Ultrafast Colloidal Quantum Dot Infrared Photodiode

Xu, Qiwei; Meng, Lingju; Sinha, Kaustubh; Chowdhury, Farsad Imtiaz; Hu, Jun; Wang, Xihua

doi:10.1021/acsphotonics.0c00363

Cited by 48 publications

(49 citation statements)

References 44 publications

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“…Ranging between 0.6 and 1.6 µs, these rise and fall times are comparable to some of the fastest mature PbS QDPDs, for which times of a few µs have been reported. [ 48 , 49 , 50 ]…”

Section: Resultsmentioning

confidence: 99%

Colloidal III–V Quantum Dot Photodiodes for Short‐Wave Infrared Photodetection

et al. 2022

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Short‐wave infrared (SWIR) image sensors based on colloidal quantum dots (QDs) are characterized by low cost, small pixel pitch, and spectral tunability. Adoption of QD‐SWIR imagers is, however, hampered by a reliance on restricted elements such as Pb and Hg. Here, QD photodiodes, the central element of a QD image sensor, made from non‐restricted In(As,P) QDs that operate at wavelengths up to 1400 nm are demonstrated. Three different In(As,P) QD batches that are made using a scalable, one‐size‐one‐batch reaction and feature a band‐edge absorption at 1140, 1270, and 1400 nm are implemented. These QDs are post‐processed to obtain In(As,P) nanocolloids stabilized by short‐chain ligands, from which semiconducting films of n‐In(As,P) are formed through spincoating. For all three sizes, sandwiching such films between p‐NiO as the hole transport layer and Nb:TiO2 as the electron transport layer yields In(As,P) QD photodiodes that exhibit best internal quantum efficiencies at the QD band gap of 46±5% and are sensitive for SWIR light up to 1400 nm.

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“…Ranging between 0.6 and 1.6 µs, these rise and fall times are comparable to some of the fastest mature PbS QDPDs, for which times of a few µs have been reported. [ 48 , 49 , 50 ]…”

Section: Resultsmentioning

confidence: 99%

Colloidal III–V Quantum Dot Photodiodes for Short‐Wave Infrared Photodetection

et al. 2022

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“…With the well-passivated Si surface, we then proceeded to build Si:CQD heterojunction photodiodes. The PbS CQDs were synthesized via a hot-injection method according to previous reports 38 (also see the Methods section). The absorption spectrum of the PbS CQD in Figure 3a shows an exciton peak at 1290 nm (see Figure S6 for the transmission electron microscopic (TEM) image).…”

Section: Resultsmentioning

confidence: 99%

Silicon Surface Passivation for Silicon-Colloidal Quantum Dot Heterojunction Photodetectors

Cheong

Meng

et al. 2021

ACS Nano

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Sensitizing crystalline silicon (c-Si) with an infrared-sensitive material, such as lead sulfide (PbS) colloidal quantum dots (CQDs), provides a straightforward strategy for enhancing the infrared-light sensitivity of a Si-based photodetector. However, it remains challenging to construct a high-efficiency photodetector based upon a Si:CQD heterojunction. Herein, we demonstrate that Si surface passivation is crucial for building a high-performance Si:CQD heterojunction photodetector. We have studied one-step methyl iodine (CH 3 I) and two-step chlorination/methylation processes for Si surface passivation. Transient photocurrent (TPC) and transient photovoltage (TPV) decay measurements reveal that the two-step passivated Si:CQD interface exhibits fewer trap states and decreased recombination rates. These passivated substrates were incorporated into prototype Si:CQD infrared photodiodes, and the best performance photodiode based upon the two-step passivation shows an external quantum efficiency (EQE) of 31% at 1280 nm, which represents a near 2-fold increase over the standard device based upon the one-step CH 3 I passivated Si.

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“…This post-synthetic surface engineering leads to high carrier mobility (4×10 -2 cm 2 V -1 s -1 ) and improved device power conversion efficiency. 2) In 2014, Chuang et al [56] showed different ligands can be gained from the development and characterization of PbS nanocrystals and devices will facilitate their use for example in photodiode applications [164,165] or can be applied to the development of other nanocrystal chemistries for solar cells, such as leadhalide perovskites as well as non-toxic, lead-free nanocrystals such as AgBiS 2 , [166] Cu 2 S, [167] or Cu 3 BiS 3 nanocrystals. [168]…”

Section: Outlook: Realizing Nanocrystal Devicesmentioning

confidence: 99%

Nanocrystal Quantum Dot Devices: How the Lead Sulfide (PbS) System Teaches Us the Importance of Surfaces

Lin

Yarema

Liu

et al. 2021

Chimia

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Semiconducting thin films made from nanocrystals hold potential as composite hybrid materials with new functionalities. With nanocrystal syntheses, composition can be controlled at the sub-nanometer level, and, by tuning size, shape, and surface termination of the nanocrystals as well as their packing, it is possible to select the electronic, phononic, and photonic properties of the resulting thin films. While the ability to tune the properties of a semiconductor from the atomistic- to macro-scale using solution-based techniques presents unique opportunities, it also introduces challenges for process control and reproducibility. In this review, we use the example of well-studied lead sulfide (PbS) nanocrystals and describe the key advances in nanocrystal synthesis and thin-film fabrication that have enabled improvement in performance of photovoltaic devices. While research moves forward with novel nanocrystal materials, it is important to consider what decades of work on PbS nanocrystals has taught us and how we can apply these learnings to realize the full potential of nanocrystal solids as highly flexible materials systems for functional semiconductor thin-film devices. One key lesson is the importance of controlling and manipulating surfaces.

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Ultrafast Colloidal Quantum Dot Infrared Photodiode

Cited by 48 publications

References 44 publications

Colloidal III–V Quantum Dot Photodiodes for Short‐Wave Infrared Photodetection

Colloidal III–V Quantum Dot Photodiodes for Short‐Wave Infrared Photodetection

Silicon Surface Passivation for Silicon-Colloidal Quantum Dot Heterojunction Photodetectors

Nanocrystal Quantum Dot Devices: How the Lead Sulfide (PbS) System Teaches Us the Importance of Surfaces

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