Dirk Döhler scite author profile

The combination of oxide and heavier chalcogenide layers in thin film photovoltaics suffers limitations associated with oxygen incorporation and sulfur deficiency in the chalcogenide layer or with a chemical incompatibility which results in dewetting issues and defect states at the interface. Here, we establish atomic layer deposition (ALD) as a tool to overcome these limitations. ALD allows one to obtain highly pure Sb2S3 light absorber layers, and we exploit this technique to generate an additional interfacial layer consisting of 1.5 nm ZnS. This ultrathin layer simultaneously resolves dewetting and passivates defect states at the interface. We demonstrate via transient absorption spectroscopy that interfacial electron recombination is one order of magnitude slower at the ZnS-engineered interface than hole recombination at the Sb2S3/P3HT interface. The comparison of solar cells with and without oxide incorporation in Sb2S3, with and without the ultrathin ZnS interlayer, and with systematically varied Sb2S3 thickness provides a complete picture of the physical processes at work in the devices.

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Atomic Layer Deposition from Dissolved Precursors

Döhler

Barr

et al. 2015

Nano Lett.

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We establish a novel thin film deposition technique by transferring the principles of atomic layer deposition (ALD) known with gaseous precursors toward precursors dissolved in a liquid. An established ALD reaction behaves similarly when performed from solutions. "Solution ALD" (sALD) can coat deep pores in a conformal manner. sALD offers novel opportunities by overcoming the need for volatile and thermally robust precursors. We establish a MgO sALD procedure based on the hydrolysis of a Grignard reagent.

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Preparation and physical properties of soft magnetic nickel-cobalt three-segmented nanowires

Bochmann

Döhler

Trapp

et al. 2018

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We establish a method to produce cylindrical magnetic nanowires displaying several segments, with a large versatility in terms of segment diameter and length. It is based on electroplating in alumina templates, the latter being prepared by several steps of anodization, wet etching and atomic layer deposition to produce, widen or shrink pores, respectively. We propose an analytical model to analyze the in-plane and out-of-plane magnetization loops of dense assemblies of multisegmented wires. The model considers inter-wires dipolar fields, end-domain curling and predicts the switching field of individual wires with no adjustable parameter. Its ingredients are crucial to extract reliable parameters from the fitting of loops, such as magnetization or the porosity of the array.

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ZnS Ultrathin Interfacial Layers for Optimizing Carrier Management in Sb₂S₃-based Photovoltaics

Büttner

Scheler

Pointer

et al. 2021

ACS Appl. Mater. Interfaces

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Antimony chalcogenides represent a family of materials of low toxicity and relative abundance, with a high potential for future sustainable solar energy conversion technology. However, solar cells based on antimony chalcogenides present open-circuit voltage losses that limit their efficiencies. These losses are attributed to several recombination mechanisms, with interfacial recombination being considered as one of the dominant processes. In this work, we exploit atomic layer deposition (ALD) to grow a series of ultrathin ZnS interfacial layers at the TiO 2 /Sb 2 S 3 interface to mitigate interfacial recombination and to increase the carrier lifetime. ALD allows for very accurate control over the ZnS interlayer thickness on the ångström scale (0–1.5 nm) and to deposit highly pure Sb 2 S 3 . Our systematic study of the photovoltaic and optoelectronic properties of these devices by impedance spectroscopy and transient absorption concludes that the optimum ZnS interlayer thickness of 1.0 nm achieves the best balance between the beneficial effect of an increased recombination resistance at the interface and the deleterious barrier behavior of the wide-bandgap semiconductor ZnS. This optimization allows us to reach an overall power conversion efficiency of 5.09% in planar configuration.

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A solution-based ALD route towards (CH₃NH₃)(PbI₃) perovskite via lead sulfide films

et al. 2019

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Dirk Döhler

Adjusting Interfacial Chemistry and Electronic Properties of Photovoltaics Based on a Highly Pure Sb₂S₃ Absorber by Atomic Layer Deposition

Atomic Layer Deposition from Dissolved Precursors

Preparation and physical properties of soft magnetic nickel-cobalt three-segmented nanowires

ZnS Ultrathin Interfacial Layers for Optimizing Carrier Management in Sb₂S₃-based Photovoltaics

A solution-based ALD route towards (CH₃NH₃)(PbI₃) perovskite via lead sulfide films

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Dirk Döhler

Adjusting Interfacial Chemistry and Electronic Properties of Photovoltaics Based on a Highly Pure Sb2S3 Absorber by Atomic Layer Deposition

Atomic Layer Deposition from Dissolved Precursors

Preparation and physical properties of soft magnetic nickel-cobalt three-segmented nanowires

ZnS Ultrathin Interfacial Layers for Optimizing Carrier Management in Sb2S3-based Photovoltaics

A solution-based ALD route towards (CH3NH3)(PbI3) perovskite via lead sulfide films

Contact Info

Product

Resources

About

Adjusting Interfacial Chemistry and Electronic Properties of Photovoltaics Based on a Highly Pure Sb₂S₃ Absorber by Atomic Layer Deposition

ZnS Ultrathin Interfacial Layers for Optimizing Carrier Management in Sb₂S₃-based Photovoltaics

A solution-based ALD route towards (CH₃NH₃)(PbI₃) perovskite via lead sulfide films