Infrared Photodetectors Based on 2D Materials and Nanophotonics

Zha, Jiajia; Luo, Mingcheng; Ye, Ming; Ahmed, Tanveer; Yu, Xuechao; Lien, Der‐Hsien; He, Qiyuan; Lei, Dangyuan; Ho, Johnny C.; Bullock, James; Crozier, Kenneth B.; Tan, Chaoliang

doi:10.1002/adfm.202111970

Cited by 128 publications

(102 citation statements)

References 235 publications

(513 reference statements)

Supporting

Mentioning

Contrasting

Order By: Relevance

“…Layered 2D crystals exploiting the photovoltaic effect [44] are emerging as excellent candidates for both solar cells, and as photodetectors down to the near-infrared region. [45] Photovoltaic P → E energy conversion can be enhanced in 2D semiconductor crystals compared to bulk semiconductors due to their unique properties. First, 2D crystals can easily form material junctions by layering 2D crystals on bulk materials or by layering different 2D crystals.…”

Section: Conventional Photovoltaic Effectmentioning

confidence: 99%

See 1 more Smart Citation

Energy Interplay in Materials: Unlocking Next‐Generation Synchronous Multisource Energy Conversion with Layered 2D Crystals

et al. 2022

View full text Add to dashboard Cite

Layered 2D crystals have unique properties and rich chemical and electronic diversity, with over 6000 2D crystals known and, in principle, millions of different stacked hybrid 2D crystals accessible. This diversity provides unique combinations of properties that can profoundly affect the future of energy conversion and harvesting devices. Notably, this includes catalysts, photovoltaics, superconductors, solar‐fuel generators, and piezoelectric devices that will receive broad commercial uptake in the near future. However, the unique properties of layered 2D crystals are not limited to individual applications and they can achieve exceptional performance in multiple energy conversion applications synchronously. This synchronous multisource energy conversion (SMEC) has yet to be fully realized but offers a real game‐changer in how devices will be produced and utilized in the future. This perspective highlights the energy interplay in materials and its impact on energy conversion, how SMEC devices can be realized, particularly through layered 2D crystals, and provides a vision of the future of effective environmental energy harvesting devices with layered 2D crystals.

show abstract

Section: Conventional Photovoltaic Effectmentioning

confidence: 99%

“…Layered 2D crystals exploiting the photovoltaic effect [ 44 ] are emerging as excellent candidates for both solar cells, and as photodetectors down to the near‐infrared region. [ 45 ]…”

Section: Energy Conversion Mechanisms In Layered 2d Crystalsmentioning

confidence: 99%

Energy Interplay in Materials: Unlocking Next‐Generation Synchronous Multisource Energy Conversion with Layered 2D Crystals

et al. 2022

View full text Add to dashboard Cite

show abstract

“…Compared with graphene photodetectors, [200][201][202] photodetectors made of ultra-thin layered materials have a higher light response and spectral selectivity. 61,203,204 ZnO is a metal oxide semiconductor with great research value. 205,206 Compared with other competitive materials, ZnO has a larger exciton binding energy (60 meV) than GaN (26 meV).…”

Section: Photodetectorsmentioning

confidence: 99%

“…Compared with graphene photodetectors, 200–202 photodetectors made of ultra-thin layered materials have a higher light response and spectral selectivity. 61,203,204…”

Section: Applicationsmentioning

confidence: 99%

Progress on two-dimensional binary oxide materials

Yang

Iqbal

et al. 2022

Nanoscale

View full text Add to dashboard Cite

show abstract

“…[1][2][3][4] These merits lead 2D materials to be expected to replace traditional photodetectors with the drawbacks of fragile quality, limited pixel size, and low-temperature operation in infrared region. [5][6][7] 2D layered materials have demonstrated attractive photoelectric properties, such as broadband detection, high photoresponsivity, high external quantum efficiency (EQE), high specific detectivity, and fast photoresponse, and thus could be promising candidates for future photodetectors in flexible electronics, biological imaging, and environmental monitoring. [8][9][10][11] However, the efficiency of photon trapping in 2D materials is relatively low.…”

mentioning

confidence: 99%

Epitaxial Growth of 2D Ternary Copper–Indium–Selenide Nanoflakes for High‐Performance Near‐Infrared Photodetectors

Gan

Hao

Liu

et al. 2022

Advanced Optical Materials

View full text Add to dashboard Cite

and chemical properties, including dangling-bond-free surface, atomic thickness, flexibility, high mobility, and tunable band gap. [1][2][3][4] These merits lead 2D materials to be expected to replace traditional photodetectors with the drawbacks of fragile quality, limited pixel size, and low-temperature operation in infrared region. [5][6][7] 2D layered materials have demonstrated attractive photoelectric properties, such as broadband detection, high photoresponsivity, high external quantum efficiency (EQE), high specific detectivity, and fast photoresponse, and thus could be promising candidates for future photodetectors in flexible electronics, biological imaging, and environmental monitoring. [8][9][10][11] However, the efficiency of photon trapping in 2D materials is relatively low. [12] Lots of efforts have been taken to improve the efficiency of photon trapping, such as constructing heterostructures with n-dimensional (n = 0, 1, 2) materials. [1] On the other hand, searching for new members of more photon-sensitive 2D materials is another effective way to improve the photodetector characteristics. [13][14][15] Initially, research was focused on single or binary elemental 2D materials, such as black phosphorus and transition metal dichalcogenides. Subsequently, ternary 2D materials have attracted increasing attention because of the flexibility to tune their composition and the emerging intriguing physical properties. [15][16][17] Devices based on ternary layered materials have exhibited outstanding photoelectric characteristics, which indicates that ternary 2D materials have promising applications in future photoelectric devices. [14,15] The copper-indium-selenium (CIS) system is composed of a series of typical ternary materials. The structure and physical properties of CIS can be tuned by changing the ratio of Cu/ In, and CIS materials are widely used as a light absorption layer in solar-energy applications. [18][19][20][21] Normally, CIS structures are n-type semiconductors with a direct band gap, except for CuInSe 2 which is a p-type semiconductor, and their Hall mobilities can reach 2.3 × 10 3 cm 2 V −1 s −1 . [22][23][24][25] CIS compounds usually have a chalcopyrite structure with different ordered vacancies. When the Cu/In ratio is between 1:5 and 1:9, the CIS system can contain layered structures. [17] Layered CIS nanoflakes such as CuIn 7 Se 11 can be exfoliated from the bulk single crystals, and they have been constructed into 2D semiconductors are promising for future photodetectors because of their dangling-bond-free surface, atomic thickness, tunable bandgap, high mobility, and flexible nature. However, the low light absorption is one of the main limits for the practical applications of 2D materials. Lots of efforts have been taken to optimize the light absorption, for example, constructing heterojunctions and exploring more photo-sensitive 2D materials. Here, the epitaxial growth of layered copper-indium-selenide (CIS) nanoflakes is realized by chemical vapor deposition. The CIS nanoflakes ar...

show abstract

Infrared Photodetectors Based on 2D Materials and Nanophotonics

Cited by 128 publications

References 235 publications

Energy Interplay in Materials: Unlocking Next‐Generation Synchronous Multisource Energy Conversion with Layered 2D Crystals

Energy Interplay in Materials: Unlocking Next‐Generation Synchronous Multisource Energy Conversion with Layered 2D Crystals

Progress on two-dimensional binary oxide materials

Epitaxial Growth of 2D Ternary Copper–Indium–Selenide Nanoflakes for High‐Performance Near‐Infrared Photodetectors

Contact Info

Product

Resources

About