Fabrication of Crystalline Si Thin Films for Photovoltaics

An, Junyang; Shen, Ya; Cabarrocas, Pere Roca i; Chen, Wanghua

doi:10.1002/pssr.202200290

Cited by 4 publications

(3 citation statements)

References 136 publications

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“…[2,3,15] In the last decade, studies on plasma-epi Si have primarily focused on two aspects: improving the charge-carrier transport properties for electronic applications and suppressing the growth of plasma-epi Si for high-efficiency SHJ solar cells. [2,3,[6][7][8][9][10][11][12][13][14][15][16] Plasma-assisted epitaxially grown silicon (plasma-epi Si) is a new silicon-based material with a tailorable nanostructure. Nanovoids can be introduced into plasma-epi Si during growth, enabling the bottom-up fabrication of porous Si for applications such as batteries, hydrogen storage, and even explosives.…”

Section: Introductionmentioning

confidence: 99%

“…First, the low growth temperature of plasma‐epi Si restricts the surface mobility of reactive species, resulting in incomplete surface reconstruction and crystallographic defects such as dislocations and stacking faults. [ 16 ] Second, plasma‐epi Si consists of a high concentration of SiH bonds owing to the hydrogen radicals in the plasma. This hydrogen incorporation can also induce defects such as hydrogen‐incorporated nanovoids and platelets.…”

Section: Introductionmentioning

confidence: 99%

“…[ 2,3,15 ] In the last decade, studies on plasma‐epi Si have primarily focused on two aspects: improving the charge‐carrier transport properties for electronic applications and suppressing the growth of plasma‐epi Si for high‐efficiency SHJ solar cells. [ 2,3,6–16 ]…”

Section: Introductionmentioning

confidence: 99%

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Dynamics of Plasma‐Assisted Epitaxial Silicon Growth Driven by a Hydrogen‐Incorporated Nanostructure for Novel Applications

Oh,

Lee,

Kim

et al. 2023

Small Structures

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Plasma‐assisted epitaxially grown silicon (plasma‐epi Si) is a new silicon‐based material with a tailorable nanostructure. Nanovoids can be introduced into plasma‐epi Si during growth, enabling the bottom‐up fabrication of porous Si for applications such as batteries, hydrogen storage, and even explosives. To fully control the nanostructure of plasma‐epi Si, its growth dynamics must be studied. In this study, the correlation between hydrogen incorporation and defect nanostructures in plasma‐epi Si grown under various process conditions is investigated, and the experimental results are supported by molecular dynamics simulations. The nanostructural evolution during growth suggests a model in which plasma‐epi Si shows two growth stages distinguished by different dominant defect nanostructures. In the initial growth stage, the nanostructure can be controlled by the deposition conditions, whereas the nanostructure is dominated by interconnected voids, forming a porous structure. In the subsequent bulk growth stage, the material growth is less sensitive to the deposition conditions, whereas the nanostructure becomes prevalent isolated defects. In the results of this study, different strategies for the plasma‐epi Si growth process for different applications are suggested. In these results, a better understanding of this new material may be provided and the discovery of various applications for bottom‐up‐grown porous Si is facilitated.

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Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

Dynamics of Plasma‐Assisted Epitaxial Silicon Growth Driven by a Hydrogen‐Incorporated Nanostructure for Novel Applications

Oh,

Lee,

Kim

et al. 2023

Small Structures

View full text Add to dashboard Cite

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

Gupta,

Min,

Lee

et al. 2024

Advanced Energy Materials

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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.

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Characteristics of high-order silane based Si and SiGe epitaxial growth under 600 ℃

Yoon,

Shin,

et al. 2024

Journal of Crystal Growth

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Fabrication of Crystalline Si Thin Films for Photovoltaics

Cited by 4 publications

References 136 publications

Dynamics of Plasma‐Assisted Epitaxial Silicon Growth Driven by a Hydrogen‐Incorporated Nanostructure for Novel Applications

Dynamics of Plasma‐Assisted Epitaxial Silicon Growth Driven by a Hydrogen‐Incorporated Nanostructure for Novel Applications

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

Characteristics of high-order silane based Si and SiGe epitaxial growth under 600 ℃

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