Surface passivation and carrier selectivity of the thermal-atomic-layer-deposited TiO<sub>2</sub> on crystalline silicon

Plakhotnyuk, Maksym; Schüler, Nadine; Shkodin, Evgeniy; Vijayan, Ramachandran Ammapet; Masilamani, S.; Varadharajaperumal, Muthubalan; Crovetto, Andrea; Hansen, Ole

doi:10.7567/jjap.56.08ma11

Cited by 21 publications

(18 citation statements)

References 58 publications

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“…Among them, ALD‐TiO x thin layers have been intensely investigated since it functions as a good passivation layer for c‐Si surface due to the low deposition damage to c‐Si surface and the ability to fabricate sub 5 nm thick films. Indeed, it is well known that the good passivation performance is provided by the ALD‐TiO x /c‐Si heterocontact after postannealing at about 300 °C . We reported that the origin of improved passivation by postannealing is effusion of hydrogen and hydrogenated molecules from H‐terminated c‐Si and subsequent formation of a silicon oxide (SiO x ) layer at the TiO x /c‐Si interface .…”

Section: Influence Of the Siox Interlayers Prepared By Different Chemmentioning

confidence: 99%

Local Structure of High Performance TiO_x Electron‐Selective Contact Revealed by Electron Energy Loss Spectroscopy

Mochizuki

Gotoh

Kurokawa

et al. 2018

Adv Materials Inter

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Section: Influence Of the Siox Interlayers Prepared By Different Chemmentioning

confidence: 99%

Local Structure of High Performance TiO_x Electron‐Selective Contact Revealed by Electron Energy Loss Spectroscopy

Mochizuki

Gotoh

Kurokawa

et al. 2018

Adv Materials Inter

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“…Thus, employing TiO x as an electron selective contact, they also achieved good surface passivation and demonstrated the development of improved c‐Si solar cells with efficiency as high as ≈21.6%, and with a potential of achieving 23.7% efficiency . Thomson and McIntosh and Plakhotnyuk et al have also observed good surface passivation and carrier selectivity with TiO 2 on c‐Si. While interesting functional characteristics have been realized with TiO x dielectric, the fundamental nature of the c‐Si/TiO x interface and the structural behavior of TiO x still remain unclear, thus limiting both scientific and technological development.…”

Section: Introductionmentioning

confidence: 96%

“…In recent years, the search continued to find novel dielectrics with multifunctional capabilities in order to further alleviate the surface recombination, enhance the efficiency, and reduce the cost of c‐Si solar cells. Titanium oxide (TiO x ) is one such emerging dielectric for c‐Si solar cells due to its excellent optical properties, remarkable carrier selectivity, and excellent surface passivation features . Liao et al and Gad et al have previously demonstrated that atomic layer deposited (ALD) TiO x is able to provide excellent surface passivation on c‐Si surfaces, in addition to its ideal optical properties (refractive index of ≈2.4 at a wavelength of 632.8 nm and a relatively low absorption in the visible wavelength range) to be used as an antireflection coating (ARC) for encapsulated silicon wafer solar cells.…”

Section: Introductionmentioning

confidence: 99%

Evidence for Chemicals Intermingling at Silicon/Titanium Oxide (TiO_x) Interface and Existence of Multiple Bonding States in Monolithic TiO_x

Dwivedi

Yeo

Tan

et al. 2018

Adv Funct Materials

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Metal oxides (MOs) are used in photovoltaics and microelectronics as surface passivating layers and gate dielectrics, respectively. The effectiveness of MOs predominantly depends on their structure and the nature of the semiconductor/MO (S/MO) interface. While some efforts are made to analyze interface behavior of a few MOs, greater fundamental understanding on the interface and structural behaviors of emerging MOs is yet to be established for enhanced scientific and technological developments. Here, the structure of atomic layer deposited titanium oxide (TiO x ) and the nature of the c-Si/ TiO x interface on the atomic-to nanoscale are probed. A new breed of mixed oxide (SiO x +TiO x ) interfacial layer with a thickness of ≈1.3 nm at the c-Si/ TiO x interface is discovered, and its thickness further increases to ≈1.5 nm after postdeposition annealing. It is observed that both as-deposited and annealed monolithic TiO x films comprise multiple bonding states at varying film thickness, with an oxygen-deficient TiO x layer located close to the mixed oxide/TiO x interface. The stoichiometry of this layer improves when reaching the middle and near surface regions of the TiO x layer, respectively. This work uncovers several critical structural and interface aspects of TiO x , and thus creates opportunities to control and design improved photovoltaic and electronic devices for future development.

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“…Two explanations may be plausible here: (i) photogenerated holes near the bottom of the CBTS film are trapped in the Cu 4 BaS 3 /BaSn 2 S 3 phases and can only escape under a high electric field, and (ii) there is a barrier at the Ti(O,N)/PolySi interface or at the Ti(O,N)/CBTS interface. We note that the pure oxide TiO 2 is typically used as an electron contact, even for CBTS devices, , so the Ti(O,N)/CBTS hole contact may be the most likely location of a barrier to carrier transport.…”

Section: Resultsmentioning

confidence: 99%

TaS₂ Back Contact Improving Oxide-Converted Cu₂BaSnS₄ Solar Cells

Crovetto

Børsting

Nielsen

et al. 2019

ACS Appl. Energy Mater.

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Solar cells based on the wide band-gap Cu 2 BaSnS 4 (CBTS) photoabsorber have achieved open circuit voltages up to 1.1 V over a short development period, making CBTS an attractive material for tandem photovoltaic and photoelectrochemical cells. In this work, we explore an alternative CBTS growth route based on oxide precursors, and we propose TaS 2 as an alternative back contact material to the commonly used Mo/MoS 2 . The oxide precursor route does not require higher sulfurization temperatures than other more common fabrication routes, and it yields CBTS lms with negligible Stokes shift between photoluminescence maximum and band gap energy, while at the same time avoiding sulfur contamination of vacuum systems. The high work-function metallic TaS 2 compound is selected as a prospective hole-selective contact, which could also prevent the losses associated with carrier transport across the semiconducting MoS 2 layer. By comparing CBTS solar cells with Mo and TaS 2 back contacts, the latter shows 1 Page 1 of 29 ACS Paragon Plus Environment ACS Applied Energy Materials a signicantly lower series resistance, resulting in a 10% relative eciency improvement.Finally, we fabricate a proof-of-concept monolithic CBTS/Si tandem cell using a thin Ti(O,N) interlayer intended both as a diusion barrier and as a recombination layer between the two subcells.

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Surface passivation and carrier selectivity of the thermal-atomic-layer-deposited TiO₂ on crystalline silicon

Cited by 21 publications

References 58 publications

Local Structure of High Performance TiO_x Electron‐Selective Contact Revealed by Electron Energy Loss Spectroscopy

Local Structure of High Performance TiO_x Electron‐Selective Contact Revealed by Electron Energy Loss Spectroscopy

Evidence for Chemicals Intermingling at Silicon/Titanium Oxide (TiO_x) Interface and Existence of Multiple Bonding States in Monolithic TiO_x

TaS₂ Back Contact Improving Oxide-Converted Cu₂BaSnS₄ Solar Cells

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Surface passivation and carrier selectivity of the thermal-atomic-layer-deposited TiO2 on crystalline silicon

Cited by 21 publications

References 58 publications

Local Structure of High Performance TiOx Electron‐Selective Contact Revealed by Electron Energy Loss Spectroscopy

Local Structure of High Performance TiOx Electron‐Selective Contact Revealed by Electron Energy Loss Spectroscopy

Evidence for Chemicals Intermingling at Silicon/Titanium Oxide (TiOx) Interface and Existence of Multiple Bonding States in Monolithic TiOx

TaS2 Back Contact Improving Oxide-Converted Cu2BaSnS4 Solar Cells

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Surface passivation and carrier selectivity of the thermal-atomic-layer-deposited TiO₂ on crystalline silicon

Local Structure of High Performance TiO_x Electron‐Selective Contact Revealed by Electron Energy Loss Spectroscopy

Local Structure of High Performance TiO_x Electron‐Selective Contact Revealed by Electron Energy Loss Spectroscopy

Evidence for Chemicals Intermingling at Silicon/Titanium Oxide (TiO_x) Interface and Existence of Multiple Bonding States in Monolithic TiO_x

TaS₂ Back Contact Improving Oxide-Converted Cu₂BaSnS₄ Solar Cells