TY  - JOUR
AU  - Šetrajčić, Jovan P.
AU  - Sajfert, Vjekoslav D.
AU  - Jaćimovski, Stevo
PY  - 2016
UR  - http://jakov.kpu.edu.rs/handle/123456789/695
AB  - Application of nano-structures requires a knowledge of their fundamental physical (mechanical, electromagnetic, optical, etc.) characteristics. Thermodynamic properties associated with phonon displacements through the nano-samples are particularly interesting. Independent of the type of lattices, the thermodynamics of their subsystems (electrons, excitons, spin waves, etc.) is determined when the subsystem is in thermodynamic equilibrium with phonons. Phonons are collective mechanical oscillations of molecules or atoms and represent the most important system of excitations. Besides, the acoustical characteristics as well as conductive and superconductive properties etc. could not be realistically explained without phonons. All quoted is well known and all applications of phonons in bulk structures have been intensively exploited for more than a century. The fact which must be especially pointed out is that the role of phonons in nanostructures is much more impressive than in bulk structures. The main fact concerning phonon properties in nanostructures is the absence of the so-called acoustic phonons, i.e., phonons whose energy tends to zero when phonon momentum tends to zero. For the exciting of phonons in nanostructures activation energy different from zero is necessary. These unexpected characteristics require revision of all conclusions obtained by bulk theories of phonons. Therefore, the contribution of phonon subsystems to thermodynamic and energy transfering analysis is the first step in a research of nanostructure properties. This paper describes a major aspect of the effort to understand nanostructures, namely the study of phonons and phonon-mediated effects in structures with nanoscale dimensional confinement in one or more spatial dimensions. During the last two decades, there has been a steady effort to understand the optical and acoustic phonons in nanostructures such as the superlattice, quantum wires, nanotubes and quantum dots. The central theme of this paper is the description of the acoustic phonons of the optical type in these nanostructures. As a preliminary to describing the dispersion relations and mode structures for phonons in nanostructures, phonon amplitudes are quantized in terms of the harmonic oscillator approximation, and anharmonic effects leading to phonon decay are described in terms of the dominant phonon decay channels. These elastic and discontinued models are applied to describe the deformation potential and interactions in a variety of nanostructures. Dependence of energy on the wave vector is highly nonlinear and linear approximation of the laws of dispersion of phonons in small size nanostructures makes no sense. Changing the phonon dispersion law due to confinement severely affects the kinetic effects conditioned by the interaction of acoustic phonons with electrons, dotted defects, phonon-phonon interactions. Managing transport properties of acoustic phonons through the modification of their energy spectrum in nanostructures was named phonon engineering. In this paper we will try to observe the difference between the characteristics of different nano-crystalline structures: ultrathin films, composite films, i.e., superlattices, nanorods and quantum dots, we were interested in whether the quantum size effects (quantum confinement), quantum (de) coherence and influence of boundary conditions, strengthen or weaken in nanosamples. Finally, this paper describes how the dimensional confinement of phonons in nanostructures leads to modifications in the electronic, optical, acoustic, superconducting and thermodynamic properties of quantum. Thermal properties of nanostructures have recently attracted a lot of attention. The influence of size effects on thermal conductivity is becoming extremely important for device design and reliability. The problem of thermal management is even more severe for photonic devices such as vertical cavity surface emitting lasers. On the other hand, to improve performance of thermoelectrics, one needs to achieve low thermal conductivity. These are two contradictory demands, but both can be approached with appropriate modification of phonon modes, e.g., phonon engineering. On the basis of the calculated dispersion law and distribution of phonon states in nanoscopis crystals, free energy and entropy will be calculated. Internal energy as well as heat capacitance will also be analyzed. Low-temperature behavior of these quantities will be compared to the corresponding ones of bulk-structures. It was shown that heat capacitances of nano-layered structures in low-temperature region were higher than the same quantities of the corresponding bulk sample. In the middle and the highest temperature region, temperature behavior was inverse: heat capacitance of layered structures was lower than of the corresponding bulk ones. The consequences were discussed with relation to the better superconductive properties of nanomaterials.
PB  - Amer Scientific Publishers, Valencia
T2  - Reviews in theoretical science
T1  - Fundamental Preferences of the Phonon Engineering for Nanostructural Samples
VL  - 4
IS  - 4
SP  - 353
EP  - 401
DO  - 10.1166/rits.2016.1067
ER  - 

@article{
author = "Šetrajčić, Jovan P. and Sajfert, Vjekoslav D. and Jaćimovski, Stevo",
year = "2016",
abstract = "Application of nano-structures requires a knowledge of their fundamental physical (mechanical, electromagnetic, optical, etc.) characteristics. Thermodynamic properties associated with phonon displacements through the nano-samples are particularly interesting. Independent of the type of lattices, the thermodynamics of their subsystems (electrons, excitons, spin waves, etc.) is determined when the subsystem is in thermodynamic equilibrium with phonons. Phonons are collective mechanical oscillations of molecules or atoms and represent the most important system of excitations. Besides, the acoustical characteristics as well as conductive and superconductive properties etc. could not be realistically explained without phonons. All quoted is well known and all applications of phonons in bulk structures have been intensively exploited for more than a century. The fact which must be especially pointed out is that the role of phonons in nanostructures is much more impressive than in bulk structures. The main fact concerning phonon properties in nanostructures is the absence of the so-called acoustic phonons, i.e., phonons whose energy tends to zero when phonon momentum tends to zero. For the exciting of phonons in nanostructures activation energy different from zero is necessary. These unexpected characteristics require revision of all conclusions obtained by bulk theories of phonons. Therefore, the contribution of phonon subsystems to thermodynamic and energy transfering analysis is the first step in a research of nanostructure properties. This paper describes a major aspect of the effort to understand nanostructures, namely the study of phonons and phonon-mediated effects in structures with nanoscale dimensional confinement in one or more spatial dimensions. During the last two decades, there has been a steady effort to understand the optical and acoustic phonons in nanostructures such as the superlattice, quantum wires, nanotubes and quantum dots. The central theme of this paper is the description of the acoustic phonons of the optical type in these nanostructures. As a preliminary to describing the dispersion relations and mode structures for phonons in nanostructures, phonon amplitudes are quantized in terms of the harmonic oscillator approximation, and anharmonic effects leading to phonon decay are described in terms of the dominant phonon decay channels. These elastic and discontinued models are applied to describe the deformation potential and interactions in a variety of nanostructures. Dependence of energy on the wave vector is highly nonlinear and linear approximation of the laws of dispersion of phonons in small size nanostructures makes no sense. Changing the phonon dispersion law due to confinement severely affects the kinetic effects conditioned by the interaction of acoustic phonons with electrons, dotted defects, phonon-phonon interactions. Managing transport properties of acoustic phonons through the modification of their energy spectrum in nanostructures was named phonon engineering. In this paper we will try to observe the difference between the characteristics of different nano-crystalline structures: ultrathin films, composite films, i.e., superlattices, nanorods and quantum dots, we were interested in whether the quantum size effects (quantum confinement), quantum (de) coherence and influence of boundary conditions, strengthen or weaken in nanosamples. Finally, this paper describes how the dimensional confinement of phonons in nanostructures leads to modifications in the electronic, optical, acoustic, superconducting and thermodynamic properties of quantum. Thermal properties of nanostructures have recently attracted a lot of attention. The influence of size effects on thermal conductivity is becoming extremely important for device design and reliability. The problem of thermal management is even more severe for photonic devices such as vertical cavity surface emitting lasers. On the other hand, to improve performance of thermoelectrics, one needs to achieve low thermal conductivity. These are two contradictory demands, but both can be approached with appropriate modification of phonon modes, e.g., phonon engineering. On the basis of the calculated dispersion law and distribution of phonon states in nanoscopis crystals, free energy and entropy will be calculated. Internal energy as well as heat capacitance will also be analyzed. Low-temperature behavior of these quantities will be compared to the corresponding ones of bulk-structures. It was shown that heat capacitances of nano-layered structures in low-temperature region were higher than the same quantities of the corresponding bulk sample. In the middle and the highest temperature region, temperature behavior was inverse: heat capacitance of layered structures was lower than of the corresponding bulk ones. The consequences were discussed with relation to the better superconductive properties of nanomaterials.",
publisher = "Amer Scientific Publishers, Valencia",
journal = "Reviews in theoretical science",
title = "Fundamental Preferences of the Phonon Engineering for Nanostructural Samples",
volume = "4",
number = "4",
pages = "353-401",
doi = "10.1166/rits.2016.1067"
}

Šetrajčić, J. P., Sajfert, V. D.,& Jaćimovski, S.. (2016). Fundamental Preferences of the Phonon Engineering for Nanostructural Samples. in Reviews in theoretical science
Amer Scientific Publishers, Valencia., 4(4), 353-401.
https://doi.org/10.1166/rits.2016.1067

Šetrajčić JP, Sajfert VD, Jaćimovski S. Fundamental Preferences of the Phonon Engineering for Nanostructural Samples. in Reviews in theoretical science. 2016;4(4):353-401.
doi:10.1166/rits.2016.1067 .

Šetrajčić, Jovan P., Sajfert, Vjekoslav D., Jaćimovski, Stevo, "Fundamental Preferences of the Phonon Engineering for Nanostructural Samples" in Reviews in theoretical science, 4, no. 4 (2016):353-401,
https://doi.org/10.1166/rits.2016.1067 . .

TY  - JOUR
AU  - Šetrajčić, Jovan P.
AU  - Jaćimovski, Stevo
AU  - Sajfert, Vjekoslav D.
PY  - 2015
UR  - http://jakov.kpu.edu.rs/handle/123456789/665
AB  - The paper presents the innovated method of two-time dependent Green's functions applied to the bounded and translational perturbed systems. Film-structures and super-lattices were analyzed by employing the phonon spectra for the calculation of relevant thermodynamic characteristics. Free energy and the internal energy of the system were found as well as the temperature behavior of layered structures. Heat capacitances of these nanostructures were compared to bulk ones. It was shown that heat capacitances of nanolayered structures in low-temperature region were higher than the same quantities of the corresponding bulk sample. In the middle and the highest temperature region, temperature behavior was inverse: heat capacitance of layered structures was lower than of the corresponding bulk ones. The consequences were discussed with relation to the ( super) conductive properties of nanomaterials.
PB  - World Scientific Publ Co Pte Ltd, Singapore
T2  - Modern physics letters B
T1  - Phonon contribution to heat capacitance of nanolayered crystalline structures
VL  - 29
IS  - 4
DO  - 10.1142/S0217984915500086
ER  - 

@article{
author = "Šetrajčić, Jovan P. and Jaćimovski, Stevo and Sajfert, Vjekoslav D.",
year = "2015",
abstract = "The paper presents the innovated method of two-time dependent Green's functions applied to the bounded and translational perturbed systems. Film-structures and super-lattices were analyzed by employing the phonon spectra for the calculation of relevant thermodynamic characteristics. Free energy and the internal energy of the system were found as well as the temperature behavior of layered structures. Heat capacitances of these nanostructures were compared to bulk ones. It was shown that heat capacitances of nanolayered structures in low-temperature region were higher than the same quantities of the corresponding bulk sample. In the middle and the highest temperature region, temperature behavior was inverse: heat capacitance of layered structures was lower than of the corresponding bulk ones. The consequences were discussed with relation to the ( super) conductive properties of nanomaterials.",
publisher = "World Scientific Publ Co Pte Ltd, Singapore",
journal = "Modern physics letters B",
title = "Phonon contribution to heat capacitance of nanolayered crystalline structures",
volume = "29",
number = "4",
doi = "10.1142/S0217984915500086"
}

Šetrajčić, J. P., Jaćimovski, S.,& Sajfert, V. D.. (2015). Phonon contribution to heat capacitance of nanolayered crystalline structures. in Modern physics letters B
World Scientific Publ Co Pte Ltd, Singapore., 29(4).
https://doi.org/10.1142/S0217984915500086

Šetrajčić JP, Jaćimovski S, Sajfert VD. Phonon contribution to heat capacitance of nanolayered crystalline structures. in Modern physics letters B. 2015;29(4).
doi:10.1142/S0217984915500086 .

Šetrajčić, Jovan P., Jaćimovski, Stevo, Sajfert, Vjekoslav D., "Phonon contribution to heat capacitance of nanolayered crystalline structures" in Modern physics letters B, 29, no. 4 (2015),
https://doi.org/10.1142/S0217984915500086 . .

TY  - JOUR
AU  - Šetrajčić, Jovan P.
AU  - Jaćimovski, Stevo
AU  - Sajfert, Vjekoslav D.
AU  - Šetrajčić, Igor J.
PY  - 2014
UR  - http://jakov.kpu.edu.rs/handle/123456789/594
AB  - Difficulties connected to solving difference equations of hyperbolic type were analyzed in this work and discussed in detail. The results are compared to those of the standard wave equation and certain similarities were established. The method of solving the equation is generalized by means of kernel expanded into separable polynomials. The analysis was inspired by some new ideas concerning quantization of time. Two examples are given: excitons and phonons in thin crystalline films. The advanced methodology of Green's function method and the application of this new methodology resulted in a set of interesting conclusions concerning thin film properties. The significance of the obtained spatial dependence of exciton concentration was discussed and it was concluded, on the basis of the found spatial dependence of exciton concentration, that such boundary conditions of a thin molecular film which lead to high exciton concentrations can be determined. It was also concluded that thin films possess high superconductive properties, that physical characteristics of thin films are spatially dependent and that the spatial dependence can be the basis for widening the field of application of nanostructures.
PB  - Elsevier Science Bv, Amsterdam
T2  - Communications in nonlinear science and numerical simulation
T1  - Specific quantum mechanical solution of difference equation of hyperbolic type
VL  - 19
IS  - 5
SP  - 1313
EP  - 1328
DO  - 10.1016/j.cnsns.2013.08.026
ER  - 

@article{
author = "Šetrajčić, Jovan P. and Jaćimovski, Stevo and Sajfert, Vjekoslav D. and Šetrajčić, Igor J.",
year = "2014",
abstract = "Difficulties connected to solving difference equations of hyperbolic type were analyzed in this work and discussed in detail. The results are compared to those of the standard wave equation and certain similarities were established. The method of solving the equation is generalized by means of kernel expanded into separable polynomials. The analysis was inspired by some new ideas concerning quantization of time. Two examples are given: excitons and phonons in thin crystalline films. The advanced methodology of Green's function method and the application of this new methodology resulted in a set of interesting conclusions concerning thin film properties. The significance of the obtained spatial dependence of exciton concentration was discussed and it was concluded, on the basis of the found spatial dependence of exciton concentration, that such boundary conditions of a thin molecular film which lead to high exciton concentrations can be determined. It was also concluded that thin films possess high superconductive properties, that physical characteristics of thin films are spatially dependent and that the spatial dependence can be the basis for widening the field of application of nanostructures.",
publisher = "Elsevier Science Bv, Amsterdam",
journal = "Communications in nonlinear science and numerical simulation",
title = "Specific quantum mechanical solution of difference equation of hyperbolic type",
volume = "19",
number = "5",
pages = "1313-1328",
doi = "10.1016/j.cnsns.2013.08.026"
}

Šetrajčić, J. P., Jaćimovski, S., Sajfert, V. D.,& Šetrajčić, I. J.. (2014). Specific quantum mechanical solution of difference equation of hyperbolic type. in Communications in nonlinear science and numerical simulation
Elsevier Science Bv, Amsterdam., 19(5), 1313-1328.
https://doi.org/10.1016/j.cnsns.2013.08.026

Šetrajčić JP, Jaćimovski S, Sajfert VD, Šetrajčić IJ. Specific quantum mechanical solution of difference equation of hyperbolic type. in Communications in nonlinear science and numerical simulation. 2014;19(5):1313-1328.
doi:10.1016/j.cnsns.2013.08.026 .

Šetrajčić, Jovan P., Jaćimovski, Stevo, Sajfert, Vjekoslav D., Šetrajčić, Igor J., "Specific quantum mechanical solution of difference equation of hyperbolic type" in Communications in nonlinear science and numerical simulation, 19, no. 5 (2014):1313-1328,
https://doi.org/10.1016/j.cnsns.2013.08.026 . .

TY  - JOUR
AU  - Jaćimovski, Stevo
AU  - Sajfert, Vjekoslav D.
AU  - Raković, Dejan
AU  - Šetrajčić, Jovan P.
PY  - 2012
UR  - http://jakov.kpu.edu.rs/handle/123456789/496
AB  - We have transformed the Scott's model of protein Hamiltonian to metastable form, by means of double coherent unitary transformation. It turned out that in metastable Hamiltonian the number of quasi particles is not conserved due to the forming of pairs of excitations. The energies of pairs are found and their population is quoted. It is interesting that elementary excitations of metastable state behave similarly as excitations of molecular vibration field as well as excitations of electromagnetic field.
PB  - Inst Materials Physics, Bucharest
T2  - Digest journal of nanomaterials and biostructures
T1  - Metastable processes in proteins
VL  - 7
IS  - 1
SP  - 117
EP  - 122
UR  - https://hdl.handle.net/21.15107/rcub_jakov_496
ER  - 

@article{
author = "Jaćimovski, Stevo and Sajfert, Vjekoslav D. and Raković, Dejan and Šetrajčić, Jovan P.",
year = "2012",
abstract = "We have transformed the Scott's model of protein Hamiltonian to metastable form, by means of double coherent unitary transformation. It turned out that in metastable Hamiltonian the number of quasi particles is not conserved due to the forming of pairs of excitations. The energies of pairs are found and their population is quoted. It is interesting that elementary excitations of metastable state behave similarly as excitations of molecular vibration field as well as excitations of electromagnetic field.",
publisher = "Inst Materials Physics, Bucharest",
journal = "Digest journal of nanomaterials and biostructures",
title = "Metastable processes in proteins",
volume = "7",
number = "1",
pages = "117-122",
url = "https://hdl.handle.net/21.15107/rcub_jakov_496"
}

Jaćimovski, S., Sajfert, V. D., Raković, D.,& Šetrajčić, J. P.. (2012). Metastable processes in proteins. in Digest journal of nanomaterials and biostructures
Inst Materials Physics, Bucharest., 7(1), 117-122.
https://hdl.handle.net/21.15107/rcub_jakov_496

Jaćimovski S, Sajfert VD, Raković D, Šetrajčić JP. Metastable processes in proteins. in Digest journal of nanomaterials and biostructures. 2012;7(1):117-122.
https://hdl.handle.net/21.15107/rcub_jakov_496 .

Jaćimovski, Stevo, Sajfert, Vjekoslav D., Raković, Dejan, Šetrajčić, Jovan P., "Metastable processes in proteins" in Digest journal of nanomaterials and biostructures, 7, no. 1 (2012):117-122,
https://hdl.handle.net/21.15107/rcub_jakov_496 .

TY  - JOUR
AU  - Sajfert, Vjekoslav D.
AU  - Jaćimovski, Stevo
AU  - Šetrajčić, Jovan P.
AU  - Mašković, Ljiljana
AU  - Bednar, Nikola
AU  - Pop, Nicolina
AU  - Tošić, Bratislav
PY  - 2011
UR  - http://jakov.kpu.edu.rs/handle/123456789/402
AB  - We analyzed linear molecular chain with exciton excitations for the case when number of excitons is not conserved. The results obtained are in some sense amazing. The dispersion law of finite chain is surface depending on two independent angles. The same conclusion is valid for concentrations of exitons and exciton pairs. As it was expectable physical characteristics of the finite chain depend on spatial coordinates. All results are compared to corresponding results of infinite chain.
PB  - Amer Scientific Publishers, Valencia
T2  - Journal of computational and theoretical nanoscience
T1  - Optical Properties of Nanostructures
VL  - 8
IS  - 11
SP  - 2285
EP  - 2290
DO  - 10.1166/jctn.2011.1957
ER  - 

@article{
author = "Sajfert, Vjekoslav D. and Jaćimovski, Stevo and Šetrajčić, Jovan P. and Mašković, Ljiljana and Bednar, Nikola and Pop, Nicolina and Tošić, Bratislav",
year = "2011",
abstract = "We analyzed linear molecular chain with exciton excitations for the case when number of excitons is not conserved. The results obtained are in some sense amazing. The dispersion law of finite chain is surface depending on two independent angles. The same conclusion is valid for concentrations of exitons and exciton pairs. As it was expectable physical characteristics of the finite chain depend on spatial coordinates. All results are compared to corresponding results of infinite chain.",
publisher = "Amer Scientific Publishers, Valencia",
journal = "Journal of computational and theoretical nanoscience",
title = "Optical Properties of Nanostructures",
volume = "8",
number = "11",
pages = "2285-2290",
doi = "10.1166/jctn.2011.1957"
}

Sajfert, V. D., Jaćimovski, S., Šetrajčić, J. P., Mašković, L., Bednar, N., Pop, N.,& Tošić, B.. (2011). Optical Properties of Nanostructures. in Journal of computational and theoretical nanoscience
Amer Scientific Publishers, Valencia., 8(11), 2285-2290.
https://doi.org/10.1166/jctn.2011.1957

Sajfert VD, Jaćimovski S, Šetrajčić JP, Mašković L, Bednar N, Pop N, Tošić B. Optical Properties of Nanostructures. in Journal of computational and theoretical nanoscience. 2011;8(11):2285-2290.
doi:10.1166/jctn.2011.1957 .

Sajfert, Vjekoslav D., Jaćimovski, Stevo, Šetrajčić, Jovan P., Mašković, Ljiljana, Bednar, Nikola, Pop, Nicolina, Tošić, Bratislav, "Optical Properties of Nanostructures" in Journal of computational and theoretical nanoscience, 8, no. 11 (2011):2285-2290,
https://doi.org/10.1166/jctn.2011.1957 . .

TY  - CHAP
AU  - Sajfert, Vjekoslav D.
AU  - Popov, Dušan
AU  - Jaćimovski, Stevo
AU  - Tošić, Bratislav
PY  - 2011
UR  - http://jakov.kpu.edu.rs/handle/123456789/366
AB  - In connection with the experimental result which stated that polyethylene foil amplifies about three times the penetrated light, we propose two theoretical explanations of this phenomenon. One of them is that several amplified peaks are the consequence of the forming of solitons in a polyethylene chain whose velocities are close to the velocity of sound. Forming of solitons, together with boundary conditions in a polyethylene macromolecules chain, which contain about thirty monomers, lead to the amplification of light. The second explanation requires introduction of homeopolar excitons in polymer macromolecules. Both energy gap of homeopolar excitons and width of homeopolar exciton zone are of the same order of magnitude. It means that transitions in a very wide zone give light quanta which are able to amplify the initial light. In order to avoid some confusion and misunderstandings, we wish to point out the following. Atoms and molecules as the whole are treated classically (transition through potential barriers, for example, etc.). The exception to this rule are phonon theories of crystals where the phonon is considered as a quanta of boson field, i.e., it means that, in the theory of mechanical oscillations, molecules and atoms as the whole are treated quantum mechanically. On the other hand, elementary excitations in crystals such as excitons, vibrons, spin waves, and ferroelectric excitations, etc., which arise from changes of some parts of atoms or molecules are treated quantum mechanically exclusively. In the analyses of this work, the excitations of an individual molecule subsystem (i.e. the quantum objects) would serve as an explanation of the light amplification by a polymer chain.
T2  - Quantum Frontiers of Atoms and Molecules
T1  - Theoretical explanation of light amplifying by polyethylene foil
SP  - 141
EP  - 155
UR  - https://hdl.handle.net/21.15107/rcub_jakov_366
ER  - 

@inbook{
author = "Sajfert, Vjekoslav D. and Popov, Dušan and Jaćimovski, Stevo and Tošić, Bratislav",
year = "2011",
abstract = "In connection with the experimental result which stated that polyethylene foil amplifies about three times the penetrated light, we propose two theoretical explanations of this phenomenon. One of them is that several amplified peaks are the consequence of the forming of solitons in a polyethylene chain whose velocities are close to the velocity of sound. Forming of solitons, together with boundary conditions in a polyethylene macromolecules chain, which contain about thirty monomers, lead to the amplification of light. The second explanation requires introduction of homeopolar excitons in polymer macromolecules. Both energy gap of homeopolar excitons and width of homeopolar exciton zone are of the same order of magnitude. It means that transitions in a very wide zone give light quanta which are able to amplify the initial light. In order to avoid some confusion and misunderstandings, we wish to point out the following. Atoms and molecules as the whole are treated classically (transition through potential barriers, for example, etc.). The exception to this rule are phonon theories of crystals where the phonon is considered as a quanta of boson field, i.e., it means that, in the theory of mechanical oscillations, molecules and atoms as the whole are treated quantum mechanically. On the other hand, elementary excitations in crystals such as excitons, vibrons, spin waves, and ferroelectric excitations, etc., which arise from changes of some parts of atoms or molecules are treated quantum mechanically exclusively. In the analyses of this work, the excitations of an individual molecule subsystem (i.e. the quantum objects) would serve as an explanation of the light amplification by a polymer chain.",
journal = "Quantum Frontiers of Atoms and Molecules",
booktitle = "Theoretical explanation of light amplifying by polyethylene foil",
pages = "141-155",
url = "https://hdl.handle.net/21.15107/rcub_jakov_366"
}

Sajfert, V. D., Popov, D., Jaćimovski, S.,& Tošić, B.. (2011). Theoretical explanation of light amplifying by polyethylene foil. in Quantum Frontiers of Atoms and Molecules, 141-155.
https://hdl.handle.net/21.15107/rcub_jakov_366

Sajfert VD, Popov D, Jaćimovski S, Tošić B. Theoretical explanation of light amplifying by polyethylene foil. in Quantum Frontiers of Atoms and Molecules. 2011;:141-155.
https://hdl.handle.net/21.15107/rcub_jakov_366 .

Sajfert, Vjekoslav D., Popov, Dušan, Jaćimovski, Stevo, Tošić, Bratislav, "Theoretical explanation of light amplifying by polyethylene foil" in Quantum Frontiers of Atoms and Molecules (2011):141-155,
https://hdl.handle.net/21.15107/rcub_jakov_366 .

TY  - JOUR
AU  - Jaćimovski, Stevo
AU  - Sajfert, Vjekoslav D.
AU  - Raković, Dejan
AU  - Tošić, Bratislav
PY  - 2010
UR  - http://jakov.kpu.edu.rs/handle/123456789/356
AB  - In the nanocylinder, a cut-off from the molecular crystal, dielectric permeability tensor is investigated. Excitons in the nanocylinder arise due to the exciting of the electron subsystem of the molecule. In evaluation of dielectric permeability Dzhyaloshinskii-Pitaevskii approach is used, connected with retarded and advanced exciton Green's functions and correct use of Paulion Green's function. It turned out that refraction and absorption indices depend on configuration coordinates, having maximal values at boundary cross-sections and minimal value at central cross-section of the nanocylinder broken symmetry structure. Although it was expected that boundary conditions make higher refractive and absorptive characteristics of the nanocylinder, this appeared not to be possible because Paulion Green's function is not proportional to the exciton concentration.
PB  - Polish Acad Sciences Inst Physics, Warsaw
T2  - Acta physica polonica A
T1  - Dielectric Permeability of Nanocylinder
VL  - 117
IS  - 5
SP  - 738
EP  - 744
DO  - 10.12693/APhysPolA.117.738
ER  - 

@article{
author = "Jaćimovski, Stevo and Sajfert, Vjekoslav D. and Raković, Dejan and Tošić, Bratislav",
year = "2010",
abstract = "In the nanocylinder, a cut-off from the molecular crystal, dielectric permeability tensor is investigated. Excitons in the nanocylinder arise due to the exciting of the electron subsystem of the molecule. In evaluation of dielectric permeability Dzhyaloshinskii-Pitaevskii approach is used, connected with retarded and advanced exciton Green's functions and correct use of Paulion Green's function. It turned out that refraction and absorption indices depend on configuration coordinates, having maximal values at boundary cross-sections and minimal value at central cross-section of the nanocylinder broken symmetry structure. Although it was expected that boundary conditions make higher refractive and absorptive characteristics of the nanocylinder, this appeared not to be possible because Paulion Green's function is not proportional to the exciton concentration.",
publisher = "Polish Acad Sciences Inst Physics, Warsaw",
journal = "Acta physica polonica A",
title = "Dielectric Permeability of Nanocylinder",
volume = "117",
number = "5",
pages = "738-744",
doi = "10.12693/APhysPolA.117.738"
}

Jaćimovski, S., Sajfert, V. D., Raković, D.,& Tošić, B.. (2010). Dielectric Permeability of Nanocylinder. in Acta physica polonica A
Polish Acad Sciences Inst Physics, Warsaw., 117(5), 738-744.
https://doi.org/10.12693/APhysPolA.117.738

Jaćimovski S, Sajfert VD, Raković D, Tošić B. Dielectric Permeability of Nanocylinder. in Acta physica polonica A. 2010;117(5):738-744.
doi:10.12693/APhysPolA.117.738 .

Jaćimovski, Stevo, Sajfert, Vjekoslav D., Raković, Dejan, Tošić, Bratislav, "Dielectric Permeability of Nanocylinder" in Acta physica polonica A, 117, no. 5 (2010):738-744,
https://doi.org/10.12693/APhysPolA.117.738 . .

TY  - JOUR
AU  - Šetrajčić, Jovan P.
AU  - Mirjanić, D. Lj
AU  - Vučenović, Siniša M.
AU  - Ilić, Dušan I.
AU  - Markoski, Branko
AU  - Jaćimovski, Stevo
AU  - Sajfert, Vjekoslav D.
AU  - Zorić, Vojkan M.
PY  - 2009
UR  - http://jakov.kpu.edu.rs/handle/123456789/270
AB  - Spectra of possible phonon states, as well as thermodynamic characteristics of nanocrystals (ultrathin film and quantum wire) of simple cubic crystalline structure are analyzed in this paper, using the method of two-time dependent Green functions. From energy spectra and internal energy of the system the thermal capacitance of these structures in low temperature region is found. The temperature behavior of specific heat is compared to that of corresponding bulk structure. It is shown that at extremely low temperatures thermal capacitance of quantum wire is considerably lower than the thermal capacitance 4 film as well as the bulk sample. Consequences of this fact are discussed in detail and its influence to thermodynamic properties of materials is estimated.
PB  - Polish Acad Sciences Inst Physics, Warsaw
T2  - Acta physica polonica A
T1  - Phonon Contribution in Thermodynamics of Nano-Crystalline Films and Wires
VL  - 115
IS  - 4
SP  - 778
EP  - 782
DO  - 10.12693/APhysPolA.115.778
ER  - 

@article{
author = "Šetrajčić, Jovan P. and Mirjanić, D. Lj and Vučenović, Siniša M. and Ilić, Dušan I. and Markoski, Branko and Jaćimovski, Stevo and Sajfert, Vjekoslav D. and Zorić, Vojkan M.",
year = "2009",
abstract = "Spectra of possible phonon states, as well as thermodynamic characteristics of nanocrystals (ultrathin film and quantum wire) of simple cubic crystalline structure are analyzed in this paper, using the method of two-time dependent Green functions. From energy spectra and internal energy of the system the thermal capacitance of these structures in low temperature region is found. The temperature behavior of specific heat is compared to that of corresponding bulk structure. It is shown that at extremely low temperatures thermal capacitance of quantum wire is considerably lower than the thermal capacitance 4 film as well as the bulk sample. Consequences of this fact are discussed in detail and its influence to thermodynamic properties of materials is estimated.",
publisher = "Polish Acad Sciences Inst Physics, Warsaw",
journal = "Acta physica polonica A",
title = "Phonon Contribution in Thermodynamics of Nano-Crystalline Films and Wires",
volume = "115",
number = "4",
pages = "778-782",
doi = "10.12693/APhysPolA.115.778"
}

Šetrajčić, J. P., Mirjanić, D. L., Vučenović, S. M., Ilić, D. I., Markoski, B., Jaćimovski, S., Sajfert, V. D.,& Zorić, V. M.. (2009). Phonon Contribution in Thermodynamics of Nano-Crystalline Films and Wires. in Acta physica polonica A
Polish Acad Sciences Inst Physics, Warsaw., 115(4), 778-782.
https://doi.org/10.12693/APhysPolA.115.778

Šetrajčić JP, Mirjanić DL, Vučenović SM, Ilić DI, Markoski B, Jaćimovski S, Sajfert VD, Zorić VM. Phonon Contribution in Thermodynamics of Nano-Crystalline Films and Wires. in Acta physica polonica A. 2009;115(4):778-782.
doi:10.12693/APhysPolA.115.778 .

Šetrajčić, Jovan P., Mirjanić, D. Lj, Vučenović, Siniša M., Ilić, Dušan I., Markoski, Branko, Jaćimovski, Stevo, Sajfert, Vjekoslav D., Zorić, Vojkan M., "Phonon Contribution in Thermodynamics of Nano-Crystalline Films and Wires" in Acta physica polonica A, 115, no. 4 (2009):778-782,
https://doi.org/10.12693/APhysPolA.115.778 . .

TY  - JOUR
AU  - Sajfert, Vjekoslav D.
AU  - Mašković, Ljiljana
AU  - Jaćimovski, Stevo
AU  - Popov, Dušan
AU  - Tošić, Bratislav
PY  - 2008
UR  - http://jakov.kpu.edu.rs/handle/123456789/217
AB  - The superconductivity properties of cylinder with nano cross-section are investigated. In the nearest neighbours approximation, electron Hamiltonian of cylinder decays onto two independent Hamiltonians. One corresponds to electrons which propagate along chains parallel to the axis of cylinder. Second correspond to electrons moving in discs. The electron-phonon interaction Hamiltonians are found and superconductive properties were examined in the frames of BCS approach. It was shown that superconductive temperature in chains is several Kelvins, while in discs it can be higher for two orders of magnitude. It is also shown that magnetic field produced by electron currents in discs is of the order of thousand Tesla, i.e., extremely high.
PB  - Amer Scientific Publishers, Stevenson Ranch
T2  - Journal of computational and theoretical nanoscience
T1  - Electron-Phonon Interaction in Cylindrical Nanostructures
VL  - 5
IS  - 7
SP  - 1230
EP  - 1239
DO  - 10.1166/jctn.2008.2558
ER  - 

@article{
author = "Sajfert, Vjekoslav D. and Mašković, Ljiljana and Jaćimovski, Stevo and Popov, Dušan and Tošić, Bratislav",
year = "2008",
abstract = "The superconductivity properties of cylinder with nano cross-section are investigated. In the nearest neighbours approximation, electron Hamiltonian of cylinder decays onto two independent Hamiltonians. One corresponds to electrons which propagate along chains parallel to the axis of cylinder. Second correspond to electrons moving in discs. The electron-phonon interaction Hamiltonians are found and superconductive properties were examined in the frames of BCS approach. It was shown that superconductive temperature in chains is several Kelvins, while in discs it can be higher for two orders of magnitude. It is also shown that magnetic field produced by electron currents in discs is of the order of thousand Tesla, i.e., extremely high.",
publisher = "Amer Scientific Publishers, Stevenson Ranch",
journal = "Journal of computational and theoretical nanoscience",
title = "Electron-Phonon Interaction in Cylindrical Nanostructures",
volume = "5",
number = "7",
pages = "1230-1239",
doi = "10.1166/jctn.2008.2558"
}

Sajfert, V. D., Mašković, L., Jaćimovski, S., Popov, D.,& Tošić, B.. (2008). Electron-Phonon Interaction in Cylindrical Nanostructures. in Journal of computational and theoretical nanoscience
Amer Scientific Publishers, Stevenson Ranch., 5(7), 1230-1239.
https://doi.org/10.1166/jctn.2008.2558

Sajfert VD, Mašković L, Jaćimovski S, Popov D, Tošić B. Electron-Phonon Interaction in Cylindrical Nanostructures. in Journal of computational and theoretical nanoscience. 2008;5(7):1230-1239.
doi:10.1166/jctn.2008.2558 .

Sajfert, Vjekoslav D., Mašković, Ljiljana, Jaćimovski, Stevo, Popov, Dušan, Tošić, Bratislav, "Electron-Phonon Interaction in Cylindrical Nanostructures" in Journal of computational and theoretical nanoscience, 5, no. 7 (2008):1230-1239,
https://doi.org/10.1166/jctn.2008.2558 . .