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SWIR 이미지 센서 기술개발 동향 및 응용현황  

Lee, Jae-Ung (한국생산기술연구원)
Publication Information
Ceramist / v.21, no.2, 2018 , pp. 59-74 More about this Journal
Abstract
Imaging in the Short Wave Infrared (SWIR) provides several advantages over the visible and near-infrared regions: enhanced image resolution in in foggy or dusty environments, deep tissue penetration, surveillance capabilities with eye-safe lasers, assessment of food quality and safety. Commercially available SWIR imagers are fabricated by integrating expensive epitaxial grown III-V compound semiconductor sensors with Si-based readout integrated circuits(ROIC) by indium bump bonding Infrared image sensors made of solution-processed quantum dots have recently emerged as candidates for next-generation SWIR imagers. They combine ease of processing, tunable optoelectronic properties, facile integration with Si-based ROIC and good performance. Here, we review recent research and development trends of various application fields of SWIR image sensors and nano-materials capable of absorption and emission of SWIR band. With SWIR sensible nano-materials, new type of SWIR image sensor can replace current high price SWIR imagers.
Keywords
Short wavelength infrared (SWIR); Quantum dot; Image sensor; Bio imaging;
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1 M.C. Weidman, M.E. Beck, R.S. Hoffman, F. Prins and W.A. Tisdale, "Monodisperse, Air-Stable PbS Nanocrystals via Precursor Stoichiometry Control," ACS Nano, 8 6363 (2014).   DOI
2 J.W. Lee, D.Y. Kim, S. Baek, H. Yu and F. So, "Inorganic UV-Visible-SWIR Broadband Photodetector Based on Monodisperse PbS Nanocrystals," Small, 12 1328-1333 (2016).   DOI
3 P.R. Brown, D. Kim, R.R. Lunt, N. Zhao, M.G. Bawendi, J.C. Grossman and V. Bulovic, "Energy Level Modification in Lead Sulfide Quantum Dot Thin Films through Ligand Exchange," ACS Nano, 8 5863-5872 (2014).   DOI
4 M. Liu, O. Voznyy, R. Sabatini, F. P. Garcia de Arquer, R. Munir, A. H. Balawi, X. Lan, F. Fan, G. Walters, A. R. Kirmani, S. Hoogland, F. Laquai, A. Amassian and E. H. Sargent, "Hybrid organicinorganic inks flatten the energy landscape in colloidal quantum dot solid," Nat Mater, 16 258-263 (2017).   DOI
5 C.H. Carey, A.L. Abdelhady, Z. Ning, S.M. Thon, O.M. Bakr and E.H. Sargent, "Colloidal Quantum Dot Solar Cells," Chem. Rev., 115 12732-12763 (2015).   DOI
6 E.R. Fossum, "CMOS Image sensors: electronic camera on a chip," IEDM Tech. Dig., 17-25, (1995).
7 A.M. Smith, M.C. Mancini and S. Nie, "Bioimaging: second window for in vivo imaging," Nat Nanotechnol, 4 710-711, (2009).   DOI
8 G. Hong, S. Diao, J. Chang, A.L. Antaris, C. Chen, B. Zhang, S. Zhao, D.N. Atochin, P.L. Huang, K.I. Andreasson, C.J. Kuo and H. Dai, "Through-skull fluorescence imaging of the brain in a new nearinfrared window," Nature Photonics, 8 723-730 (2014).   DOI
9 M. Casalboni, D.F. Matteis, P. Prosposito, A. Quatela and F. Sarcinelli, "Fluorescence efficiency of four infrared polymethine dyes," Chem Phys Lett, 373 372-378 (2003).   DOI
10 D.R. Klaus, M. Keene, S. Silchenko, M. Berezin and N. Gerasimchuk, "1D polymeric platinum cyanoximate: a strategy toward luminescence in the near-infrared region beyond 1000 nm," Inorg Chem, 54 1890-1900 (2015).   DOI
11 O.E. Semonin, J.C. Johnson, J.M. Luther, A.G. Midgett and A.J.Nozik, "Beard MC. Absolute photoluminescence quantum yields of IR-26 Dye, PbS, and PbSe quantum dots," J Phys Chem Lett, 1 2445-50 (2010).   DOI
12 S. Hatami, C. Wurth, M. Kaiser, S. Leubner, S. Gabriel, L. Bahrig, V. Lesnyak, J. Pauli and N. Gaponik, "Absolute photoluminescence quantum yields of IR26 and IR-emissive $Cd_{1-x}Hg_xTe$ and PbS quantum dots-method-and material-inherent challenges," Nanoscale, 7 133-143 (2015).   DOI
13 K. Welsher, Z. Liu, S.P. Sherlock, J.T. Robinson, Z. Chen, D. Daranciang and H. Dai, "A route to brightly fluorescent carbon nanotubes for near-infrared imaging in mice," Nature Nano., 4 773-780 (2009).   DOI
14 F.P.G.de Arquer, A.Armin, P.Meredith and E. H. Sargent, "Solution-processed semiconductors for next-generation photodetectors," Nature Reviews Materials, 2 Article number: 16100 (2017).
15 D.Y. Kim, T. Lai, J.W. Lee, J.R. Manders and F. So, "Multi-spectral imaging with infrared sensitive organic light emitting diode," Scientific Reports, 4 Article number: 5946 (2014).
16 S. Goossens, G. Navickaite, C. Monasterio, S. Gupta, J.J. Piqueras, R. Perez, G. Burwell, I. Nikitskiy, T. Lasanta, T. Galan, E. Puma, A. Centeno, A. Pesquera, A. Zurutuza, G. Konstantatos and F. Koppens, "Broadband image sensor array based on graphene-CMOS integration," Nature Photonics, 11 366-371 (2017).   DOI
17 P. Zhao, Q. Xu, J. Tao, Z. Jin, Y. Pan, C. Yu, and Z. Yu, "Near infrared quantum dots in biomedical applications: current status and future perspective," Nanomed. Nanobiotechnol., 10 [3] 1483-1498 (2017).
18 O.T. Bruns, T.S. Bischof, D.K. Harris, D. Franke, Y. Shi, L. Riedemann, A. Bartelt, F.B. Jaworski, J.A. Carr, C.J. Rowlands, M.W.B. Wilson, O. Chen, H. Wei, G.W. Hwang, D.M. Montana, I. Coropceanu, O.B. Achorn, J. Kloepper, J. Heeren, P.T.C. So, D. Fukumura, K.F. Jensen, R.K. Jain and M.G. Bawendi, "Next-generation in vivo optical imaging with short-wave infrared quantum dots," Nature biomedical engineering, 1 Article Number 56 (2017).
19 K.M. Bedka, "Overshooting cloud top detections using MSG SEVIRI infrared brightness temperatures and their relationship to severe weather over Europe," Atmos. Res., 99 175-189 (2011).   DOI
20 J.E. Kallhammer, "Imaging: The road ahead for car night-vision," Nature Photon., 5 12-13 (2006).
21 X.H. Gao, Y.Y. Cui, R.M. Levenson, L.W.K. Chung and S.M. Nie, "In vivo cancer targeting and imaging with semiconductor quantum dots," Nature Biotechnol., 22 969-976 (2004).   DOI
22 G. Schmid, "Nanoparticles: From Theory to Application," Wiley-VCH, Weinheim, (2004).
23 J.B. Barton, R.F. Cannata and S.M. Petronio, "InGaAs NIR focal plane arrays for imaging and DWDM applications," Pro. SPIE, 4721 37-47 (2002).
24 M.P. Hansen and D.S. Malchow, "Overview of SWIR detectors, cameras, and applications," Proc. SPIE, 6939 Thermosense XXX 69390I (2008).
25 Y. Ni, C. Bouvier, B. Arion and V. Noguier, "Wide dynamic logarithmic InGaAs sensor suitable for eyesafe active imaging," Proc. SPIE, 9861 Thermosense: Thermal Infrared Applications XXXVIII, 986111 (2016).
26 J. Park, "Quantum Dots for Bioimaging," Polymer Science and Technology, 23 [5] 509-512 (2012).
27 S. Mendis, S.E. Kemeny, and E.R. Fossum, "CMOS active pixel image sensor," IEEE Trans. Electron Devices, 41 [3] 452-453 (1994).   DOI
28 E. Thimsen, B. Sadtler and M.Y. Berezin, "Shortwaveinfrared (SWIR) emitters for biological imaging: a review of challenges and opportunities," Nanophotonics, 6 1043 (2017).   DOI
29 J. Kim, K.K. Kwon and S.I. Lee, "Trend and Applications on Lidar Sensor Technology," Electronics and Telecommunications Trends, 27 [6] 134-142 (2012).
30 M.T. Zuber, D.E. Smith, F.G. Lemoine and G.A. Neumann, "The Shape and Internal Structure of the Moon from the Clementine Mission," Science, 16 [266] 1839-1843 (1994).
31 D. Malchow, J. Battaglia, R. Brubaker and M. Ettenberg, "High speed short wave infrared (SWIR) imaging and range gating cameras", Proc. SPIE, 6541 Thermosense XXIX 654106 (2007).
32 M. Laurenzis, and F. Christnacher, "Laser gated viewing at ISL for vision through smoke, active polarimetry, and 3D imaging in NIR and SWIR wavelength bands," Advanced Optical Technologies, 2 397-405 (2013).
33 T. Sasaki, M. Kitamura and I. Mito, "Selective metalorganic vapor phase epitaxial growth of InGaAsP/InP layers with bandgap energy control in InGaAs/InGaAsP multiple-quantum well structures," J. Cryst. Growth, 132 435-443 (1993).   DOI
34 D. McDuff, R. El Kaliouby, S. Thibaud, A. May, J. Cohn and R. Picard, "Affectiva-MIT facial expression dataset (AM-FED): naturalistic and spontaneous facial expressions collected in-the-wild," Computer Vision and Pattern Recognition Workshops (CVPRW), IEEE Computer Society Conference on 881-888 (2013)
35 Commercializations Promotion Agency for R&D Outcomes, "Biometrics Technology and Market Trends(in Korean)," S&T Market Report, 39 1-28 (2016).
36 M. Sharif, S. Bhagavatula, L. Bauer and M.K. Reiter, "Accessorize to a Crime: Real and Stealthy Attacks on State-of-the-Art Face Recognition," Proceedings of the 2016 ACM SIGSAC Conference on Computer and Communications Security, 24-28 (2016).
37 J. Galbally and R. Satta, "Three-dimensional and two-and-a-half-dimensional face recognition spoofing using three-dimensional printed models," IET Biometrics, 5 [2] 83-91 (2015).   DOI
38 Laservision, "Laser Safety Guide: Depth of penetration of electromagnetic radiation in the human eye," www.lasersafety.com, (2018).
39 R. Albarracin, J. Eells and K. Valter, "Photobiomodulation protects the retina from lightinduced photoreceptor degeneration," Invest. Ophthalmol. Vis. Sci., 52 3582-3592 (2011).   DOI
40 J.A. Zuclich, D.J. Lund and B.E. Stuck, "Wavelength dependence of ocular damage thresholds in the near-IR to far-IR transition region: Proposed revisions to MPEs," Health Phys, 92 [1] 15-23 (2007).   DOI
41 Y. Barkana, M. Belkin, "Laser eye injuries," Surv. Ophthalmol., 44 [6] 459-478 (2000).   DOI
42 H. Yao, Z. Hruska, R. Kincaid, R.L. Brown, D. Bhatnagar and T.E. Cleveland, "Detecting maize inoculated with toxigenic and atoxigenic fungal strains with fluorescence hyperspectral imagery," Biosyst. Eng., 115 125-135 (2013).   DOI
43 I. Kim, M. Kim, Y. Chen and S. Kong, "Detection of skin tumors on chicken carcasses using hyperspectral fluorescence imaging," Trans. Am. Soc. Agric. Eng., 47 1785-1792 (2004).   DOI
44 J. Xing, C. Bravo, P.T. Jancsok, H. Ramon and J. Baerdemaeker, "Detecting bruises on 'golden delicious' apples using hyperspectral imaging with multiple wavebands," Biosyst. Eng., 90 27-36 (2005).   DOI
45 M. Nagata, J.G. Tallada and T. Kobayashi, "Bruise detection using nir hyperspectral imaging for strawberry (fragaria x ananassa duch.)," Environ. Control Biol., 44 133 (2006).   DOI
46 J. Qiao, M.O. Ngadi, N. Wang, C. Gariepyand S.O. Prasher, "Pork quality and marbling level assessment using a hyperspectral imaging system," J. Food Eng., 83 10-16 (2007).   DOI
47 D.W. Sun, "Hyperspectral Imaging for Food Quality Analysis and Control" Academic Press, Elsevier, San Diego, CA, USA, (2010).
48 J. Qin, J. T.F. Burks, M.A. Ritenour and W.G. Bonn, "Detection of citrus canker using hyperspectral reflectance imaging with spectral information divergence," J. Food Eng., 93 183-191 (2009).   DOI
49 F. Mendoza, R. Lu, D. Ariana, H. Cen and B. Bailey, "Integrated spectral and image analysis of hyperspectral scattering data for prediction of apple fruit firmness and soluble solids content," Postharv. Biol. Technol., 62 149-160 (2011).
50 G.A. Leiva-Valenzuela, L. Renfu and J.M. Aguilera, "Prediction of firmness and soluble solids content of blueberries using hyperspectral reflectance imaging," J. Food Eng., 115 91-98 (2013).   DOI
51 D.P. Ariana and R. Lu, "Evaluation of internal defect and surface color of whole pickles using hyperspectral imaging," J. Food Eng., 96 583-590 (2010).   DOI
52 E. Gaston, J.S.M. As, P.J. Cullen, C.P. O'donnell and A.A. Gowen, "Prediction of polyphenol oxidase activity using visible near-infrared hyperspectral imaging on mushroom (agaricus bisporus) caps," J. Agric. Food Chem., 58 6226-6233 (2010).   DOI
53 A. Gowen, C. O'donnell, M. Taghizadeh, P. Cullen, J. Frias, and G. Downey, "Hyperspectral imaging combined with principal component analysis for bruise damage detection on white mushrooms (agaricus bisporus)," J. Chemometr., 22 259-267 (2008).   DOI
54 L. Liu, M. Ngadi, S. Prasher and C. Gariepy, "Objective determination of pork marbling scores using the wide line detector," J. Food Eng., 110 497-504 (2012).   DOI
55 D. Wu, H. Shi, Y. He, X. Yu and Y. Bao, "Potential of hyperspectral imaging and multivariate analysis for rapid and non-invasive detection of gelatin adulteration in prawn," J. Food Eng., 119 680-686 (2013).   DOI
56 L. Liu, M. Ngadi, S. Prasher and C. Gariepy, "Categorization of pork quality using gabor filterbased hyperspectral imaging technology," J. Food Eng., 99 284-293 (2010).   DOI
57 H. Huang, L. Liu, M.O. Ngadi and C. Gariepy, "Rapid and non-invasive quantification of intramuscular fat content of intact pork cuts," Talanta, 119 385-395 (2014).   DOI
58 Y. Peng, J. Zhang, W. Wang, Y. Li, J. Wu, H. Huang, X. Gao, and W. Jiang, "Potential prediction of the microbial spoilage of beef using spatially resolved hyperspectral scattering profiles," J. Food Eng., 102 163-169 (2011).   DOI
59 D. Barbin, G. Elmasry, D.W. Sun and P. Allen, "Near-infrared hyperspectral imaging for grading and classification of pork," Meat Sci., 90 259-268 (2012).   DOI
60 D. Wu, D.W. Sun and Y. He, "Application of longwave near infrared hyperspectral imaging for measurement of color distribution in salmon fillet," Innov. Food Sci. Emerg. Technol., 16 361-372 (2012).   DOI
61 P.A. Coelho, M.E. Soto, S.N. Torres, D.G. Sbarbaro and J.E. Pezoa, "Hyperspectral transmittance imaging of the shell-free cooked clam mulinia edulis for parasite detection," J. Food Eng., 117 408-416 (2013).   DOI
62 M. Arngren, P.W. Hansen, B. Eriksen, J. Larsen and R. Larsen, "Analysis of pregerminated barley using hyperspectral image analysis," J. Agric. Food Chem., 59 11385-11394 (2011).   DOI
63 M. Vollmer and K.P. Mollmann, "Infrared Thermal Imaging: Fundamentals, Research and Applications," JohnWiley & Sons, (2010).
64 P. Williams, P. Geladi, G. Fox and M. Manley, "Maize kernel hardness classification by near infrared (nir) hyperspectral imaging and multivariate data analysis," Anal. Chim. Acta, 653 121-130 (2009).   DOI
65 S. Serranti, D. Cesare, F. Marini and G. Bonifazi, "Classification of oat and groat kernels using nir hyperspectral imaging," Talanta, 103 276-284 (2013).   DOI
66 P.J. Williams, P. Geladi, T.J. Britz and M. Manley, "Investigation of fungal development in maize kernels using NIR hyperspectral imaging and multivariate data analysis," J. Cereal Sci., 55 272-278 (2012).   DOI
67 C.B. Singh, D.S. Jayas, J. Paliwal and N.D.G. White, "Detection of midge-damaged wheat kernels using short-wave near-infrared hyperspectral and digital color imaging," Biosyst. Eng., 105 380-387 (2010).   DOI
68 C. Ibarra-Castanedo, S. Sfarra, M. Genest and X. Maldague, "Infrared Vision: Visual Inspection Beyond the Visible Spectrum," Integrated imaging and vision techniques for industrial inspection, Springer, London (2015).
69 T. Martin, R. Brubaker, P. Dixon, M.A. Gagliardi and T. Sudol, "640x512 InGaAs focal plane array camera for visible and SWIR imaging," Proc. SPIE, 5783 Infrared Technology and Applications XXXI (2005).
70 Z.A. Peng, and X. Peng, "Formation of High-Quality CdTe, CdSe, and CdS Nanocrystals Using CdO as Precursor," J. Am. Chem. Soc., 123 [1]183-184 (2001).   DOI
71 S.L. Troyan, V. Kianzad, S.L. Gibbs-Strauss, S. Gioux, A. Matsui, R. Oketokoun, L. Ngo, A. Khamene, F. Azar and J.V. Frangioni, "The $FLARE^{TM}$ Intraoperative Near-Infrared Fluorescence Imaging System: A First-in-Human Clinical Trial in Breast Cancer Sentinel Lymph Node Mapping," Ann. Surg. Oncol., 16 1943-1952 (2009).
72 H. Zhou, S.P. Gunsten, N.G. Zhegalova, S. Bloch, S. Achilefu, J.C. Holley, D. Schweppe, W. Akers, S.L. Brody and W.C. Eades, "Visualization of pulmonary clearance mechanisms via noninvasive optical imaging validated by near-infrared flow cytometry," Cytometry A 87 419-27 (2015).   DOI
73 D. Lu, L. He, G. Zhang, A. Lv, R. Wang, X. Zhang and W. Tan, "Aptamer-assembled nanomaterials for fluorescent sensing and imaging," Nanophotonics, 6[1] 109-121 (2016).   DOI
74 S. Kim, Y.T. Lim, E.G. Soltesz, A.M.D. Grand, J. Lee, A. Nakayama, J.A. Parker, T. Mihaljevic, R.G. Laurence, D.M. Dor, L.H. Cohmn, M.G. Bawendi, and J. V. Frangioni, "Near-infrared fluorescent type II quantum dots for sentinel lymph node mapping," Nat Biotech, 22 93-97 (2004).   DOI
75 G.C. Gurtner, G.E. Jones, P.C. Neligan, M.I. Newman, B.T. Phillips, J.M. Sacks and M.R. Zenn, "Intraoperative laser angiography using the SPY system: Review of the literature and recommendations for use," Ann. Surg. Innov. Res., 7 1 (2013).   DOI
76 K. Nose, T. Omata and S.O.Y. Matsuo, "Colloidal Synthesis of Ternary Copper Indium Diselenide Quantum Dots and Their Optical Properties," J. Phys. Chem. C, 113 [9]3455-3460 (2009).   DOI
77 E. J. D. Klem, D. D. MacNeil, P. W. Cyr, L. Levina, E. H. Sargent, "Efficient solution-processed infrared photovoltaic cells: Planarized all-inorganic bulk heterojunction devices via inter-quantum-dot bridging during growth from solution," Appl. Phys. Lett., 90 183113 (2007).   DOI
78 M. Yarema, S. Pichler, M. Sytnyk, R. Seyrkammer, R.T. Lechner, G. Fritz-Popovski, D. Jarzab, K. Szendrei, R. Resel, O. Korovyanko, M.A. Loi, O. Paris, G. Hesser and W. Heiss, "Infrared Emitting and Photoconducting Colloidal Silver Chalcogenide Nanocrystal Quantum Dots from a Silylamide-Promoted Synthesis," ACS Nano, 5 3758-3765 (2011).   DOI
79 X. Hu, Q. Zhang, X. Huang, D. Li, Y. Luo and Q. Meng, "Aqueous colloidal $CuInS_2$ for quantum dot sensitized solar," J. Mater. Chem., 21 15903-15905 (2011).   DOI
80 E.C. Rossi, A. Ivanova and J.F. Boggess, "Robotically assisted fluorescence-guided lymph node mapping with ICG for gynecologic malignancies: a feasibility study," Gynecol Oncol, 124 78-82 (2012).   DOI
81 S. He, J. Song, J. Qu and Z. Cheng, "Crucial breakthrough of second near-infrared biological window fluorophores: design and synthesis toward multimodal imaging and theranostics," Chem. Soc. Rev., Advanced Article (2018).
82 I. Moreels, Y. Justo, B. De Geyter, K. Haustraete, J.C. Martins and Z. Hens, "Size-Tunable, Bright, and Stable PbS Quantum Dots: A Surface Chemistry Study," ACS Nano, 5 2004-2012 (2011).   DOI
83 D. Franke, D.K. Harris, O. Chen, O.T. Bruns, J.A. Carr, M.W. B. Wilson and M.G. Bawendi, "Continuous injection synthesis of indium arsenide quantum dots emissive in the short-wavelength infrared," Nature Communications, 7 12749 (2016).   DOI
84 V. Grigel, D. Dupont, K. De Nolf, Z. Hens, and M. D. Tessier, "InAs colloidal quantum dots synthesis via aminopnictogen precursor chemistry," J. Am. Chem. Soc., 138 [41] 13485-13488 (2016).   DOI
85 A. Sills, P. Harrison and M. Califano, "Exciton Dynamics in InSb Colloidal Quantum Dots," J. Phys. Chem. Lett., 7 31-35 (2016).   DOI