One of the important applications of subwavelength plasmonic optics is sensing of chemical and biological analytes [1]. Plasmonic sensors are based on tuning of either propagating surface waves (surface plasmon polaritons, SPP) or nonpropagating (localized) ones. The adsorption of analyte modifies the surface refractive index, ensuring ultrahigh sensitivities that may exceed 10–8 refractive index units, i.e. 1 ng/cm2 (0.003 monolayer) [2]. For all plasmonic sensors it is of interest to enhance their selectivity, since their operation is based solely on refractive index sensing, i.e. different materials with similar refractive indexes cause similar outputs. In this work we propose the integration of active plasmonic part with separator (e.g. membrane or nanomembrane with nanopores) and ligand binding the targeted analyte into a single structure. This may be done by membrane nanocompositing [3], e.g. by lamination (Fig. 1a) or volume structuring/pore formation (Fig. 1b). At the same one ...may use built-in (nano)pores to augment the effective surface for adsorption and thus vastly increase the amount of adsorbate. For our work we chose macroporous crosslinked copolymers (MCP) which are readily formed into membranes and keep a permanent well-developed porous structure. Particularly we used glycidyl methacrylate (GMA)-based MCP. GMA has already been successfully used for heavy and precious metals adsorption and enzyme immobilization [4]. For the formation of membranes comprising GMA we selected a new method combining traditional immersion precipitation with photopolymerization and crosslinking of functional monomers [5]. Our approach may be extended to other types of chemical and bio sensors. Acknowledgment:This work has been funded by Serbian Ministry of Education and Science through the projects TR32008 and III 43009.[1] W. L. Barnes, A. Dereux, T. W. Ebbesen, Nature, 424 (2003) 824-830.[2] L. S. Jung, C. T. Campbell, T. M. Chinowsky, M. N. Mar, S. S. Yee, Langmuir, 14 (1998) 5636-5648.[3] Z. Jakšić, J. Matovic, Materials, 1 (2010) 165-200.[4] N. Miletić, Z. Vuković, A. Nastasović, K. Loos, Macromol. Biosci., 11 (2011) 1537–1543.[5] P. Radovanovic, M. Kellner, J. Matovic, R. Liska, T. Koch, J. Membrane Sci., 401-402 (2012) 254-261.
Keywords:
plasmonic nanocomposites / membranes / chemical sensors / biological sensors
Source:
The 3rd International Conference on the Physics of Optical Materilas and Devices - ICOM 2012, Belgrade, Serbia September 3rd - September 6th, 2012: Book of abstracts, 2012
TY - CONF
AU - Jakšić, Zoran
AU - Radovanović, Filip
AU - Nastasović, Aleksandra
PY - 2012
UR - http://dais.sanu.ac.rs/123456789/794
UR - https://cer.ihtm.bg.ac.rs/handle/123456789/2595
AB - One of the important applications of subwavelength plasmonic optics is sensing of chemical and biological analytes [1]. Plasmonic sensors are based on tuning of either propagating surface waves (surface plasmon polaritons, SPP) or nonpropagating (localized) ones. The adsorption of analyte modifies the surface refractive index, ensuring ultrahigh sensitivities that may exceed 10–8 refractive index units, i.e. 1 ng/cm2 (0.003 monolayer) [2]. For all plasmonic sensors it is of interest to enhance their selectivity, since their operation is based solely on refractive index sensing, i.e. different materials with similar refractive indexes cause similar outputs. In this work we propose the integration of active plasmonic part with separator (e.g. membrane or nanomembrane with nanopores) and ligand binding the targeted analyte into a single structure. This may be done by membrane nanocompositing [3], e.g. by lamination (Fig. 1a) or volume structuring/pore formation (Fig. 1b). At the same one may use built-in (nano)pores to augment the effective surface for adsorption and thus vastly increase the amount of adsorbate. For our work we chose macroporous crosslinked copolymers (MCP) which are readily formed into membranes and keep a permanent well-developed porous structure. Particularly we used glycidyl methacrylate (GMA)-based MCP. GMA has already been successfully used for heavy and precious metals adsorption and enzyme immobilization [4]. For the formation of membranes comprising GMA we selected a new method combining traditional immersion precipitation with photopolymerization and crosslinking of functional monomers [5]. Our approach may be extended to other types of chemical and bio sensors. Acknowledgment:This work has been funded by Serbian Ministry of Education and Science through the projects TR32008 and III 43009.[1] W. L. Barnes, A. Dereux, T. W. Ebbesen, Nature, 424 (2003) 824-830.[2] L. S. Jung, C. T. Campbell, T. M. Chinowsky, M. N. Mar, S. S. Yee, Langmuir, 14 (1998) 5636-5648.[3] Z. Jakšić, J. Matovic, Materials, 1 (2010) 165-200.[4] N. Miletić, Z. Vuković, A. Nastasović, K. Loos, Macromol. Biosci., 11 (2011) 1537–1543.[5] P. Radovanovic, M. Kellner, J. Matovic, R. Liska, T. Koch, J. Membrane Sci., 401-402 (2012) 254-261.
PB - Beograd : Agencija Format
C3 - The 3rd International Conference on the Physics of Optical Materilas and Devices - ICOM 2012, Belgrade, Serbia September 3rd - September 6th, 2012: Book of abstracts
T1 - Membrane-based plasmonic nanocomposites for chemical or biological sensing
UR - https://hdl.handle.net/21.15107/rcub_dais_794
ER -
@conference{
author = "Jakšić, Zoran and Radovanović, Filip and Nastasović, Aleksandra",
year = "2012",
abstract = "One of the important applications of subwavelength plasmonic optics is sensing of chemical and biological analytes [1]. Plasmonic sensors are based on tuning of either propagating surface waves (surface plasmon polaritons, SPP) or nonpropagating (localized) ones. The adsorption of analyte modifies the surface refractive index, ensuring ultrahigh sensitivities that may exceed 10–8 refractive index units, i.e. 1 ng/cm2 (0.003 monolayer) [2]. For all plasmonic sensors it is of interest to enhance their selectivity, since their operation is based solely on refractive index sensing, i.e. different materials with similar refractive indexes cause similar outputs. In this work we propose the integration of active plasmonic part with separator (e.g. membrane or nanomembrane with nanopores) and ligand binding the targeted analyte into a single structure. This may be done by membrane nanocompositing [3], e.g. by lamination (Fig. 1a) or volume structuring/pore formation (Fig. 1b). At the same one may use built-in (nano)pores to augment the effective surface for adsorption and thus vastly increase the amount of adsorbate. For our work we chose macroporous crosslinked copolymers (MCP) which are readily formed into membranes and keep a permanent well-developed porous structure. Particularly we used glycidyl methacrylate (GMA)-based MCP. GMA has already been successfully used for heavy and precious metals adsorption and enzyme immobilization [4]. For the formation of membranes comprising GMA we selected a new method combining traditional immersion precipitation with photopolymerization and crosslinking of functional monomers [5]. Our approach may be extended to other types of chemical and bio sensors. Acknowledgment:This work has been funded by Serbian Ministry of Education and Science through the projects TR32008 and III 43009.[1] W. L. Barnes, A. Dereux, T. W. Ebbesen, Nature, 424 (2003) 824-830.[2] L. S. Jung, C. T. Campbell, T. M. Chinowsky, M. N. Mar, S. S. Yee, Langmuir, 14 (1998) 5636-5648.[3] Z. Jakšić, J. Matovic, Materials, 1 (2010) 165-200.[4] N. Miletić, Z. Vuković, A. Nastasović, K. Loos, Macromol. Biosci., 11 (2011) 1537–1543.[5] P. Radovanovic, M. Kellner, J. Matovic, R. Liska, T. Koch, J. Membrane Sci., 401-402 (2012) 254-261.",
publisher = "Beograd : Agencija Format",
journal = "The 3rd International Conference on the Physics of Optical Materilas and Devices - ICOM 2012, Belgrade, Serbia September 3rd - September 6th, 2012: Book of abstracts",
title = "Membrane-based plasmonic nanocomposites for chemical or biological sensing",
url = "https://hdl.handle.net/21.15107/rcub_dais_794"
}
Jakšić, Z., Radovanović, F.,& Nastasović, A.. (2012). Membrane-based plasmonic nanocomposites for chemical or biological sensing. in The 3rd International Conference on the Physics of Optical Materilas and Devices - ICOM 2012, Belgrade, Serbia September 3rd - September 6th, 2012: Book of abstracts
Beograd : Agencija Format..
https://hdl.handle.net/21.15107/rcub_dais_794
Jakšić Z, Radovanović F, Nastasović A. Membrane-based plasmonic nanocomposites for chemical or biological sensing. in The 3rd International Conference on the Physics of Optical Materilas and Devices - ICOM 2012, Belgrade, Serbia September 3rd - September 6th, 2012: Book of abstracts. 2012;.
https://hdl.handle.net/21.15107/rcub_dais_794 .
Jakšić, Zoran, Radovanović, Filip, Nastasović, Aleksandra, "Membrane-based plasmonic nanocomposites for chemical or biological sensing" in The 3rd International Conference on the Physics of Optical Materilas and Devices - ICOM 2012, Belgrade, Serbia September 3rd - September 6th, 2012: Book of abstracts (2012),
https://hdl.handle.net/21.15107/rcub_dais_794 .
