Photo‐Responsive Molecular Junctions Activated by Perovskite/Graphene Heterostructure Electrode

Lee, Changjun; Kim, Junwoo; Lee, Jonghoon; Lee, Woo-Cheol; Song, Mingjun; Baek, Kyeong‐Yoon; Shin, Jungcheol; Nam, Jongwoo; Lee, Jeong-Jae; Kang, Keehoon; Lee, Takhee

doi:10.1002/adom.202200049

Cited by 4 publications

(4 citation statements)

References 71 publications

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“…This phenomenon can induce a range of interesting physical phenomena, such as an optically induced Stark effect, [20] large hysteresis on the gate voltage dependence of the graphene resistance, [19] and enhancement of the photoresponsivity. [21,22] However, to fully exploit the potential of perovskite/graphene structures, a comprehensive understanding of their properties is still needed. High magnetic fields are invaluable for interrogating fundamental physical processes Stable all-inorganic CsPbX 3 perovskite nanocrystals (PNCs) with high optical yield can be used in combination with graphene as photon sensors with high responsivity (up to 10 6 A W −1 ) in the VIS-UV range.…”

mentioning

confidence: 99%

Magnetic and Electric Field Dependent Charge Transfer in Perovskite/Graphene Field Effect Transistors

Cottam

Austin

Zhang

et al. 2022

Adv Elect Materials

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unique and outstanding optical properties such as high quantum yield (QY), strong absorption, and widely tunable band gap energy [8][9][10] accompanied by inexpensive solution processing techniques. [11][12][13] These PNCs have been successfully used in photon detectors operational in the visible wavelength range with photoresponsivity, R > 10 5 A W −1 , [14,15] and could offer further opportunities for UV applications. [16,17] Amongst device structures of particular interest are hybrid field effect transistors (FETs) that combine single-layer graphene (SLG) with PNCs. The performance of these devices, such as their response time, is affected by the slow, >1 s, redistribution of charge between the graphene layer and PNCs under light and/or electrostatic gating, [18,19] leading to the accumulation of a large amount of charge in the PNCs (7 × 10 12 cm −2 [19] ). This phenomenon can induce a range of interesting physical phenomena, such as an optically induced Stark effect, [20] large hysteresis on the gate voltage dependence of the graphene resistance, [19] and enhancement of the photoresponsivity. [21,22] However, to fully exploit the potential of perovskite/graphene structures, a comprehensive understanding of their properties is still needed. High magnetic fields are invaluable for interrogating fundamental physical processes Stable all-inorganic CsPbX 3 perovskite nanocrystals (PNCs) with high optical yield can be used in combination with graphene as photon sensors with high responsivity (up to 10 6 A W −1 ) in the VIS-UV range. The performance of these perovskite/graphene field effect transistors (FET) is mediated by charge transfer processes at the perovskite -graphene interface. Here, the effects of high electric (up to 3000 kV cm −1 ) and magnetic (up to 60 T) fields applied perpendicular to the graphene plane on the charge transfer are reported. The authors demonstrate electric-and magnetic-field dependent charge transfer and a slow (>100 s) charge dynamics. Magneto-transport experiments in constant (≈0.005 T s −1 ) and pulsed (≈1000 T s −1 ) magnetic fields reveal pronounced hysteresis effects in the transfer characteristics of the FET. A magnetic time is used to explain and model differences in device behavior under fast (pulsed) and slowly (continuous) changing magnetic fields. The understanding of the dynamics of the charge transfer in perovskite/graphene heterostructures developed here is relevant for exploitation of these hybrid systems in electronics and optoelectronics, including ultrasensitive photon detectors and FETs for metrology.

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confidence: 99%

Magnetic and Electric Field Dependent Charge Transfer in Perovskite/Graphene Field Effect Transistors

Cottam

Austin

Zhang

et al. 2022

Adv Elect Materials

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Section: Introductionmentioning

confidence: 99%

“…20 Takhee Lee et al reported photo-responsive molecular junctions enhanced by different intrinsic dipole moments. 21 The dipole interaction in a liquid environment could also influence the measured tunneling current by the STM break junction technique. [22][23][24] This paper demonstrates that the charge transport measurements under different aqueous solutions can, to a certain extent, recognize molecule-originated transport signals and be applied to studying the charge transport through fully hydrated proteins.…”

Section: Introductionmentioning

confidence: 99%

Conductive ionogel for the study of charge transport through SAM-based junctions in aqueous solution

Bai,

Chen,

Cao

et al. 2024

J. Mater. Chem. C

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“…the molecular-scale is the primary objective and a prerequisite toward realizing commercial molecular electronic device applications. [7][8][9][10][11][12][13][14] In this context, molecular optoelectronics have emerged as a promising field capable of controlling the device characteristics using light as a physical stimulus, as well as assisting the comprehension of the intrinsic transport behavior through the interaction between molecular orbital level and light. [11][12][13][15][16][17][18][19][20][21][22][23] In the infancy of this field, Yasutomu et al were the first to report molecular photodiode systems based on two different types of self-assembled monolayers (SAMs) of helical peptides possessing selective excitation molecular groups.…”

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confidence: 99%

Molecular Van Der Waals Heterojunction Photodiodes Enabling Dipole‐Induced Polarity Switching

Shin

Yang

et al. 2022

Small Methods

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Solid‐state devices capable of controlling light‐responsive charge transport at the molecular scale are essential for developing molecular optoelectronic technology. Here, a solid‐state molecular photodiode device constructed by forming van der Waals (vdW) heterojunctions between standard molecular self‐assembled monolayers and two‐dimensional semiconductors such as WSe2 is reported. In particular, two non‐functionalized molecular species used herein (i.e., tridecafluoro‐1‐octanethiol and 1‐octanethiol) enable bidirectional modulation of the interface band alignment with WSe2, depending on their dipole orientations. This dipole‐induced band modulation at the vdW heterointerface leads to the opposite change of both photoswitching polarity and rectifying characteristics. Furthermore, compared with other molecular or 2D photodiodes at a similar scale, these heterojunction devices exhibit significantly enhanced photo‐responsive performances in terms of photocurrent magnitude, open‐circuit potential, and switching speed. This study proposes a novel concept of the solid‐state molecular optoelectronic device with controlled functions and enhanced performances.

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Photo‐Responsive Molecular Junctions Activated by Perovskite/Graphene Heterostructure Electrode

Abstract: Research data are not shared.

Cited by 4 publications

References 71 publications

Magnetic and Electric Field Dependent Charge Transfer in Perovskite/Graphene Field Effect Transistors

Magnetic and Electric Field Dependent Charge Transfer in Perovskite/Graphene Field Effect Transistors

Conductive ionogel for the study of charge transport through SAM-based junctions in aqueous solution

Molecular Van Der Waals Heterojunction Photodiodes Enabling Dipole‐Induced Polarity Switching

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