Realization of Low-Cost Multichannel Surface Plasmon Resonance Based Optical Transducer

Manjunath SOMARAPALLI; Romuald JOLIVOT; Waleed MOHAMMED

doi:10.1007/s13320-018-0511-z

[1] M. G. Manera and R. Rella, “Improved gas sensing performances in SPR sensors by transducers activation,” Sensors and Actuators B: Chemical, 2013, 179(4): 175-186.

[2] R. Galatus, B. Feier, C. Cristea, N. Cennamo, and L. Zeni, “SPR based hybrid electro-optic biosensor for β-lactam antibiotics determination in water,” SPIE, 2017, 10405: 104050C-1-104050C-6.

[3] F. Geiss, S. Fossati, I. Khan, N. G. Quilis, W. Knoll, and J. Dostalek, “UV-SPR biosensor for biomolecular interaction studies,” SPIE, 2017, 10231: 1023107-1-1023107-8.

[4] H. H. Kyaw, S. Boonruang, W. S. Mohammed, and J. Dutta, “Design of electric-field assisted surface plasmon resonance system for the detection of heavy metal ions in water,” AIP Advances, 2015, 5(10): 246-253.

[5] Y. H. Choi, G. Y. Lee, H. Ko, Y. W. Chang, M. J. Kang, and J. C. Pyun, “Development of SPR biosensor for the detection of human hepatitis B virus using plasma-treated parylene-N film,” Biosensors and Bioelectronics, 2014, 56(56): 286-294.

[6] X. L. Zhang, Y. Liu, T. Fan, N. Hu, Z. Yang, X. Chen, et al., “Design and performance of a portable and multichannel SPR device,” Sensors, 2017, 17(6): 1435-1-1435-7.

[7] S. Maegawa, J. Yamaguchi, F. Itoigawa, and T. Nakamura, “Discussion on surface plasmon resonance technique in the Otto configuration for measurement of lubricant film thickness,” Tribology Letters, 2016, 62(2): 1-14.

[8] C. Thirstrup, W. Zong, M. Borre, H. Neff, H. C. Pedersen, and G. Holzhueter, “Diffractive optical coupling element for surface plasmon resonance sensors,” Sensors and Actuators B: Chemical, 2004, 100(3): 298-308.

[9] Q. Liu, Y. Liu, S. M. Chen, F. Wang, and W. Peng, “A low-cost and portable dual-channel fiber optic surface plasmon resonance system,” Sensors, 2017, 17(12): 2797-1-2797-8.

[10] M. Somarapalli, K. Koul, R. Lahon, S. Boonruang, and W. S. Mohammed, “Demonstration of low-cost and compact SPR optical transducer through edge light coupling,” Micro & Nano Letters, 2017, 12(9): 643-646.

[11] S. Nizamov, V. Scherbahn, and V. M. Mirsky, “Self-referencing SPR-sensor based on integral measurements of light intensity reflected by arbitrarily distributed sensing and referencing spots,” Sensors and Actuators B: Chemical, 2015, 207: 740-747.

[12] X. L. Zhou, K. Chen, L. Li, W. Peng, and Q. X. Yu, “Angle modulated surface plasmon resonance spectrometer for refractive index sensing with enhanced detection resolution,” Optics Communications, 2017, 382: 610-614.

[13] H. Zhang, D. Q. Song, S. Gao, H. Q. Zhang, J. Zhang, and Y. Sun, “Enhanced wavelength modulation SPR biosensor based on gold nanorods for immunoglobulin detection,” Talanta, 2013, 115(115): 857-862.

[14] T. M. Chinowsky, J. G. Quinn, D. U. Bartholomew, R. Kaiser, and J. L. Elkind, “Performance of the Spreeta 2000 integrated surface plasmon resonance affinity sensor,” Sensors and Actuators B: Chemical, 2003, 91(1): 266-274.

[15] G. Neuert, S. Kufer, M. Benoit, and H. E. Gaub, “Modular multichannel surface plasmon spectrometer,” Review of Scientific Instruments, 2005, 76(5): 054303-1-054303-4.

[16] S. Rampazzi, G. Danese, F. Leporati, and F. Marabelli, “A localized surface plasmon resonance-based portable instrument for quick on-site biomolecular detection,” IEEE Transactions on Instrumentation and Measurement, 2016, 65(2): 317-327.

[17] I. Khodadad, N. Abedzadeh, V. Lakshminarayan, and S. S. Saini, “Low cost spectrometer and learning applications for exposing kids to optics,” SPIE, 2015, 9793: 97932W-1-97932W-5.

[18] A. J. S. McGonigle, T. C. Wilkes, T. D. Pering, J. R. Willmott, J. M. Cook, F. M. Mims, et al., “Smartphone spectrometers,” Sensors, 2018, 18(1): 223-1-223-15.

[19] Y. Liu, S. Chen, Q. Liu, J. F. Masson, and W. Peng, “Compact multi-channel surface plasmon resonance sensor for real-time multi-analyte biosensing,” Optics Express, 2015, 23(16): 20540-20548.

[20] D. Whittaker and I. Culshaw, “Scattering-matrix treatment of patterned multilayer photonic structures,” Physical Review B, 1999, 60(4): 2610-2618.

[21] R. C. Hall, R. Mittra, and K. M. Mitzner, “Analysis of multilayered periodic structures using generalized scattering matrix theory,” IEEE Transactions on Antennas and Propagation, 1988, 36(4): 511-517.

[22] S. Chah, J. Yi, and R. N. Zare, “Surface plasmon resonance analysis of aqueous mercuric ions,” Sensors and Actuators B: Chemical, 2004, 99(2): 216-222.

[23] P. Zhang, Y. P. Chen, W. Wang, Y. Shen, and J. S. Guo, “Surface plasmon resonance for water pollutant detection and water process analysis,” Trends in Analytical Chemistry, 2016, 85: 153-165.

[24] L. Goldman and A. I. Schafer, Goldman's cecil medicine E-book. Oxford, UK: Elsevier Health Sciences, 2011: 1-2704.

[25] A. S. Shcherbakov, A. O. Arellanes, and V. Chavushyan, “Optical spectrometer with acousto-optical dynamic grating for guillermo haro astrophysical observatory,” International Journal of Astronomy & Astroph, 2013, 3(4): 376-384.

[26] N. Blind, E. L. Coarer, P. Kern, and S. Gousset, “Spectrographs for astrophotonics,” Optics Express, 2017, 25(22): 27341-27369.

[27] E. C. Cull, M. E. Gehm, S. T. McCain, B. D. Guenther, and D. J. Brady, “Multimodal optical spectrometers for remote chemical detection,” SPIE, 2005, 5778: 376-383.

[28] W. K. Kuo and C. J. Hsu, “Two-dimensional grating guided-mode resonance tunable filter,” Optics Express, 2017, 25(24): 29642-29649.