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VNU Journal of Science: Mathematics – Physics, Vol. 33, No. 1 (2017) 53-59 The Photon - Drag Effect in Rectangular Quantum Wire with An Infinite Potential Hoang Van Ngoc*, Nguyen Vu Nhan, Dinh Quoc Vuong Faculty of Physics, VNU University of Science, 334 Nguyen Trai, Hanoi, Vietnam Received 15 January 2017 Revised 26 February 2017; Accepted 20 March 2017 Abstract: The photon - drag effect with optical phonon-electron scattering in rectangular quantum wire with an infinite potential is studied. Based on the quantum kinetic equation for electrons under the action of a linearly polarized electromagnetic wave, a dc electric field and an intense laser field, analytic expressions for the density of the direct current for the case of electron – optical phonon scattering are calculated. The dependence of the direct current density on the frequency  of the laser radiation field, the frequency  of the linearly polarized electromagnetic wave, the size of the wire is obtained. The analytic expressions are numerically evaluated and plotted for a specific quantum wire, GaAs/AlGaAs. All these results of quantum wire are compared with bulk semiconductors and superlattices to show the differences. Keywords: The photon – drag effect; rectangular quantum wire; optical phonon; infinite potential; the density of the direct current. 1. Introduction The photon – drag effect by electromagnetic wave is explained by carriers absorb both energy and electromagnetic wave momentum, so electrons are generated with detected motion and a direct current arises in this direction, as well as for characterizing kinetic properties of semiconductors [1]. It is known that the presence of intense laser radiation can influence the electrical conductivity and kinetic effects in material [2-9]. In recent years [10 - 12], it has been revealed that the photon - drag effect in superlattices and in quantum wells should be characterized by new features under the action of strong fields. However, in quantum wire, the photon - drag effect still opens for studying. In this work, we use the quantum kinetic to study the drag of charge carriers in rectangular quantum wire with an infinite potential by a linearly polarized electromagnetic, a dc electric field and a laser field. We obtained the density of the current for the case electrons interacting with optical phonon and results are compared with bulk semiconductors and superlattices. The paper has six sections: Introduction, calculating the density of the current by the quantum kinetic equation method, numerical results and discussion, conclusions. _______  Corresponding author. Tel.: 84-986729839 Email: hoangfvanwngocj@gmail.com 53 H.V. Ngoc et al. / VNU Journal of Science: Mathematics – Physics, Vol. 33, No. 1 (2017) 53-59 54 2. Calculating the density of the current by the quantum kinetic equation method We examine the electron system, which is placed in a linearly polarized electromagnetic wave ( E(t)  E(eit  eit ),H(t)  n,E(t)  ), in a dc electric field E 0 and in a strong radiation field F(t)  Fsin t.   The Hamiltonian of the electron - phonon system in the quantum wire can be written as: H = H0 + U =  n,l,pz (pz  n,l,pz +   C .I q n,l,n ,l pz ,q n,l,n ,l e  A(t)).a n,l,p .a n,l,pz   q bq bq + z c q (q)a n,l,ps q .a n,l,pz (bq  b q ) (1) Where A  t  is the vector potential of laser field (only the laser field affects the probability of 1 scattering):  A(t)  F0 sin t ; a n,l,pz and a n,l,pz ( b q and b q ) are the creation and annihilation c operators of electron (phonon); q is the frequency of optical phonon; Cq is the electron-optical phonon interaction constant: Cq2  2e2 0  1 1    ; In ',l',n,l (q) is form factor.  2 0 q z     0  The electron energy takes the simple:  n,l,pz  l  1, 2,3,... ). p2z 2 2  n 2 l2      2m 2m  L2x L2y  ( n  0, 1, 2,... , In order to establish the quantum kinetic equations for electrons in quantum wire, we use general quantum equations for the particle number operator or electron distribution function: i f n,l,pz (t) t  a n,l,pz a n,l,pz , H  t (2)  a n,l,pz t is distribution function. From Eqs. (1) and (2), we obtain the With f n,l,pz (t)  a n,l,p z quantum kinetic equation for electrons in quantum wire (after supplement: a linearly polarized electromagnetic wave field and a direct electric field E 0 ): f n,,l pz (t) t  2   e.E(t)  e.E 0  c  p z , h(t)   n ,l,q  Dn,l,n,l (q) .  J 2L ( 2 L   1 f n,l,pz (t) p z   eE 0 q ) N q f n ,l,pz  q (t)  f n,l,pz (t) .( n ,l,pz q z   n,,l pz  q  L ) m2  f n,l,pz qz (t)  f n,l,pz (t)   n,l,pz qz  n,l,pz  q  L   (3) eE q H is the unit vector in the magnetic field direction, J L ( 0 2 ) is the Bessel function of H m k T real argument; N q is the time-independent component of distribution function of phonon: N q  B ; q Where h  where c is the cyclotron frequency, () is the relaxation time of electrons with energy  . H.V. Ngoc et al. / VNU Journal of Science: Mathematics – Physics, Vol. 33, No. 1 (2017) 53-59 55 For simplicity, we limit the problem to the case of l  0, 1. We multiply both sides Eq. (2) by (e / m)pz (  n,p ) are carry out the summation over n, l and p z , we obtained: (i  1 )R     Q()  S()  c R 0 (),h  () (4) (i  1 )R *     Q()  S* ()  c R 0 (),h  () (5) R 0 ( )  Q0 ()  S0 ()  c R()  R * (), h  () (6) With: R()   Q()     (7) e2 E  p2zf0 (n,l,pz )   n,l,pz m2 k BT n,l,pz   (8) e2 E 0  p2z f0 (n,l,pz )   n,l,pz m2 k BT n,l,pz  (9) Q 0 ( )   S0 ()   e  pz f1 (pz )   n,l,pz m n,l,pz  2 e2 F2 q 2z 2e 2 C I (q) N q f (p )   q n,l,n ',l' q z 10 z m n,l,n ',l',pz ,qz 4m 2  4  ( n ',l',pz  qz   n,l,pz  q  )  ( n ',l',pz  q z   n,l,pz  q  )    (10)  ( n ',l',pz qz   n,l,pz  q  )  ( n ',l',pz q z   n,l,pz  q  )   (   n,l,pz ) where f10 (p z )  p z 0  n,l,pz e f 0 f  n exp(  )   E   ; 0 0 0 n,l,pz ; 0 k BT m  n,l,pz   n0 is particle density; kB is Boltzmann constant; T is temperature of system;. S()   2 e 2 F2 q 2z 2e 2 C I (q) N q f (p )   q n,l,n ',l' q z 1 z m n,l,n ',l',pz ,q z 4m 2  4  ( n ',l',pz  qz   n,l,pz  q  )  ( n ',l',pz  q z   n,l,pz  q  )     ( n ',l',pz qz   n,l,pz  q  )  ( n ',l',pz q z   n,l,p z  q  )   (   n,l,pz ) (11) H.V. Ngoc et al. / VNU Journal of Science: Mathematics – Physics, Vol. 33, No. 1 (2017) 53-59 56 with f1 (pz )  p z     n,l,p  f 0 e ;  E m 1  i   n,l,p  n,l,pz z z  Solving the equation system (4), (5), (6), we obtain: R 0 ()  ()(Q0  S0 )   S,h   2c 2 ()     2   Q, h  2   (  ) Re   c  1  2 2 ()  1  i         (12) The density of current:  2c   F  1  2 2   F  j0   R 0 ()d   AC  D E 0  AC  D   E, h  2 2 2 2 1     1           F  F 0 where  A 2 2 2  n 0 e 6 F2  2   F   1 1  l2     n  2  I exp         n,l,n ',l' 4 4 2 2    80 m    0  n,l,n ',l' 2m  L x L y        N 5/2 2   (2,5/ 2;   N 5/4 2   (2,5/ 2; 2  2  N2 ) 2m N4 ) 2m (3,7/ 2; (3,7/ 2; (14) 1/ 2    N15/ 2    2 2 N1 N1 (3,7/ 2; )  (2,5/ 2; 2m ) 2m     5/ 2     N 3  2 2 2 N2 N3 N3 ) (2,5/ 2; ) (3,7/ 2; )  2m  2m 2m     2 N4 ) 2m  2  1 1 1 1  C   N1  N 2  N 3  N 4     2 2 2 2   2m  (13) (15)   (a,b,z)  1 e zx x a 1 (1  ax)b a 1 dx is the Hypergeometrix function.  (a ) 0  2m  2 2 2 2 2 2 2 2  (n  n )  (l  l )  q     2 2 2 2mL y   2mL x 2 2 2 2  2m    N2   2  (n2  n 2 )  (l2  l2 )  q    2 2 2mL y  2mL x   2m  2 2 2 2 2 2 2 2  N3   2  (n  n )  (l  l )  q    2 2 2mL y  2mL x  N1   (16) (17) (18) H.V. Ngoc et al. / VNU Journal of Science: Mathematics – Physics, Vol. 33, No. 1 (2017) 53-59 N4   57  2m  2 2 2 2 2 2 2 2  (n  n )  (l  l )  q    (  2 2 2 2mL y   2mL x (19) 2 2 2 2 2    n 02 e2 l2     n  D    exp          F  2 2 2    4m k BT  2m  2m  L x L y   n,l    We obtain the expressions for the current density j0 , and select: (20) E  0x ; h  0y : j0x   AC  D E0x ; j0y   AC  D E0y j0z   AC  D E 0z  (21)  2c    F  1  2 2   F  AC  D  E  2 2 2 2 1      F  1      F   (22) Equation (13) shows the dependent of the direct current density on the frequency  of the laser radiation field, the frequency  of the linearly polarized electromagnetic wave, the size of the wire. We also see the dependence of the constant current density on characteristic parameters for quantum wire such as: wave function; energy spectrum; form factor In,l,n’,l’ and potential barrier, that is the difference between the quantum wire, superlattices, quantum wells, and bulk semiconductors. 3. Numerical results and discussion In this section, we will survey, plot and discuss the expressions for j0z for the case of a specific GaAs/GaAsAl quantum wire. The parameters used in the calculations are as follows [2-12]: m = 0,0665m0 (m0 is the mass of free electron);  F = 50meV; (F )  10-11s; n 0  1023 m3 ;   5.3 103 kg / m3 ;   2.2 108 J ; E = 106 V/m; E0 = 5.106V/m; F = 105N. 1 Fig. 1. The dependence of jz on the frequency  of the laser radiation with different values of  Fig. 1 shows the dependence of j0z on the frequency  of the intense laser radiation. From these figure, we can see the nonlinear dependence of j0z on the frequency  of the intense laser radiation, when the frequency  of the intense laser radiation increase joz decreases. 58 H.V. Ngoc et al. / VNU Journal of Science: Mathematics – Physics, Vol. 33, No. 1 (2017) 53-59 Fig. 2. The dependence of jz on the frequency  of the electromagnetic wave with different values of T. Fig. 2 shows the dependence of j0z on the frequency  of the electromagnetic wave, we see there is a resonant peak when  = 2.1*1012rad/s, it shows the resonance of optical phonon at a value of the frequency of electromagnetic wave. Fig. 3. The dependence of j0z on the size of the wire. Fig. 3 shows the dependence of j0z on the size of the wire. From this figure, when radius increase joz decreases, when Lx, Ly continue to increase then j0z will have a stable value, that is the value of the bulk semiconductor (Lx, Ly   ). 4. Conclusions In this paper, we have studied the drag - effect in rectangular quantum wire with a infinite potential. In this case, one dimensional electron systems is placed in a linearly polarized H.V. Ngoc et al. / VNU Journal of Science: Mathematics – Physics, Vol. 33, No. 1 (2017) 53-59 59 electromagnetic wave, a dc electric field and a laser radiation field at high frequency. We obtain the expressions for current density vector j0 , in which, plot and discuss the expressions for j0z . The expressions of j0z show the dependence of j0z on the frequency  of the linearly polarized electromagnetic wave, on the size of the wire, the frequency  of the intense laser radiation; and on the basic elements of quantum wire with a infinite potential. The analytical results are numerically evaluated and plotted for a specific quantum wire GaAs/AlGaAs. These results are compared of the results of quantum wire with bulk semiconductors [1], quantum well [10] and superlattices [11, 12] to show the differences. Acknowledgments This work was completed with financial support from the National Foundation of Science and Technology Development of Vietnam (NAFOSTED) (Grant No. 103. 01 – 2015. 22). References [1] G. M. Shmelev, G. I. Tsurkan and É. M. Épshtein, “Photostumilated radioelectrical transverse effect in semiconductors”, Phys. Stat. Sol. B, Vol. 109 (1982) 53. [2] N. Q. Bau and B. D. Hoi, “Influence of a strong electromagnetic wave (Laser radiation) on the Hall effect in quantum well with a parabolic potential”, J. Korean Phys. Soc, Vol. 60 (2012) 59. [3] V. L. Malevich Izv, “High-frequency conductivity of semiconductors in a laser radiation field”, Radiophysics and quantum electronics, Vol. 20, Issue 1 (1977) 98. [4] M. F. Kimmitt, C. R. Pidgeon, D. A. Jaroszynski, R. J. Bakker, A. F. G. Van Der Meer, and D. 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