Carrier‐Selective Contact Based Silicon Solar Cells Processed at Room Temperature using Industrially Feasible Cz Wafers

Nayak, Mrutyunjay; Singh, Krishna Nand; Mudgal, Sapna; Mandal, Sourav; Singh, Surabhi; Komarala, Vamsi K.

doi:10.1002/pssa.201900208

Cited by 16 publications

(12 citation statements)

References 32 publications

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“…For this dilemma, the formation of a practically proper, sufficiently conducting contact at the metal electrode/Si interface requires an additional high-temperature post-annealing process after the electrode deposition. Nayak et al processed Si cells at room temperature based on the asymmetric heterocontact concept ( 10 ), but still had to use vacuumed thermal evaporation and sputtering facilities as well as a heating pretreatment ( 20 ).…”

Section: Introductionmentioning

confidence: 99%

An all ambient, room temperature–processed solar cell from a bare silicon wafer

et al. 2023

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Solar cells are a promising optoelectronic device for the simultaneous solution of energy-resource and environmental problems. However, their high cost and slow, laborious production process so far severely hinder a sufficient widespread of clean, renewable photovoltaic energy as a major alternative electricity generator. This undesirable situation is mainly attributed to the fact that photovoltaic devices have been manufactured through a series of vacuum and high-temperature processes. Here we realize a PEDOT:PSS/Si heterojunction solar cell fabricated only in ambient and room-temperature conditions from a plain Si wafer, with an over-10% energy conversion efficiency. Our production scheme is based on our finding that PEDOT:PSS photovoltaic layers actively operate even on highly doped Si substrates, which substantially mitigates the condition requirements for electrode implementation. Our approach may pave the way for facile, low-cost, high-throughput solar cell fabrication, useful in various fields even including developing countries and educational sites.

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Section: Introductionmentioning

confidence: 99%

An all ambient, room temperature–processed solar cell from a bare silicon wafer

et al. 2023

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“…Transition metal oxides are currently explored as hole-/ electron-selective contact options in silicon (Si) heterojunction solar cells. [1][2][3][4][5][6][7][8][9][10][11][12][13][14] Indeed, negligible parasitic absorption, tunable electronic properties, abundance, and low-cost deposition methods make these materials attractive for optoelectronic applications. Importantly, some of the transition metal oxides exhibit n-type conductivity due to energetically favorable oxygen (anion) vacancies (e.g., MoO 3 , V 2 O 5 , WO 3 , TiO 2 ); on the other hand, oxides like NiO or Cu 2 O behave as p-type due to energetically favorable metal cation vacancies.…”

Section: Introductionmentioning

confidence: 99%

Sub‐Stochiometric Nickel Oxide Hole‐Selective Contacts in Solar Cells: Comparison of Simulations and Experiments with Sputtered Films

Nayak

Bergum

Stan

et al. 2023

Physica Status Solidi (a)

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Sub‐stochiometric nickel oxide (NiOx) films were investigated as a hole selective contact option in silicon (Si) heterojunction solar cells. Numerical simulations were carried out to evaluate the impacts of the NiOx electronic properties variations and the NiOx/Si interface defect density (Dit) on device performance. Simulation data suggest that the best performance is achievable for wide bandgaps (Eg) and corresponding high valence band edge (EVB) positions in the NiOx films. Overall, in simulations, the performance remains practically unchanged for the nickel vacancy concentrations [VNi] = 1017–1021 cm−3, assuming high EVB and low Dit. The experimental data measured using NiOx films prepared by radio‐frequency magnetron sputtering reveal that the increase in [VNi] lifts the conductivity, concurrently decreasing Eg and EVB. As a result, we concluded that the performance of the fabricated sputtered NiOx/Si heterojunction solar cell is limited by high Dit as well as narrow Eg and low EVB.

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“…Carrier selective contacts (CSC) are being investigated to develop more low-cost photovoltaics (PVs) by reducing the thermal budget of the cell manufacturing process, as high temperature doping steps can be avoided in the CSC based cell fabrication [3][4][5]. Interface engineering to reduce recombination, large area deposition and low-cost fabrication methods are some of the major areas of research in carrier selective contact based heterojunction solar cells [6,7].…”

Section: Introductionmentioning

confidence: 99%

Spray deposited TiO₂thin films for large-area TiO₂/p-Si heterojunction solar cells

et al. 2021

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Carrier selective contacts (CSC) have the potential to lower the cost of photovoltaic (PV) cells. In the present work p-Si/TiO2 heterojunction solar cells have been fabricated using titanium dioxide (TiO2) as an electron-selective layer. Thin uniform anatase TiO2 films have been deposited using a commercially viable spray deposition technique over large area Si substrates. With a simple architecture of Al (200 nm fingers)/Al (15 nm thin film)/TiO2/c-Si(p)/Ag (200 nm), a highest conversion efficiency of 1.56 % has been achieved for the TiO2 carrier selective contact based solar cell with an active area of ~3.84 cm2. The minority carrier lifetime value of the TiO2 coated Si wafer was found to be less than that of the uncoated wafer, indicating the inability of the anatase TiO2 layer to provide surface passivation. Suns-VOC measurements yielded comparable values of the implied open circuit voltage for both the uncoated and the TiO2 coated Si wafers. Spray deposition technique can be used for scalable fabrication of carrier selective contact based heterojunction solar cells.

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Carrier‐Selective Contact Based Silicon Solar Cells Processed at Room Temperature using Industrially Feasible Cz Wafers

Cited by 16 publications

References 32 publications

An all ambient, room temperature–processed solar cell from a bare silicon wafer

An all ambient, room temperature–processed solar cell from a bare silicon wafer

Sub‐Stochiometric Nickel Oxide Hole‐Selective Contacts in Solar Cells: Comparison of Simulations and Experiments with Sputtered Films

Spray deposited TiO₂thin films for large-area TiO₂/p-Si heterojunction solar cells

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Carrier‐Selective Contact Based Silicon Solar Cells Processed at Room Temperature using Industrially Feasible Cz Wafers

Cited by 16 publications

References 32 publications

An all ambient, room temperature–processed solar cell from a bare silicon wafer

An all ambient, room temperature–processed solar cell from a bare silicon wafer

Sub‐Stochiometric Nickel Oxide Hole‐Selective Contacts in Solar Cells: Comparison of Simulations and Experiments with Sputtered Films

Spray deposited TiO2thin films for large-area TiO2/p-Si heterojunction solar cells

Contact Info

Product

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Spray deposited TiO₂thin films for large-area TiO₂/p-Si heterojunction solar cells