Infrared and Laser Engineering, Volume. 51, Issue 1, 20210826(2022)
Research progress of micro-nano structures enhanced infrared detectors (Invited)
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![Infrared detectors with micro-holes on silicon substrates[19-21]; (a) Schematic diagram of Si-Ge optoelectronic device with micro-hole array structures[19]; (b) External quantum efficiency enhancement coefficient and responsivity in the 1 200-1 800 nm band of the Si-Ge device[19];(c) Schematic diagram of a silicon single-photon avalanche detector with micro-hole array structures[20]; (d) External quantum efficiency of devices of different sizes[20]; (e) Schematic diagram of conformal graphene/silicon nanopore detector[21] ; (f) Photoelectric response of silicon nanopore, graphene/silicon and conformal graphene/silicon nanopore detectors[21]](/Images/icon/loading.gif){kind=icon}
Fig. 1. Infrared detectors with micro-holes on silicon substrates[19-21]; (a) Schematic diagram of Si-Ge optoelectronic device with micro-hole array structures[19]; (b) External quantum efficiency enhancement coefficient and responsivity in the 1 200-1 800 nm band of the Si-Ge device[19];(c) Schematic diagram of a silicon single-photon avalanche detector with micro-hole array structures[20]; (d) External quantum efficiency of devices of different sizes[20]; (e) Schematic diagram of conformal graphene/silicon nanopore detector[21] ; (f) Photoelectric response of silicon nanopore, graphene/silicon and conformal graphene/silicon nanopore detectors[21]
Fig. 2. (a) A schematic diagram of a silicon photodiode integrated with a micro-holes[22]; (b) SEM images of holes of different shapes integrated in the photodiode, including square holes, hexagonal holes, cylindrical and funnel shapes[22]; (c) Scanning electron microscope picture of the active area of the photodiode[22]; (d) A schematic diagram of a silicon photodetector with integrated micro structures[23]; (e) Top and cross-sectional views of the funnel-shaped and inverted pyramid-shaped light trapping structures[23]; (f) Relationship between the external quantum efficiency and the number of nano-holes[23]
Fig. 3. Mid-wave infrared detector samples of HgCdTe with microstructures of different filling factors[24]
Fig. 4. Structure and photoelectric characteristics of different types of nanorods near infrared photodetectors[26-29]. (a)
Fig. 5. Structures and performances of enhanced infrared detectors with different types of surface metal microstructures[34-37]. (a) Structure diagram of the aysmmetric infrared plasma detector(SEM image and electric field intensity enhancement coefficient)[34] ; (b) Schematic diagram of the two-color infrared detector with cross stars(SEM image and reflection curve)[35];(c) Schematic diagram of the square-hole plasma long-wave infrared detector(SEM image and curve of absorption enhancement factor)[36]; (d) Schematic diagram of the plasma cavity quantum well infrared detector(SEM image and absorption enhancement spectrum)[37]
Fig. 6. Structures and performance of several types of hot-electron infrared detectors with metal meta-surface[43-46]. (a) Structure diagram, SEM image and photoelectrical properties of local plasmon thermal electron injection photodetector[43]; (b) Structure diagram and quantum efficiency curve of plasmon thermoelectron photodetector based on surface plasma[44]; (c) Schematic diagram and spectral response of all-silicon thermoelectronic photodetector[45]; (d) Structure diagram and absorption curve of a wide band thermo-electron photodetector[46]
Fig. 8. Structures and performance of plasmonic cavity enhanced 2D materials infrared detectors with micro-structure [54-56]. (a) Schematic diagram of plasma cavity structure and absorption curve of graphene[54]; (b) Schematic diagram and absorption curve of hybrid grating Fabry-Perot structure integrated with graphene film[55]; (c) Schematic diagram of gold nanostructure plasmonic cavity and absorption curve of black phosphorus[56]
Fig. 9. Structures and performance of three kinds of heavily doped semiconducting plasma detectors[61-63]. (a) Structures of heavily doped plasmonic detector, distribution of electrical field and curve of EQE[61]; (b) Schematic diagram of ultra-thin enhanced absorption long-wave infrared detector(band-structure schematics and the absorption curve)[62] ; (c) Schematic diagram of a single-cycle GMR detector (Scanning electron micrographs and detectability curves of cross-sections)[63]
Table 1. Classification and progress of micro-nano structure enhanced infrared detectors
View tableView in ArticleTable 1. Classification and progress of micro-nano structure enhanced infrared detectors
Structure type Principle Wavelength /μm Responsivity/(A/W) D*/cm·Hz1/2·W−1 Dielectric Silicon substrate Increasing the effective propagation path by multiple reflections and scatterings 0.8-1.8[ 19 -23 ]0.91[ 19 ]1.25×1011 [ 21 ]HgCdTe 1-5[ 24 ]1-2[ 24 ]NETD:50 mK[ 24 ]Nanowires 1-1.65[ 26 ]1.5[ 26 ]2.52×1014 [ 26 ]Surface metal Meta-surface SPP and LSP are excited at resonant wavelength to improve optical field density and enhance the absorption; 3-12[ 34 -37 ]7 [ 37 ]7.4×1010 [ 37 ]LSP hot electrons 1.2~1.6[ 43 ]8×10-6[ 43 ]2.4×107 [ 46 ]SPP hot electrons 0.8-1.6[ 45 ]9×10-2[ 45 ]4.38 ×1011[ 45 ]3D plasma cavity Semi-conductor cavity Strong local enhancement and near-field coupling effect in the absorption layer of multi-layer cavity 4-11[ 51 ]2[ 51 ]6.06 ×1010[ 51 ]Quantum well cavity 11-14[ 52 ]0.6[ 52 ]8.52 ×109[ 52 ]2D material cavity 3-14[ 54 -56 ]0.32[ 55 ]——
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Peng Zhu, Lei Xiao, Tai Sun, Haofei Shi. Research progress of micro-nano structures enhanced infrared detectors (Invited)[J]. Infrared and Laser Engineering, 2022, 51(1): 20210826
Paper Information
Category: Infrared technology and application
Received: Oct. 25, 2021
Accepted: --
Published Online: Mar. 8, 2022
The Author Email: Shi Haofei (shi @cigit.ac.cn)
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