Local field enhancement at the core of cylindrical nanoinclusions embedded in a linear dielectric host matrix

Local field enhancement at the core of cylindrical nanoinclusions embedded in a linear dielectric host matrix

In this paper we have discussed theoretical concepts and presented numerical results of local field enhancement at the core of different assemblages of metal/dielectric cylindrical nanoinclusions embedded in a linear dielectric host matrix. The obtained results show that for a composite with metal...

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Дата:2016
Автори: Abbo, Y.A., Mal'nev, V.N., Ismail, A.A.
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Мова:English
Опубліковано: Інститут фізики конденсованих систем НАН України 2016
Назва видання:Condensed Matter Physics
Онлайн доступ:http://dspace.nbuv.gov.ua/handle/123456789/156203
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Цитувати:Local field enhancement at the core of cylindrical nanoinclusions embedded in a linear dielectric host matrix / Y.A. Abbo, V.N. Mal'nev, A.A. Ismail // Condensed Matter Physics. — 2016. — Т. 19, № 3. — С. 33401: 1–10. — Бібліогр.: 12 назв. — англ.

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spelling irk-123456789-1562032019-06-19T01:26:13Z Local field enhancement at the core of cylindrical nanoinclusions embedded in a linear dielectric host matrix Abbo, Y.A. Mal'nev, V.N. Ismail, A.A. In this paper we have discussed theoretical concepts and presented numerical results of local field enhancement at the core of different assemblages of metal/dielectric cylindrical nanoinclusions embedded in a linear dielectric host matrix. The obtained results show that for a composite with metal coated inclusions there exist two peak values of the enhancement factor at two different resonant frequencies. The existence of the second maxima becomes more important for a larger volume fraction of the metal part of the inclusion. For dielectric coated metal core inclusions and pure metal inclusions there is only one resonant frequency and one peak value of the enhancement factor. The enhancement of an electromagnetic wave is promising for the existence of nonlinear optical phenomena such as optical bistability which is important in optical communication and in optical computing such as optical switch and memory elements. В цiй статтi ми обговорили теоретичнi концепцiї, а також представили числовi результати пiдсилення локального поля для рiзних компонувань цилiндричних нановключень метал/дiелектрик, вбудованих у лiнiйну дiелектричну базисну матрицю. Отриманi результати показують, що для композиту з пометалованими включеннями iснує два пiкових значення коефiцiєнта пiдсилення при двох рiзних резонансних частотах. Iснування другого максимума стає важливiшим для бiльшої об’ємної частки металiчної частини включення. Для металевих включень з дiелектричним покриттям є тiльки одна резонансна частота i одне пiкове значення коефiцiєнта пiдсилення. Пiдсилення електромагнiтної хвилi є обнадiйливим для iснування нелiнiйного оптичного явища такого як бiстабiльнiсть, яке є важливим для оптичного зв’язку i оптичних розрахункiв (оптичнi комутатори i елементи пам’ятi) 2016 Article Local field enhancement at the core of cylindrical nanoinclusions embedded in a linear dielectric host matrix / Y.A. Abbo, V.N. Mal'nev, A.A. Ismail // Condensed Matter Physics. — 2016. — Т. 19, № 3. — С. 33401: 1–10. — Бібліогр.: 12 назв. — англ. 1607-324X PACS: 42.65.Pc, 42.79.Ta, 78.67.Sc, 78.67.-n DOI:10.5488/CMP.19.33401 arXiv:1609.04700 http://dspace.nbuv.gov.ua/handle/123456789/156203 en Condensed Matter Physics Інститут фізики конденсованих систем НАН України
institution Digital Library of Periodicals of National Academy of Sciences of Ukraine
collection DSpace DC
language English
description In this paper we have discussed theoretical concepts and presented numerical results of local field enhancement at the core of different assemblages of metal/dielectric cylindrical nanoinclusions embedded in a linear dielectric host matrix. The obtained results show that for a composite with metal coated inclusions there exist two peak values of the enhancement factor at two different resonant frequencies. The existence of the second maxima becomes more important for a larger volume fraction of the metal part of the inclusion. For dielectric coated metal core inclusions and pure metal inclusions there is only one resonant frequency and one peak value of the enhancement factor. The enhancement of an electromagnetic wave is promising for the existence of nonlinear optical phenomena such as optical bistability which is important in optical communication and in optical computing such as optical switch and memory elements.
format Article
author Abbo, Y.A.
Mal'nev, V.N.
Ismail, A.A.
spellingShingle Abbo, Y.A.
Mal'nev, V.N.
Ismail, A.A.
Local field enhancement at the core of cylindrical nanoinclusions embedded in a linear dielectric host matrix
Condensed Matter Physics
author_facet Abbo, Y.A.
Mal'nev, V.N.
Ismail, A.A.
author_sort Abbo, Y.A.
title Local field enhancement at the core of cylindrical nanoinclusions embedded in a linear dielectric host matrix
title_short Local field enhancement at the core of cylindrical nanoinclusions embedded in a linear dielectric host matrix
title_full Local field enhancement at the core of cylindrical nanoinclusions embedded in a linear dielectric host matrix
title_fullStr Local field enhancement at the core of cylindrical nanoinclusions embedded in a linear dielectric host matrix
title_full_unstemmed Local field enhancement at the core of cylindrical nanoinclusions embedded in a linear dielectric host matrix
title_sort local field enhancement at the core of cylindrical nanoinclusions embedded in a linear dielectric host matrix
publisher Інститут фізики конденсованих систем НАН України
publishDate 2016
url http://dspace.nbuv.gov.ua/handle/123456789/156203
citation_txt Local field enhancement at the core of cylindrical nanoinclusions embedded in a linear dielectric host matrix / Y.A. Abbo, V.N. Mal'nev, A.A. Ismail // Condensed Matter Physics. — 2016. — Т. 19, № 3. — С. 33401: 1–10. — Бібліогр.: 12 назв. — англ.
series Condensed Matter Physics
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fulltext Condensed Matter Physics, 2016, Vol. 19, No 3, 33401: 1–10 DOI: 10.5488/CMP.19.33401 http://www.icmp.lviv.ua/journal Local field enhancement at the core of cylindrical nanoinclusions embedded in a linear dielectric host matrix Y.A. Abbo1,2∗, V.N. Mal’nev2, A.A. Ismail2 1 Addis Ababa (Asko), P.O.BOX 171078, Ethiopia 2 Department of Physics, Addis Ababa University, P.O.BOX 1176, Addis Ababa, Ethiopia Received October 11, 2015, in final form March 16, 2016 In this paper we have discussed theoretical concepts and presented numerical results of local field enhance- ment at the core of different assemblages of metal/dielectric cylindrical nanoinclusions embedded in a linear dielectric host matrix. The obtained results show that for a composite with metal coated inclusions there exist two peak values of the enhancement factor at two different resonant frequencies. The existence of the second maxima becomes more important for a larger volume fraction of the metal part of the inclusion. For dielectric coated metal core inclusions and pure metal inclusions there is only one resonant frequency and one peak value of the enhancement factor. The enhancement of an electromagnetic wave is promising for the existence of nonlinear optical phenomena such as optical bistability which is important in optical communication and in optical computing such as optical switch and memory elements. Key words: nanocomposite, cylindrical nanoinclusions, local field, enhancement factor, resonant frequency, optical bistability PACS: 42.65.Pc, 42.79.Ta, 78.67.Sc, 78.67.-n 1. Introduction Classifying the materials based on their electrical, optical, magnetic or chemical properties in the sci- entific community embraces a longer period of time. In another way, the materials can be sorted based on the number of their constituents. According to the number of their constituents, the materials can be classified as monolithic or composite. A monolithic material has a single constituent, while compos- ite materials are made of two or more constituent materials having significantly different physical and chemical properties, that, when combined, produce a material with a characteristic different from the individual components. In a composite material, one of the constituents is a continuous matrix which is called a host matrix while the others dispersed in the host matrix are called inclusions or fillers [1–3]. In recent years, the materials with nano-sized inclusions become an active area of research because they have amusing optical properties and applications without significant physical change in the bulk host medium. Such a material with nano-sized dispersed particles in the matrix where the dimensions of the particles are within the scale of nanometer at least in one direction known as nanocomposites. The properties of a compositematerial are related to the properties and fraction of the constituents, so the electromagnetic properties of the composites can be tailored by varying the properties and fractions of the constituents [3]. Composite materials, consisting of small nonlinear metallic particles (existing in the shape of ellipsoid, sphere or cylinder) are preferred due to their complex responses to the incident light field. Composites are of particular interest because their nonlinearity may be strongly enhanced relative to the bulk sample of the same materials [4], Amusing nonlinear phenomena, for example op- tical bistability, have been predicted theoretically [5] and have been observed experimentally [6]. Their ∗ E-mail: yilakaa@yahoo.com © Y.A. Abbo, V.N. Mal’nev, A.A. Ismail, 2016 33401-1 http://dx.doi.org/10.5488/CMP.19.33401 http://www.icmp.lviv.ua/journal Y.A. Abbo, V.N. Mal’nev, A.A. Ismail promising applications include optical switches in optical communication and in optical computing, as well as in transistor, pulse shaper, and memory elements [5, 7, 8]. The electric field within an atom has the magnitude of Eat = 5.14×1011 V/m and the laser intensity associated with a peak field strength of Eat is Iat = 3.5 × 1016 W/cm 2 . When the applied electric field exceeds the atomic electric field strength, nonlinear optical phenomenon such as optical bistability may occur. The term optical bistability refers to the situation in which two different output intensities are possible for a given input intensity [7]. It may be insufficient to apply an ordinary intense electromagnetic wave such as laser in order to achieve an optical nonlinearity. Thus, the applied field should be enhanced. One way of enhancing the applied electromagnetic field is to modify the property of the bulk medium by introducing very small inclusions, such as nanoinclusions of different shapes. O.A. Buryl et al. studied the local field enhancement at the core of elliptical nanoinclusions in a dielec- tric host matrix [9] and, Sisay and Mal’nev studied the local field enhancement at the core of spherical nanoinclusions in a linear dielectric host matrix [10]. The results of these investigations surpass the re- sults of abnormal enhancement of the local field, when the frequency of the incident electromagnetic wave approaches the surface plasmon frequency of the metal part of the inclusions. To our knowledge, the existence of the second peak value of the enhancement factor was first pre- sented by Sisay andMal’nev [10] for a composite withmetal coted spherical nanoinclusions. In this paper, we have investigated the local field enhancement at the core of cylindrical metal/dielectric nanoinclu- sions embedded in a linear dielectric host matrix. While studying the results of early works, we consid- ered that in addition to different physical quantities, the shape of the inclusion also plays a great role in varying the magnitude of the local field enhancement factor at the core of the inclusions. This work con- firms the existence of the second peak value of the enhancement factor for a composite with metal coated dielectric core cylindrical nanoinclusion. To our knowledge, this original work shows the existence of the second maxima of the enhancement factor for a composite having cylindrical inclusions. 2. Electrical potential distribution In classical electrodynamics, the Laplace equation (i.e., ∇2Φ = 0 ) in a cylindrical coordinate system has a general form given by equation (2.1) [11] : ∂2Φ ∂r 2 + 1 r ∂Φ ∂r + 1 r 2 ∂Φ ∂θ2 + ∂Φ ∂z2 = 0. (2.1) Figure 1 shows that an external electric field Eh is applied perpendicularly to the axis of a cylindrical inclusion. In a cylindrical coordinate system, the potential is two-dimensional and choosing it is not a function of z-axis. In this case, equation (2.1) can be reduced to the form ∂2Φ ∂r 2 + 1 r ∂Φ ∂r + 1 r 2 ∂Φ ∂θ2 = 0. (2.2) The solution of equation (2.2) can yield the potential distribution at different regions of a composite of metal coated dielectric core cylindrical nanoinclusions embedded in a linear dielectric host matrix as: Φ1 =−EhAr cosθ, r É r1 , (2.3) Φ2 =−Eh ( Br − C r ) cosθ, r1 É r É r2 , (2.4) Φ3 =−Eh ( r − D r ) cosθ, r Ê r2 , (2.5) where Φ1, Φ2 and Φ3 are potentials in the dielectric core, metallic shell and the dielectric host matrix, respectively, Eh is the electric field in the host, r1 and r2 are the radii of the dielectric core and the metal shell, respectively, and A, B , C and D are unknown coefficients. The unknown coefficients can be obtained from the electrostatics boundary conditions. Under the long-wave approximation, the case in which the wavelength of the incident electromagnetic wave is 33401-2 Local field enhancement at the core of cylindrical nanoinclusions Figure 1. (Color online) Direction of the applied electric field. greater than the size of the particle, we can use the following electrostatics boundary conditions in order to get the value of the coefficients [12]. • Potential is continuous at the interface, therefore: Φ1 =Φ2 , r = r1 , (2.6) Φ2 =Φh , r = r2 . (2.7) • Displacement vector is continuous at the interface ε1 ∂Φ1 ∂r = ε2 ∂Φ2 ∂r , r = r1 , (2.8) ε2 ∂Φ2 ∂r = εh ∂Φh ∂r , r = r2 , (2.9) where ε1, ε2 and εh are the dielectric constants of the dielectric core, metal shell and dielectric host, respectively. Solving equations (2.6), (2.7), (2.8) and (2.9) simultaneously, can give us the value of the unknown coefficients as listed below: A = 4ε2εh p∆ , (2.10) B = 2εh(ε1 +ε2) p∆ , (2.11) C = 2εh(ε1 −ε2)r 2 1 p∆ , (2.12) D = { 1−2εh [ε2(2−p)+ε1p] p∆ } r 2 2 , (2.13) where p = 1− (r1/r2)2 is the metal volume fraction in the inclusion, ∆ = ε2 2 + qε2 + ε1εh, and q = (2/p − 1)(ε1 +εh). 33401-3 Y.A. Abbo, V.N. Mal’nev, A.A. Ismail 3. Resonant frequencies and enhancement factor of local field In general, the dielectric constant of the host is complex, but for simplicity we take it real. The dielec- tric function of the metal in the inclusion is chosen to be in the Drude form [10] ε2 = ε∞− 1 z(z + iγ) , (3.1) ε′2 = ε∞− 1 z2 +γ2 , (3.2) ε′′2 = γ z(z2 +γ2) , (3.3) where ε′2 and ε ′′ 2 are real and imaginary parts of ε2, respectively, z = ω/ωp is dimensionless frequency, ω is the frequency of the incident radiation, ωp is the plasma frequency of the inclusion metal part, ν is the electron collision frequency and γ= ν/ωp. The dielectric function of the dielectric core is given by ε1 = ε10 +χ|Eh|2, (3.4) where ε10 is the linear part of ε1, χ is known as nonlinear Kerr coefficient (nonlinear susceptibility) and for weak field χ|Eh|2 ¿ ε10. At intense incident electromagnetic fields (laser radiation), it is necessary to consider the nonlinear part of the dielectric. The local field in the core is constant and it can be determined from the gradient of the electrical potential in the core [10]. Eloc =−∇Φ1 = A ·Eh . (3.5) The mathematical expression of the local field enhancement factor for different assemblage of the cylindrical nanoinclusions in terms of the dielectric constants and the metal volume fraction in the inclu- sion is presented in the following three subsections. 3.1. Metal coated cylindrical nanoinclusions Since A is a complex quantity, it is appropriate to take the square of its module, which is a real quan- tity. Hence, the expression for the local field enhancement factor |A|2 is as follows: |A|2 = ρ ( β η+µ ) , (3.6) where ρ = 16ε2 h p2 , (3.7) β= ε′22 +ε′′22 , (3.8) η= (ε′22 −ε′′22 +qε′2 +ε1εh)2, (3.9) µ= ε′′22 (q +2ε′2)2, (3.10) q = ( 2 p −1 ) (ε1 +εh). (3.11) 3.2. Dielectric coated cylindrical nanoinclusions In the case of dielectric coated metal cylindrical nanoinclusions, the expression for the local field enhancement factor can be determined from equation (2.10) by changing ε1 to ε2 and ε2 to ε1. |A|2 = ρ∗ ( 1 η∗+µ∗ ) , (3.12) 33401-4 Local field enhancement at the core of cylindrical nanoinclusions where ρ∗ = 16ε2 1ε 2 h p2 , (3.13) η∗ = (ε2 1 +q∗ε1 +ε′2εh)2, (3.14) µ∗ = [( 2 p −1 ) ε1 +εh ]2 ε′′22 , (3.15) q∗ = ( 2 p −1 ) (ε′2 +εh). (3.16) 3.3. Pure metal cylindrical nanoinclusions The potential distribution for pure metal cylindrical nanoinclusions having radius r2 in a dielectric host matrix is: Φin =−EhAr cosθ, r É r2 , (3.17) Φout =−Eh ( r + B r ) cosθ, r > r2 , (3.18) where Φin and Φout are potentials inside the cylinder and outside the cylinder, respectively, A and B are unknown coefficients which can be obtained from electrostatic boundary conditions. A = 2εh ε2 +εh , (3.19) B = ( ε2 −εh ε2 +εh ) r 2 2 . (3.20) Therefore, the local field enhancement factor for a pure metal cylindrical inclusion becomes: |A|2 = 4ε2 h[ (ε′2 +εh)2 +ε′′22 ] . (3.21) 4. Numerical results and discussion All the numerical values of the dielectric functions of the composite used in this section are taken from [10] and table 1 shows constant values used in numerical calculations. Table 1. Constant values used in numerical calculations. Constant Value ε1 6 εh 2.25 ωp 1.45×1016 ν 1.68×1014 γ 1.15×10−2 4.1. Metal coated dielectric nanoinclusions The series of figures presented below, |A|2 versus z, show that the local field enhancement factor varies with z. For a composite with metal coated dielectric cylindrical nanoinclusions, figure 2 and fig- ure 3 depict that |A|2 has two peak values at two different resonant frequencies. The existence of two resonant frequency is related to the number of interfaces that the metal part of the inclusion has with the two dielectric parts of the composite. The metal shell has interfaces with the host dielectric and the 33401-5 Y.A. Abbo, V.N. Mal’nev, A.A. Ismail Figure 2. (Color online) Enhancement factor |A|2 versus dimensionless frequency z of cylindrical metal inclusion with a dielectric core at different metal fraction in the inclusion p ; ε∞ = 4.5. core dielectric. Hence, the free electrons of the metal oscillate with different surface plasmone frequency along the interface with the dielectric host matrix and along the interface of the core dielectric. At these two resonant frequencies, the enhancement factor of the local field shows a significant increase. Sisay and Mal’nev showed that the value of ε∞ plays a significant role in determining the extent of |A|2 for a composite with spherical inclusions. This study is also capable of confirming the role of ε∞ in varying the magnitude of |A|2 for a composite with cylindrical inclusions. As we decrease the ε∞ , the ex- tent of |A|2 increases and the second maxima become more important. Based on the obtained numerical results for metal volume fraction p = 9 and ε∞ = 4.5, an incident electromagnetic wave can be enhanced around 550 times at the first resonant frequency. For ε∞ = 1 and p = 9, an incident electromagnetic wave can be enhanced around 2500 times at the second resonant frequency. The second quantity which determines the magnitude of |A|2 is the volume fraction of the metal in the inclusion. For ε∞ = 4.5 and ε∞ = 1, the magnitude of the enhancement factor increases as the metal Figure 3. (Color online) Enhancement factor |A|2 versus dimensionless frequency z of cylindrical metal inclusion with a dielectric core at different metal fraction in the inclusion p ; ε∞ = 1. 33401-6 Local field enhancement at the core of cylindrical nanoinclusions Figure 4. (Color online) Enhancement factor |A|2 versus dimensionless frequency z of spherical metal inclusion with a dielectric core at different metal fraction in the inclusion p ; ε∞ = 4.5. fraction in the inclusion (i.e., p) increases, in addition to the two peak values becoming closer to each other. In addition to the value of p and ε∞ , the geometry of the nanoinclusions can be considered as a factor in obtaining a better enhancement of the local field. In order to compare the significant magnitude variation of |A|2 due to the change in the geometry of the inclusions, we have presented the results for spherical inclusion in figure 4 and figure 5. As Sisay and Mal’nev obtained and the authors of this paper numerically confirmed, for the same p , ε∞ and for other dielectric parameters, the value of |A|2 for a composite with spherical inclusion is greater by more than two times when compared with a composite having cylindrical inclusions. For ε∞ = 4.5 and p = 9, the enhancement factor for a composite having spherical inclusions has a magnitude of 1000 at the first resonant frequency. The result of our numerical calculation suggests that for the same dielectric parameter and p value, the magnitude of the enhancement factor for the cylindrical inclusion reduces to 500 at the region of the first resonant frequency. Figure 5. (Color online) Enhancement factor |A|2 versus dimensionless frequency z of spherical metal inclusion with a dielectric core at different metal fraction in the inclusion p ; ε∞ = 1. 33401-7 Y.A. Abbo, V.N. Mal’nev, A.A. Ismail Figure 6. (Color online) Enhancement factor |A|2 versus dimensionless frequency z of cylindrical metal inclusion covered by dielectric at different metal fraction in the inclusion p ; ε∞ = 4.5. 4.2. Dielectric coated metal cylindrical nanoinclusion Figure 6 and figure 7 shows that for a composite with dielectric coated metal cylindrical nanoinclu- sions, there is only one resonant frequency and one maximum value of the enhancement factor. For this type of a composite, varying the thickness of the metal plays a role in obtaining a higher value of the enhancement factor. We can easily observe from the results in figure 6 and figure 7 that, as we decrease the volume fraction of the metal core, the magnitude of the local field enhancement factor rises. Here again, ε∞ determines the magnitude of the enhancement factor and |A|2 is higher for ε∞ = 1 than for ε∞ = 4.5. For p = 0.9 and ε∞ = 4.5, an incident electromagnetic wave can be enhanced about 400 times at the core of the inclusions. For p = 0.9 and ε∞ = 1, the enhancement factor significantly increases in magnitude and it is obtained that the incident field is enhanced beyond 2000. Figure 7. (Color online) Enhancement factor |A|2 versus dimensionless frequency z of cylindrical metal inclusion covered by dielectric at different metal fraction in the inclusion p ; ε∞ = 1. 33401-8 Local field enhancement at the core of cylindrical nanoinclusions 4.3. Pure metal cylindrical nanoinclusions For pure metal inclusions, the main factor that determines the enhancement factor is ε∞ . Figure 8 and figure 9 show that there is only one maximum value of the enhancement factor at one resonant frequency. The magnitude of the enhancement factor significantly increases as we decrease the value of ε∞ . The value of |A|2 for ε∞ = 4.5 is around 500. For ε∞ = 1, we have obtained a very significant rise in the magnitude of |A|2 and numerically it is beyond 4000. Figure 8. (Color online) Enhancement factor |A|2 versus dimensionless frequency z of pure metal cylin- drical inclusion; ε∞ = 4.5. Figure 9. (Color online) Enhancement factor |A|2 versus dimensionless frequency z of pure metal cylin- drical inclusion; ε∞ = 1. 5. Conclusions The numerical results we have obtained in our study show that an incident electromagnetic wave can be significantly enhanced at the core of cylindrical nanoinclusions. For a composite with metal coated dielectric nanoinclusions, there are two peak values of the enhancement factor at two different resonant frequencies. The secondmaxima of the enhancement factor becomesmore important for a larger volume of the metal part of the inclusion. For dielectric coated metal and pure metal inclusions, there is only one maximum of the enhancement factor. 33401-9 Y.A. Abbo, V.N. Mal’nev, A.A. Ismail For coated inclusions, the maximum value of the enhancement factor can be determined by varying the thickness of the metal in the inclusion and ε∞ . For metal coated dielectric inclusions with thick metal cover and small value of ε∞ as well for dielectric coated metal inclusion with thin metal core and small value of ε∞ , the enhancement factor becomes more important. Unlike the coated inclusion, in pure metal inclusion, the only factor that determines the magnitude of the enhancement factor is ε∞ . Lowering the value of ε∞ significantly raises the magnitude of the enhancement factor. This type of a composite is more preferable and more promising for the occurrence of optical bistability based on its capability of enhancing the incident electromagnetic wave better than the composites with coated nanoinclusions. Acknowledgement We gratefully acknowledge and dedicate this paper to our former instructor and thesis advisor Pro- fessor Vadim N. Mal’nev. May his soul rest in peace! References 1. Chen L.F., Ong C.K., Neo C.P., Varadan V.V., Varadan V.K., Microwave Electronics: Measurement and Materials Characterization, Wiley, New York, 2004. 2. Milton G.W., The Theory of Composite, Cambridge University Press, New York, 2004. 3. http://en.wikipedia.org/wiki/Composite_material. 4. Pan T., Huang J.P., Li Z.Y., Physica B, 2001, 301, 190; doi:10.1016/S0921-4526(00)00768-7. 5. Leung K.M., Phys. Rev. A, 1986, 33, 2461; doi:10.1103/PhysRevA.33.2461. 6. Bergman D.S., Levy O., Stroud D., Phys. Rev. B, 1994, 49, 129; doi:10.1103/PhysRevB.49.129. 7. Boyd R.W., Nonlinear Optics, 3rd Edn., Elsevier, London, 2008. 8. Gao L., Yu X.P., Phys. Lett. A, 2005, 335, 457; doi:10.1016/j.physleta.2004.12.036. 9. Buryi O.A., Grechko L.G., Mal’nev V.N., Shewamare S., Ukr. J. Phys., 2011, 56, No. 4, 311. 10. Mal’nev V.N., Shewamare S., Physica B, 2013, 426, 52; doi:10.1016/j.physb.2013.06.013. 11. Jackson J.D., Classical Electrodynamics, 3rd Edn., Wiley, New York, 1999. 12. Bohren C.F., Huffman D.R., Absorption and Scattering of Light by Small Particles, Wiley, New York, 1983. Пiдсилення локального поля в зонi цилiндричних нановключень, вбудованих у лiнiйну дiелектричну матрицю Й.А. Аббо1,2, В.Н.Мальнєв 2, A.A. Iсмаїл2 1 Аддис Абеба (Аско), P.O.BOX 171078, Ефiопiя 2 Фiзичний факультет, Унiверситет м. Аддис Абеба, P.O.BOX 1176, Аддис Абеба, Ефiопiя В цiй статтi ми обговорили теоретичнi концепцiї, а також представили числовi результати пiдсилення локального поля для рiзних компонувань цилiндричних нановключень метал/дiелектрик, вбудованих у лiнiйну дiелектричну базисну матрицю. Отриманi результати показують, що для композиту з пометало- ваними включеннями iснує два пiкових значення коефiцiєнта пiдсилення при двох рiзних резонансних частотах. Iснування другого максимума стає важливiшим для бiльшої об’ємної частки металiчної части- ни включення. Для металевих включень з дiелектричним покриттям є тiльки одна резонансна частота i одне пiкове значення коефiцiєнта пiдсилення. Пiдсилення електромагнiтної хвилi є обнадiйливим для iснування нелiнiйного оптичного явища такого як бiстабiльнiсть, яке є важливим для оптичного зв’язку i оптичних розрахункiв (оптичнi комутатори i елементи пам’ятi). Ключовi слова: нанокомпозит, цилiндричнi нановключення, локальне поле, коефiцiєнт пiдсилення, резонансна частота, оптична бiстабiльнiсть 33401-10 http://en.wikipedia.org/wiki/Composite_material http://dx.doi.org/10.1016/S0921-4526(00)00768-7 http://dx.doi.org/10.1103/PhysRevA.33.2461 http://dx.doi.org/10.1103/PhysRevB.49.129 http://dx.doi.org/10.1016/j.physleta.2004.12.036 http://dx.doi.org/10.1016/j.physb.2013.06.013 Introduction Electrical potential distribution Resonant frequencies and enhancement factor of local field Metal coated cylindrical nanoinclusions Dielectric coated cylindrical nanoinclusions Pure metal cylindrical nanoinclusions Numerical results and discussion Metal coated dielectric nanoinclusions Dielectric coated metal cylindrical nanoinclusion Pure metal cylindrical nanoinclusions Conclusions

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