TY  - CHAP
AU  - Matović, Jovan
AU  - Jakšić, Zoran
PY  - 2011
UR  - https://cer.ihtm.bg.ac.rs/handle/123456789/4454
AB  - The goal of this chapter is to offer a concise and clear picture of the most
important artificial nanomembrane-related procedures and technologies, including
those for fabrication and functionalization, and to present the main properties and
potential applications, stressing recent results in the field contributed by the authors.
Nanomembranes are probably the most ubiquitous building block in biology and at
the same time one of the most primordial ones. Every living cell, from bacteria
to the cells in human bodies, has nanomembranes acting as interfaces between
the cytoplasm and its surroundings. All metabolic processes proceed through
nanomembranes and involve their active participation. Functionally, the man-made
nanomembrane strives to mimic this most basic biological unit. The existence of
the life itself is a proof that such a fundamental task can be performed. When
designing artificial nanomembranes, the whole wealth of structures and processes
already enabling and supporting life is at our disposal to recreate, tailor, fine-tune,
and utilize them. In some cases, the obstacles are formidable, but then the potential
rewards are stunning.
There is an additional advantage in bionic approach to nanomembranes: we
do not have to use only the limited toolbox of materials and processes found in
nature. Instead we are free to experiment with enhancements not readily met in
natural structures – for instance, we may utilize nanoparticles of isotopes emitting
ionizing radiation, even at lethal doses. We can introduce additional structures
to our bionic nanomembranes, each carrying its own functionality, for instance
nanoparticles or layers with plasmonic properties (e.g., to be used in sensing
applications), target-specific binding agents (to improve selectivity) and carbonnanotube
support (to enhance mechanical strength). In this way, we are able to
create meta-nanomembranes with properties exceeding the known ones (Jakšić and
Matovic, Materials 3:165–200, 2010). In this chapter, we present some small steps
toward that goal.
PB  - Switzerland : Springer Nature
T2  - Biomimetrics - Materials, Sructures and Processes
T1  - Bionic (Nano) Membranes
SP  - 9
EP  - 24
DO  - 10.1007/978-3-642-11934-7_2
ER  - 

@inbook{
author = "Matović, Jovan and Jakšić, Zoran",
year = "2011",
abstract = "The goal of this chapter is to offer a concise and clear picture of the most
important artificial nanomembrane-related procedures and technologies, including
those for fabrication and functionalization, and to present the main properties and
potential applications, stressing recent results in the field contributed by the authors.
Nanomembranes are probably the most ubiquitous building block in biology and at
the same time one of the most primordial ones. Every living cell, from bacteria
to the cells in human bodies, has nanomembranes acting as interfaces between
the cytoplasm and its surroundings. All metabolic processes proceed through
nanomembranes and involve their active participation. Functionally, the man-made
nanomembrane strives to mimic this most basic biological unit. The existence of
the life itself is a proof that such a fundamental task can be performed. When
designing artificial nanomembranes, the whole wealth of structures and processes
already enabling and supporting life is at our disposal to recreate, tailor, fine-tune,
and utilize them. In some cases, the obstacles are formidable, but then the potential
rewards are stunning.
There is an additional advantage in bionic approach to nanomembranes: we
do not have to use only the limited toolbox of materials and processes found in
nature. Instead we are free to experiment with enhancements not readily met in
natural structures – for instance, we may utilize nanoparticles of isotopes emitting
ionizing radiation, even at lethal doses. We can introduce additional structures
to our bionic nanomembranes, each carrying its own functionality, for instance
nanoparticles or layers with plasmonic properties (e.g., to be used in sensing
applications), target-specific binding agents (to improve selectivity) and carbonnanotube
support (to enhance mechanical strength). In this way, we are able to
create meta-nanomembranes with properties exceeding the known ones (Jakšić and
Matovic, Materials 3:165–200, 2010). In this chapter, we present some small steps
toward that goal.",
publisher = "Switzerland : Springer Nature",
journal = "Biomimetrics - Materials, Sructures and Processes",
booktitle = "Bionic (Nano) Membranes",
pages = "9-24",
doi = "10.1007/978-3-642-11934-7_2"
}

Matović, J.,& Jakšić, Z.. (2011). Bionic (Nano) Membranes. in Biomimetrics - Materials, Sructures and Processes
Switzerland : Springer Nature., 9-24.
https://doi.org/10.1007/978-3-642-11934-7_2

Matović J, Jakšić Z. Bionic (Nano) Membranes. in Biomimetrics - Materials, Sructures and Processes. 2011;:9-24.
doi:10.1007/978-3-642-11934-7_2 .

Matović, Jovan, Jakšić, Zoran, "Bionic (Nano) Membranes" in Biomimetrics - Materials, Sructures and Processes (2011):9-24,
https://doi.org/10.1007/978-3-642-11934-7_2 . .

TY  - JOUR
AU  - Jakšić, Zoran
AU  - Vuković, Slobodan M.
AU  - Matovic, Jovan
AU  - Tanasković, Dragan
PY  - 2011
UR  - https://cer.ihtm.bg.ac.rs/handle/123456789/831
AB  - In this paper we review some metasurfaces with negative values of effective refractive index, as scaffolds for a new generation of surface plasmon polariton-based biological or chemical sensors. The electromagnetic properties of a metasurface may be tuned by its full immersion into analyte, or by the adsorption of a thin layer on it, both of which change its properties as a plasmonic guide. We consider various simple forms of plasmonic crystals suitable for this purpose. We start with the basic case of a freestanding, electromagnetically symmetrical plasmonic slab and analyze different ultrathin, multilayer structures, to finally consider some two-dimensional "wallpaper" geometries like split ring resonator arrays and fishnet structures. A part of the text is dedicated to the possibility of multifunctionalization where a metasurface structure is simultaneously utilized both for sensing and for selectivity enhancement. Finally we give an overview of surface-bound intrinsic electromagnetic noise phenomena that limits the ultimate performance of a metasurfaces sensor.
PB  - MDPI
T2  - Materials
T1  - Negative Refractive Index Metasurfaces for Enhanced Biosensing
VL  - 4
IS  - 1
SP  - 1
EP  - 36
DO  - 10.3390/ma4010001
ER  - 

@article{
author = "Jakšić, Zoran and Vuković, Slobodan M. and Matovic, Jovan and Tanasković, Dragan",
year = "2011",
abstract = "In this paper we review some metasurfaces with negative values of effective refractive index, as scaffolds for a new generation of surface plasmon polariton-based biological or chemical sensors. The electromagnetic properties of a metasurface may be tuned by its full immersion into analyte, or by the adsorption of a thin layer on it, both of which change its properties as a plasmonic guide. We consider various simple forms of plasmonic crystals suitable for this purpose. We start with the basic case of a freestanding, electromagnetically symmetrical plasmonic slab and analyze different ultrathin, multilayer structures, to finally consider some two-dimensional "wallpaper" geometries like split ring resonator arrays and fishnet structures. A part of the text is dedicated to the possibility of multifunctionalization where a metasurface structure is simultaneously utilized both for sensing and for selectivity enhancement. Finally we give an overview of surface-bound intrinsic electromagnetic noise phenomena that limits the ultimate performance of a metasurfaces sensor.",
publisher = "MDPI",
journal = "Materials",
title = "Negative Refractive Index Metasurfaces for Enhanced Biosensing",
volume = "4",
number = "1",
pages = "1-36",
doi = "10.3390/ma4010001"
}

Jakšić, Z., Vuković, S. M., Matovic, J.,& Tanasković, D.. (2011). Negative Refractive Index Metasurfaces for Enhanced Biosensing. in Materials
MDPI., 4(1), 1-36.
https://doi.org/10.3390/ma4010001

Jakšić Z, Vuković SM, Matovic J, Tanasković D. Negative Refractive Index Metasurfaces for Enhanced Biosensing. in Materials. 2011;4(1):1-36.
doi:10.3390/ma4010001 .

Jakšić, Zoran, Vuković, Slobodan M., Matovic, Jovan, Tanasković, Dragan, "Negative Refractive Index Metasurfaces for Enhanced Biosensing" in Materials, 4, no. 1 (2011):1-36,
https://doi.org/10.3390/ma4010001 . .

TY  - CONF
AU  - Matovic, J.
AU  - Adamovic, N.
AU  - Jakšić, Zoran
AU  - Schmid, U.
PY  - 2010
UR  - https://cer.ihtm.bg.ac.rs/handle/123456789/3178
AB  - We demonstrated a field effect transistor based on the modulation of the proton flow in confined water-containing nanochannels. The device resembles an MOSFET transistor with the difference that the charge carriers here are ions (i.e. protons) instead of electrons. The effective cross-section of the conductive channels in the transistor is defined by the intensity of the electrical double layer and by the potential applied to the transistor gate.
PB  - Elsevier
C3  - Procedia Engineering
T1  - Field effect transistor based on protons as charge carriers
VL  - 5
SP  - 1368
EP  - 1371
DO  - 10.1016/j.proeng.2010.09.369
ER  - 

@conference{
author = "Matovic, J. and Adamovic, N. and Jakšić, Zoran and Schmid, U.",
year = "2010",
abstract = "We demonstrated a field effect transistor based on the modulation of the proton flow in confined water-containing nanochannels. The device resembles an MOSFET transistor with the difference that the charge carriers here are ions (i.e. protons) instead of electrons. The effective cross-section of the conductive channels in the transistor is defined by the intensity of the electrical double layer and by the potential applied to the transistor gate.",
publisher = "Elsevier",
journal = "Procedia Engineering",
title = "Field effect transistor based on protons as charge carriers",
volume = "5",
pages = "1368-1371",
doi = "10.1016/j.proeng.2010.09.369"
}

Matovic, J., Adamovic, N., Jakšić, Z.,& Schmid, U.. (2010). Field effect transistor based on protons as charge carriers. in Procedia Engineering
Elsevier., 5, 1368-1371.
https://doi.org/10.1016/j.proeng.2010.09.369

Matovic J, Adamovic N, Jakšić Z, Schmid U. Field effect transistor based on protons as charge carriers. in Procedia Engineering. 2010;5:1368-1371.
doi:10.1016/j.proeng.2010.09.369 .

Matovic, J., Adamovic, N., Jakšić, Zoran, Schmid, U., "Field effect transistor based on protons as charge carriers" in Procedia Engineering, 5 (2010):1368-1371,
https://doi.org/10.1016/j.proeng.2010.09.369 . .