Numerical analysis of single-point spectroscopy curves used in photo-carrier dynamics measurements by Kelvin probe force microscopy under frequency-modulated excitation

Garrillo, Pablo A. Fernández; Grévin, Benjamin; Borowik, Łukasz

doi:10.3762/bjnano.9.175

Cited by 3 publications

(2 citation statements)

References 21 publications

(38 reference statements)

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“…Last, the analysis of IM-KPFM data becomes a complex matter when the photocharging time is not negligible compared to the light pulse duration. In this case, numerical simulations are necessary to properly analyze the spectroscopic SP(f mod ) curves [18].…”

Section: Introductionmentioning

confidence: 99%

Implementation of data-cube pump–probe KPFM on organic solar cells

Grévin¹,

Bardagot²,

Demadrille³

2020

Beilstein J. Nanotechnol.

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An implementation of pump–probe Kelvin probe force microscopy (pp-KPFM) is reported that enables recording the time-resolved surface potential in single-point mode or over a 2D grid. The spectroscopic data are acquired in open z-loop configuration, which simplifies the pp-KPFM operation. The validity of the implementation is probed by measurements using electrical pumping. The dynamical photoresponse of a bulk heterojunction solar cell based on PTB7 and PC71BM is subsequently investigated by recording point-spectroscopy curves as a function of the optical power at the cathode and by mapping 2D time-resolved images of the surface photovoltage of the bare organic active layer.

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Section: Introductionmentioning

confidence: 99%

Implementation of data-cube pump–probe KPFM on organic solar cells

Grévin¹,

Bardagot²,

Demadrille³

2020

Beilstein J. Nanotechnol.

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“…Pablo A. Fernández Garrillo and co-workers go one step further by addressing photocarrier dynamics in order to study charge carrier lifetimes. This contribution focuses on a mathematical model to calculate time constants [3]. Such a model is critical for understanding the photophysics at the nanometer scale.…”

mentioning

confidence: 99%

Scanning probe microscopy for energy-related materials

Berger¹,

Grévin²,

Leclère³

et al. 2019

Beilstein J. Nanotechnol.

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Wafer‐Scale Fabrication of 2D β‐In₂Se₃ Photodetectors

Claro

Grzonka

Nicoara

et al. 2020

Advanced Optical Materials

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Nevertheless, the research of 2D materials is still in its early stages. The field started with graphene several years ago, [3] but more materials have been added continuously to the list. Among these, transition metal dichalcogenides (TMDC), [4] which have impressive optical properties in the visible range, are currently one of the most studied 2D materials. Devices made of these materials have shown remarkable performance as photodetectors, [5,6] nonvolatile random access memory, [7] or photovoltaics, [8] even when using simple manual exfoliation methods. More recently, 2D indium selenides (In x Se y) have gained attention, [9] due to their bandgap in the visible spectral region, comparable to TMDCs, but also due to several novel properties: InSe exhibits one of the largest mobilities of 2D semiconductor materials, [10] and β-In 2 Se 3 shows good mobility, [11] excellent photoresponsivity, [12] and exotic ferroelectricity [13] (the ordered ferroelectric phase is also called β′-In 2 Se 3 by some authors). [11,13] Transistors with high mobility and on/off ratio have already been realized. [14] Therefore, 2D In 2 Se 3 materials have the potential to address several limitations of the current silicon (Si) and III-V technologies, such as improved mobility and overall performance of transistors for electronics, as well as integrated photodetectors and light emitters in the same material system (same die), all possible on virtually any substrate, including transparent and flexible substrates. [15,16] Yet, the majority of reported devices from 2D materials rely on fabrication methods based on exfoliation and transfer of layers onto other substrates or other 2D materials. While this device fabrication process allows unprecedented flexibility in the combination of materials and therefore has nearly unlimited device design possibilities, [1] it leads typically to individual or few devices and is a slow and tedious process. On the other hand, due to their layered nature, instead of strong covalent bonds (as in Si and compound semiconductors) van der Waals forces exist between the layers. Hence, 2D materials can be grown epitaxially on substrates with completely different lattice constants without creating the strain and the defects commonly found in mismatched heteroepitaxy. This method is called van der Waals (vdW) epitaxy. [17] Nevertheless, the substrate does influence the growth, [18] as it modifies the nucleation of the first layer. Some substrates provide growth with superior quality (amount of defects, 2D materials are considered the future of electronics and photonics, stimulated by their remarkable performance. Among the 2D materials family, β-In 2 Se 3 shows good mobility, excellent photoresponsivity, and exotic ferroelectricity, making it suitable for a wide variety of applications. To date, most reported devices from 2D materials in general, and β-In 2 Se 3 in specific, rely on cumbersome fabrication methods using mechanical exfoliation and transfer of layers onto other substrates. However, for a successful ado...

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Numerical analysis of single-point spectroscopy curves used in photo-carrier dynamics measurements by Kelvin probe force microscopy under frequency-modulated excitation

Cited by 3 publications

References 21 publications

Implementation of data-cube pump–probe KPFM on organic solar cells

Implementation of data-cube pump–probe KPFM on organic solar cells

Scanning probe microscopy for energy-related materials

Wafer‐Scale Fabrication of 2D β‐In₂Se₃ Photodetectors

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Numerical analysis of single-point spectroscopy curves used in photo-carrier dynamics measurements by Kelvin probe force microscopy under frequency-modulated excitation

Cited by 3 publications

References 21 publications

Implementation of data-cube pump–probe KPFM on organic solar cells

Implementation of data-cube pump–probe KPFM on organic solar cells

Scanning probe microscopy for energy-related materials

Wafer‐Scale Fabrication of 2D β‐In2Se3 Photodetectors

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Wafer‐Scale Fabrication of 2D β‐In₂Se₃ Photodetectors