizing different key parameters for CZTS
and AZO thin films, and finally, developing a complete and optimized SLG/ Mo/CZTS/CdS/iZnO/AZO
solar
cell
fabrication
process.
Moreover,
A
comprehensive
theoretical
model
of
CZTS
solar
cell
has been developed and anlyzed. From the Simulations, the maximum PCE is shown as 23.74%
with V
oc
= 1.62 V and J
sc
= 28.37 mA/cm
2
for 3000 nm CZTS absorber layer. The research not only
advances the understanding of solar cell technology but also has practical implications for sustainable
energy solutions in the future. |
en_US |