Atomic Layer Deposition of ZnO on InP Quantum Dot Films for Charge Separation, Stabilization, and Solar Cell Formation

Crisp, Ryan W.; Hashemi, Fatemeh; Alkemade, J.; Kirkwood, Nicholas; Grimaldi, Gianluca; Kinge, Sachin; Siebbeles, Laurens D. A.; Ommen, J. Ruud van; Houtepen, Arjan J.

doi:10.1002/admi.201901600

Cited by 26 publications

(21 citation statements)

References 79 publications

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“…In addition to above-mentioned NBG QDs delivering considerable photovoltaic performance, there are some binary QDs that currently offer petty results with modest PCEs but have development potential, such as SnS, [59,[168][169][170][171] FeS 2 , [60,[172][173][174] Bi 2 S 3 , [175] HgTe, [62,176,177] InAs, [63] InP, [178,179] etc. Table 6 summarizes the recent reports of photovoltaic performance for these potential binary QD-based QDSCs.…”

Section: Other Potential Binary Quantum Dotsmentioning

confidence: 99%

“…[176] The use of III-V InAs and InP QDs as light harvesting materials yields relatively low PCEs either in sensitized nanocrystalline TiO 2 solar cells or heterojunction devices. [63,178,179] Future optimization of the device interfaces, together with improved quality of QDs, should lead to much enhanced photovoltaic performance.…”

Section: Other Potential Binary Quantum Dotsmentioning

confidence: 99%

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Near‐Infrared Photoactive Semiconductor Quantum Dots for Solar Cells

Zhou

Luo

et al. 2021

Advanced Energy Materials

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Section: Other Potential Binary Quantum Dotsmentioning

confidence: 99%

Section: Other Potential Binary Quantum Dotsmentioning

confidence: 99%

Near‐Infrared Photoactive Semiconductor Quantum Dots for Solar Cells

Zhou

Luo

et al. 2021

Advanced Energy Materials

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“…Note that InP QD, one of the III‐V with higher bulk bandgap, when used in solar cell, provides only around 1% efficiency due to inadequate bandgap and insufficient surface treatment. [ 110,111 ] Nevertheless, the development of III‐V QDs for PVs faces numerous obstacles. [ 112,113 ] First, there are numerous trap sites from intractable bonds and surfaces.…”

Section: Eco‐friendly Materials Design For Qd Pvsmentioning

confidence: 99%

Design Strategy of Quantum Dot Thin‐Film Solar Cells

Kim

Lim

Yun

et al. 2020

Small

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Quantum dots (QDs) are emerging photovoltaic materials that display exclusive characteristics that can be adjusted through modification of their size and surface chemistry. However, designing a QD‐based optoelectronic device requires specialized approaches compared with designing conventional bulk‐based solar cells. In this paper, design considerations for QD thin‐film solar cells are introduced from two different viewpoints: optics and electrics. The confined energy level of QDs contributes to the adjustment of their band alignment, enabling their absorption characteristics to be adapted to a specific device purpose. However, the materials selected for this energy adjustment can increase the light loss induced by interface reflection. Thus, management of the light path is important for optical QD solar cell design, whereas surface modification is a crucial issue for the electrical design of QD solar cells. QD thin‐film solar cell architectures are fabricated as a heterojunction today, and ligand exchange provides suitable doping states and enhanced carrier transfer for the junction. Lastly, the stability issues and methods on QD thin‐film solar cells are surveyed. Through these strategies, a QD solar cell study can provide valuable insights for future‐oriented solar cell technology.

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“…Recently, Algadi et al employed a 10 nm thick ZnO IL in indium tin oxide (ITO)/InP Schottky photodetectors and they attributed the improved efficiency to the hole barrier by the valence band offset at the ZnO/InP interface [25]. About 14 nm thick ZnO encapsulation layer for InP quantum dots was found to improve the solar cell performance [26]. Zhu et al deposited ZnO/AlN (220 nm/1.9-11.4 nm) stacks on Ti substrate and found the improved piezo-electric performance [27].…”

Section: Introductionmentioning

confidence: 99%

Barrier reduction and current transport mechanism in Pt/n-InP Schottky diodes using atomic layer deposited ZnO interlayer

Kim

Jung

Choi

2021

J Mater Sci: Mater Electron

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Modification of interface properties in Pt/n-InP Schottky contacts with atomic layer deposited ZnO interlayer (IL) (5 and 10 nm) has been carried out and the electrical properties were investigated using current-voltage (I-V) and capacitance-voltage (C-V) techniques. The insertion of ZnO IL in the Pt/n-InP interface reduced the effective barrier height. The barrier heights from C-V method were higher with respect to those from I-V method. The interface state density for 5 nm thick ZnO was higher than that for 10 nm thick ZnO. The barrier heights according to thermionic field emission model showed much closer to those from C-V method. Surface passivation and interfacial dipole were suggested to modulate the Schottky barrier at the Pt/ZnO/n-InP interface.

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Atomic Layer Deposition of ZnO on InP Quantum Dot Films for Charge Separation, Stabilization, and Solar Cell Formation

Cited by 26 publications

References 79 publications

Near‐Infrared Photoactive Semiconductor Quantum Dots for Solar Cells

Near‐Infrared Photoactive Semiconductor Quantum Dots for Solar Cells

Design Strategy of Quantum Dot Thin‐Film Solar Cells

Barrier reduction and current transport mechanism in Pt/n-InP Schottky diodes using atomic layer deposited ZnO interlayer

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