Textured Stainless Steel as a Platform for Black Mg2Si/Si Heterojunction Solar Cells with Advanced Photovoltaic Performance

Shevlyagin, A. V.; Il’yaschenko, Vladimir M.; Kuchmizhak, Aleksandr; Mitsai, Eugeny; Amosov, A. V.; Balagan, Semyon A.; Kulinich, Sergei A.

doi:10.3390/ma15196637

Cited by 3 publications

(1 citation statement)

References 54 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…That is why, correlated metals and semimetals became the systems of interest, , which infrared transparency has been recently validated for the thin films of calcium disilicide (CaSi 2 ) and tungsten ditelluride (WTe 2 ) both possessing layered crystal structure and classified as trivial and type-II Weyl semimetals, respectively. , High intrinsic transparency in the optical telecommunication spectral range of the former material was shown in addition to a very low sheet resistance, which resulted in a record near-infrared (NIR) figure of merit (FOM) competitive with state-of-the-art TCOs and other TCMs. Moreover, a prototype photovoltaic device utilizing a CaSi 2 top electrode instead of conventional metal-finger contacts was demonstrated resulting in enhanced photovoltaic performance and clearly confirming the reliability of the semimetal approach …”

Section: Introductionmentioning

confidence: 58%

Alternative Look at Calcium Digermanide CaGe₂: A High-Performing Semimetal Transparent Conducting Material for Ge Optoelectronics

Il’yaschenko,

Pavlov,

Balagan

et al. 2024

ACS Appl. Electron. Mater.

Self Cite

View full text Add to dashboard Cite

Following a recently manifested guide of how to team up infrared transparency and high electrical conductivity within semimetal materials [Cui, C. et al. Prog. Mater. Sci. 2023, 136, 101112], we evaluate the applicability of the calcium digermanide (CaGe 2 ) thin-film electrodes for advanced Ge-based optical devices. Rigorous growth experiments were conducted to define the optimal annealing treatment and thickness of the Ca− Ge mixture for producing stable CaGe 2 layers with a high figure of merit (FOM) as transparent conducting material. Ab initio electronic band structure calculations and optical modeling confirmed the CaGe 2 semimetal nature, which is responsible for a demonstrated high FOM. To test CaGe 2 electrodes under actual conditions, a planar Ge photodetector (PD) with a metal−semiconductor−metal structure was fabricated, where the CaGe 2 /Ge interface acts as a Schottky barrier. The resulting Ge PD with semimetal electrodes outperformed commercially available Ge devices in terms of both photoresponse magnitude and operated spectral range. Moreover, by using femtosecond-laser projection lithography, a mesh CaGe 2 electrode with a relative broadband transmittance of 90% and a sheet resistance of 20 Ω/sq. was demonstrated, which further enhanced the Ge PD photoresponse. Thus, the obtained results suggest that CaGe 2 thin films have great potential in numerous applications promoting the era of advanced Ge optoelectronics.

show abstract

Section: Introductionmentioning

confidence: 58%

Alternative Look at Calcium Digermanide CaGe₂: A High-Performing Semimetal Transparent Conducting Material for Ge Optoelectronics

Il’yaschenko,

Pavlov,

Balagan

et al. 2024

ACS Appl. Electron. Mater.

Self Cite

View full text Add to dashboard Cite

show abstract

From Rigid to Flexible: Progress, Challenges and Prospects of Thin c‐Si Solar Energy Devices

Gupta,

Min,

Lee

et al. 2024

Advanced Energy Materials

View full text Add to dashboard Cite

The increasing adoption of solar energy as a renewable power source marks a significant shift toward clean, sustainable alternatives to conventional energy forms. A notable development in this field is the advancement of thin monocrystalline silicon (c‐Si) solar cells. Characterized by their lightweight, flexible nature, these solar cells promise to transform the renewable energy landscape with enhanced durability, adaptability, and portability. Amidst the growing demand for sustainable energy solutions, refining and evolving thin c‐Si solar cell technologies is crucial. This review comprehensively examines the latest progress in thin c‐Si solar energy conversion device technologies, offering an extensive overview of current methodologies for producing thin c‐Si films, advanced light trapping techniques, surface passivation strategies, and methods for managing thin wafers. It also explores the wide‐ranging applications of thin c‐Si solar cells. Furthermore, this article sheds light on the techno‐economic aspects, highlighting the intertwined challenges of commercializing these innovative cells. Through an in‐depth analysis of the latest advancements, this review serves as a valuable resource for researchers and industry experts, keeping them abreast of current trends and catalyzing further advancements in thin c‐Si solar cell technology.

show abstract

Investigation of surface morphology, optical and electronic properties of Mg2Si thin films on Si(111)

Fomin,

Polyakov,

Galkin

et al. 2024

VESTNIK of Samara University. Aerospace and Mechanical Engineer

View full text Add to dashboard Cite

The article presents the results of a study of the elemental composition, surface morphology, optical and electronic properties of Mg2Si thin films formed on Si (111). Both samples containing films were formed in layers by the method of reactive epitaxy, but at different heating temperatures of the substrates. The formed films consisting of alternating layers of Mg and Si at a ratio of 3:1, according to electron Auger spectroscopy, contain Mg and Si atoms in the associated layers. The Raman light scattering method established the presence of peaks on the graphs of samples at a shift of 258 and 348cm-1 belonging to Mg2Si. Infrared spectroscopy data also indicate the presence of magnesium silicide in the films. The thickness of Mg2Si films was estimated from the data of the known dependence of the amplitude of absorption peaks at 272 cm-1 on the absorption coefficient, which gave the values of the thicknesses of the grown films. Based on the results of the study of samples in the infrared-ultraviolet range and on the basis of geometric calculations, the width of the Mg2Si band gap was determined.

show abstract

Textured Stainless Steel as a Platform for Black Mg2Si/Si Heterojunction Solar Cells with Advanced Photovoltaic Performance

Cited by 3 publications

References 54 publications

Alternative Look at Calcium Digermanide CaGe₂: A High-Performing Semimetal Transparent Conducting Material for Ge Optoelectronics

Alternative Look at Calcium Digermanide CaGe₂: A High-Performing Semimetal Transparent Conducting Material for Ge Optoelectronics

From Rigid to Flexible: Progress, Challenges and Prospects of Thin c‐Si Solar Energy Devices

Investigation of surface morphology, optical and electronic properties of Mg2Si thin films on Si(111)

Contact Info

Product

Resources

About

Textured Stainless Steel as a Platform for Black Mg2Si/Si Heterojunction Solar Cells with Advanced Photovoltaic Performance

Cited by 3 publications

References 54 publications

Alternative Look at Calcium Digermanide CaGe2: A High-Performing Semimetal Transparent Conducting Material for Ge Optoelectronics

Alternative Look at Calcium Digermanide CaGe2: A High-Performing Semimetal Transparent Conducting Material for Ge Optoelectronics

From Rigid to Flexible: Progress, Challenges and Prospects of Thin c‐Si Solar Energy Devices

Investigation of surface morphology, optical and electronic properties of Mg2Si thin films on Si(111)

Contact Info

Product

Resources

About

Alternative Look at Calcium Digermanide CaGe₂: A High-Performing Semimetal Transparent Conducting Material for Ge Optoelectronics

Alternative Look at Calcium Digermanide CaGe₂: A High-Performing Semimetal Transparent Conducting Material for Ge Optoelectronics