Effective passivation of silicon surfaces by ultrathin atomic-layer deposited niobium oxide

Macco, Bart; Bivour, Martin; Deijkers, J. H.; Basuvalingam, Saravana Balaji; Black, Lachlan E.; Melskens, Jimmy; Loo, Bas W. H. van de; Berghuis, Wilhelmus J. H.; Hermle, Martin; Kessels, W.M.M.

doi:10.1063/1.5029346

Cited by 26 publications

(24 citation statements)

References 27 publications

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“…These include the classical silicon-based compounds (SiO 2 , 1 SiN x , 2,3 and a-Si:H 4 ) as well as the more recently proven Al 2 O 3 , 5 AlN, 6 Ga 2 O 3 , 7 TiO 2 , 8 Ta 2 O 5 , 9 HfO 2 , 10 ZnO, 11 and Nb 2 O 5 . 12 Sometimes these materials are combined in stacks.…”

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confidence: 99%

POx/Al2O3 stacks: Highly effective surface passivation of crystalline silicon with a large positive fixed charge

Black

Kessels

2018

Applied Physics Letters

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Thin-film stacks of phosphorus oxide (POx) and aluminium oxide (Al2O3) are shown to provide highly effective passivation of crystalline silicon (c-Si) surfaces. Surface recombination velocities as low as 1.7 cm s−1 and saturation current densities J0s as low as 3.3 fA cm−2 are obtained on n-type (100) c-Si surfaces passivated by 6 nm/14 nm thick POx/Al2O3 stacks deposited in an atomic layer deposition system and annealed at 450 °C. This excellent passivation can be attributed in part to an unusually large positive fixed charge density of up to 4.7 × 1012 cm−2, which makes such stacks especially suitable for passivation of n-type Si surfaces.

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confidence: 99%

POx/Al2O3 stacks: Highly effective surface passivation of crystalline silicon with a large positive fixed charge

Black

Kessels

2018

Applied Physics Letters

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“…[1,2] The key to this contact technology is reducing recombination losses without increasing resistive losses. The passivating, carrier-selective functionality can be achieved using different materials systems, such as the stack of ultrathin dielectric layers including silicon oxide (SiO x ), [3] aluminum oxide (Al 2 O 3 ), [4][5][6] various transition metal oxides, [3,[5][6][7][8] and a stack of hydrogenated doped and undoped amorphous silicon (a-Si:H) layers. [9,10] Another effective approach is to use a very thin SiO x layer with a heavily doped polycrystalline silicon (poly-Si) layer, also known as a tunnel oxide passivated poly-Si contact (TOPCon) [11][12][13][14][15][16] or poly-Si on oxide (POLO).…”

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confidence: 99%

Process–Structure–Properties Relationships of Passivating, Electron‐Selective Contacts Formed by Atmospheric Pressure Chemical Vapor Deposition of Phosphorus‐Doped Polysilicon

Mousumi

Gregory

Ganesan

et al. 2022

Physica Rapid Research Ltrs

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Herein, we investigate the process–structure–properties relationships of in situ phosphorus (P)‐doped polycrystalline silicon (poly‐Si) films by atmospheric pressure chemical vapor deposition (APCVD) for fabricating poly‐Si passivating, electron selective contacts. This high‐throughput in‐line APCVD technique enables to achieve a low‐cost, simple manufacturing process for crystalline silicon (c‐Si) solar cells featuring poly‐Si passivating contact by excluding the need for vacuum/plasma environment, and additional post‐deposition doping steps. A thin layer of this P‐doped poly‐Si is deposited on an ultrathin (1.5 nm) silicon oxide (SiO x ) coated c‐Si substrate to fabricate the passivating contact. This is followed by various post‐deposition treatments, including a high‐temperature annealing step and hydrogenation process. The poly‐Si films are characterized to achieve a better understanding of the impacts of deposition process conditions and post‐deposition treatments on the microstructure, electrical conductivity, passivation quality, and carrier selectivity of the contacts which assists to identify the optimal process conditions. In this work, the optimized annealing process with post‐hydrogenation yields passivating contact with a saturation current density (J 0) of 3 fA cm−2 and an implied open‐circuit voltage (iV OC) of 712 mV on planar c‐Si wafer. Junction resistivity values ranging from 50 to 260 mΩ cm2 are realized for the poly‐Si contacts processed in the optimal annealing condition.

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“…Although the dopantfree approaches do not yet reach the >25 % efficiency level of the doped silicon layers [5], solar cell with metal oxide layers have in a span of a few years already demonstrated efficiencies in excess of 22 % [6]. Also more and more carrier-selective materials based on metal oxides (TiO2 [6], Nb2O5 [7], MO3 [8]), metal nitrides (TaN [9]) and metal fluorides (LiF [10]) are being developed for device applications. Further optimization and also further exploration of novel carrier-selective contacts therefore remains of importance to chart the potential of this dopant-free approach.…”

Section: Introductionmentioning

confidence: 99%

Low-Temperature Atomic Layer Deposited Magnesium Oxide as a Passivating Electron Contact for c-Si-Based Solar Cells

Chistiakova

Macco

Korte

2020

IEEE J. Photovoltaics

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In this work, we explore magnesium oxide (MgO) as electron-selective contact layer in silicon heterojunction solar cells. We report on the successful deposition of MgO layers by atomic layer deposition (ALD) at low temperatures ≤200 °C using Bis(ethylcyclopentadienyl)magnesium (Mg(CpEt)2 and H2O as precursors. Depositions were carried out on bare c-Si wafers and c-Si wafers with an intrinsic amorphous hydrogenated silicon (i-aSi:H) passivation layer. The resulting interfacial properties, surface passivation quality and contact resistivity were investigated. Upon initial deposition of MgO on an i-aSi:H/c-Si stack, the c-Si surface passivation degrades drastically. However, with an additional annealing step of 5 minutes at 200-250 °C it is possible to reverse the degradation and even to achieve charge carrier lifetimes in excess of those achieved with an i-aSi:H alone. Furthermore, we show that MgO forms an Ohmic contact with both MgO/i-aSi:H/c-Si and MgO/c-Si stacks, and we demonstrate solar cells using both types of stacks as electron contact layers.

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Effective passivation of silicon surfaces by ultrathin atomic-layer deposited niobium oxide

Cited by 26 publications

References 27 publications

POx/Al2O3 stacks: Highly effective surface passivation of crystalline silicon with a large positive fixed charge

POx/Al2O3 stacks: Highly effective surface passivation of crystalline silicon with a large positive fixed charge

Process–Structure–Properties Relationships of Passivating, Electron‐Selective Contacts Formed by Atmospheric Pressure Chemical Vapor Deposition of Phosphorus‐Doped Polysilicon

Low-Temperature Atomic Layer Deposited Magnesium Oxide as a Passivating Electron Contact for c-Si-Based Solar Cells

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