Abstract
Quadratic electro-optic effects (QEOEs) and electro-absorption (EA) process in a GaN/AlGaN spherical quantum dot are theoretically investigated. It is found that the magnitude and resonant position of third-order nonlinear optical susceptibility depend on the nanostructure size and aluminum mole fraction. With increase of the well width and barrier potential, quadratic electro-optic effect and electro-absorption process nonlinear susceptibilities are decreased and blueshifted. The results show that the DC Kerr effect in this case is much larger than that in the bulk case. Finally, it is observed that QEOEs and EA susceptibilities decrease and broaden with the decrease of relaxation time.
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Background
Semiconductor quantum dots with their excellent optoelectronic properties are now mostly used for various technologies such as biological science [1–4], quantum dot lasers [5, 6], light-emitting diodes (LEDs) [7], solar cells [8], infrared and THZ-IR photodetectors [9–14], photovoltaic devices [15], and quantum computing [16, 17]. GaN and AlN are members of III-V nitride family. These wide bandgap semiconductors are mostly appropriate for optoelectronic instrument fabrication.
Third-order nonlinear optical processes in ZnS/CdSe core-shell quantum dots are investigated in [18–20]. It is shown that the symmetry of the confinement potential breaks due to large applied external electric fields and leads to an important blueshift of the peak positions in the nonlinear optical spectrum. The effect of quantum dot size is also studied, and it is verified that large nonlinear third-order susceptibilities can be achieved by increasing the thickness of the nanocrystal shell.
The authors of [21, 22] studied the quadratic electro-optic effects (QEOEs) and electro-absorption (EA) process in InGaN/GaN cylinder quantum dots and CdSe-ZnS-CdSe nanoshell structures. They have found that the position of nonlinear susceptibility peak and its amplitude may be tuned by changing the nanostructure configuration. The obtained susceptibilities in these works are around and 10-15 esu, respectively.
In reference [23], self-focusing effects in wurtzite InGaN/GaN quantum dots are studied. The results of this paper show that the quantum dot size has an immense effect on the nonlinear optical properties of wurtzite InGaN/GaN quantum dots. Also, with decrease of the quantum dot size, the self-focusing effect increases.
In a recent paper [24], we have shown that with the control of GaN/AlGaN spherical quantum dot parameters, different behaviors are obtained. For example, with the increase of well width, third-order susceptibility decreases. The aim of this study is to investigate our proposed GaN/AlGaN quantum dot nanostructure from quadratic electro-optic effect and electro-absorption process points of view. In this paper, we study third-order nonlinear susceptibility of GaN/AlGaN semiconductor quantum dot based on the effective mass approximation. The numerical results have shown that in the proposed structure, the third-order nonlinear susceptibilities near 2 to 5 orders of magnitudes are increased.
The organization of this paper is as follows. In the 'Methods’ section, the theoretical model and background are described. The 'Results and discussion’ section is devoted to the numerical results and discussion. Summarization of numerical results is given in the last section.
Methods
In this section, theoretical model and mathematical background of the third-order nonlinear properties of a new GaN/AlGaN quantum dot nanostructure are presented. The geometry of a spherical centered defect quantum dot and potential distribution of this nanostructure are shown in Figure 1. We consider three regions consisting of a spherical well (with radius a), an inner defect shell (with thickness b - a), and an outer barrier (with radius b). The proposed spherical centered defect quantum dot can be performed by adjusting the aluminum mole fraction.
In this paper, the potential in the core region is supposed to be zero, and the potential difference between two materials is constant [25]. There are various methods for investigating electronic structures of quantum dot systems [26–28]. The effective mass approximation is employed in this study. The time-independent Schrödinger equation of the electron in spherical coordinate can be written as [29].
where m i ∗ and V i (r) are effective mass and potential distribution in different regions. They are obtained as follows [30]:
and
where xd and xb are defect and barrier regions of aluminum molar fraction, respectively. The rest mass of electron is denoted by me, and ΔEc(x) = 0.7 × [Eg(x) - Eg(0)] is the conduction band offset [30]. The bandgap energy of Al x Ga1 - xN is Eg(x) = 6.13x + (1 - x)(3.42 - x) (expressed in electron volts) [30, 31]. In a spherical coordinate, Schrödinger Equation 1 can be readily solved with the separation of variables. Thus, the wave function can be written as
where n is the principal quantum number, and ℓ and m are the angular momentum numbers. Y ℓm (θ, ϕ) is the spherical harmonic function and is the solution of the angular part of the Schrödinger equation. By substituting Equation 4 into Equation 1, the following differential equation is obtained for R nℓ (r):
In order to calculate R nℓ (r), the two E < V01 and E > V01 cases must be considered. With change of variables and some mathematical rearranging, the following spherical Bessel functions in both cases are obtained:
Case 1: E < V01.
where
Case 2: E > V01.
where
For the whole determination of eigenenergies and constants that appeared in the wave function, R nℓ (r) should satisfy the following boundary, convergence, and normalization conditions.
After determining the eigenvalues and wave functions, the third-order susceptibility for two energy levels, ground and first excited states, the model should be described [32, 33]. Thus, the density matrix method [34, 35] is used, and the nonlinear third-order susceptibility corresponding to optical mixing between two incident light fields with frequencies ω1 and ω2 appears in Equation 11:
where q is electron charge, N is carrier density, αfg = 〈ψf|r|ψg〉 indicates the dipole transition matrix element, ωo = (Ef - Eg)/ħ is the resonance frequency between the first excited and ground states (transition frequency), and Γ is the relaxation rate. For the calculation of third-order susceptibility of QEOEs, we take ω1 = 0, ω2 = -ω in Equation 11. The third-order nonlinear optical susceptibility χ(3)(-ω, 0, 0, ω) is a complex function. The nonlinear quadratic electro-optic effect (DC-Kerr effect) and EA frequency dependence susceptibilities are related to the real and imaginary part of χ(3)(-ω, 0, 0, ω) [20–22].
These nonlinear susceptibilities are important characteristics for photoemission or detection applications of quantum dots.
Results and discussion
In this section, numerical results including the quadratic electro-optic effect and electro-absorption process nonlinear susceptibilities of the proposed spherical quantum dot are explained. In our calculations, some of the material parameters are taken as follows. The number density of carriers is N = 1 × 1024 m-3, electrostatic constant is ϵ = (-0.3x + 10.4)ϵo[30, 31], and typical relaxation constants are ℏΓ = 0.27556 and 2.7556 meV which correspond to 15- and 1.5-ps relaxation times, respectively.
The quadratic electro-optic effect and electro-absorption process susceptibilities as functions of pump photon wavelength at 15-ps relaxation time are illustrated in Figure 2. In these figure, the solid and dashed lines show 15- and 30-Å well widths, respectively. It is clear that with the increase of the well width, both QEOEs and EA susceptibilities decreased and blueshifted. These behaviors can be related to quantum confinement effect. Because of the increase of well width, the centered defect acts as small perturbation.
The third-order susceptibility of GaN/AlGaN quantum dot versus pump photon wavelength with different barrier potentials as parameter is shown in Figure 3. The third-order susceptibility is decreased and blueshifted by the increasing barrier potential. These are related to energy levels and dipole transition matrix element behaviors by dot potential. See Figures four and twelve of [24]. So, the resonance wavelength and magnitude of the third-order susceptibility can be managed by the control of well width and confining quantum dot potential.
Same as Figure 2, we illustrate the quadratic electro-optic effect and electro-absorption process susceptibilities as functions of pump photon wavelength at 1.5-ps relaxation time in Figure 4. By comparing Figures 2 and 4, it is observed that the QEOEs and EA susceptibilities decrease and broaden with decreasing relaxation time.
In Figure 5, we show the effect of confining quantum dot potential on third-order susceptibility. As can be seen with increasing barrier potential, the third-order susceptibility is decreased and blueshifted. Full-width at half maximum (FWHM) of third-order susceptibility in Figure 5 is approximately ten times broader than the FWHM in Figure 3.
The effect of relaxation constant (ħ Γ) is demonstrated for two well sizes in Figure 6. It can be seen that the peak of the third-order susceptibility is decreased by the increase of the relaxation rate. It is clear from Equation 11 that the third-order susceptibility has an inverse relationship with relaxation constant. Also, the difference between the peak of susceptibilities in a = 15 Å and a = 30 Å is decreased with the increase of relaxation rate.
Conclusions
In this paper, we have introduced spherical centered defect quantum dot (SCDQD) based on GaN composite nanoparticle to manage electro-optical properties. We have presented that the variation of system parameters can be tuned by the magnitude and wavelength of quadratic electro-optic effects and electro-absorption susceptibilities. For instance, the results show an increase of well width from 15 to 30 Å; the peaks of the both QEOEs and EA susceptibilities are decreased and blueshifted (59.76 to 37.29 μm). With decreasing dot potential, the third-order susceptibility is increased and red shifted (45.25 to 59.76 μm). The effect of relaxation constant (ħ Γ) which is verified by the peak of the third-order susceptibility is decreased by the increasing relaxation rate. These behaviors can be related to the quantum confinement effect and inverse impact of relaxation constant.
Abbreviations
- EA:
-
electro-absorption
- FWHM:
-
full-width at half maximum
- LEDs:
-
light-emitting diodes
- QEOEs:
-
quadratic electro-optic effects
- SCDQD:
-
spherical centered defect quantum dot
References
Valizadeh A, Mikaeili H, Farkhani MSM, Zarghami N, Kouhi M, Akbarzadeh A, Davaran S: Quantum dots: synthesis, bioapplications, and toxicity. Nanoscale Res Lett 2012, 7: 480. 10.1186/1556-276X-7-480
Absalan H, SalmanOgli A, Rostami R: Simulation of a broadband nano-biosensor based on an onion-like quantum dot quantum well structure. Quantum Electron 2013, 43(7):674–678. 10.1070/QE2013v043n07ABEH014990
Bruchez MJ, Moronne M, Gin P, Weiss S, Alivisatos AP: Semiconductor nanocrystals as fluorescent biological labels. Science 1998, 281(5385):2013–2016.
Deb P, Bhattacharyya A, Ghosh SK, Ray R, Lahiri A: Excellent biocompatibility of semiconductor quantum dots encased in multifunctional poly (N-isopropylacrylamide) nanoreservoirs and nuclear specific labeling of growing neurons. Appl Phys Lett 2011, 98(10):103702–103703. 10.1063/1.3562036
Li SG, Gong Q, Cao CF, Wang XZ, Yan JY, Wang Y, Wang HL: The developments of InP-based quantum dot lasers. Infrared Phys Technol 2013, 60: 216–224.
Weng WC, Frank J: On the physics of semiconductor quantum dots for applications in lasers and quantum optics. Prog Quant Electron 2013, 37(3):109–184. 10.1016/j.pquantelec.2013.04.001
Brault J, Damilano B, Kahouli A, Chenot S, Leroux M, Vinter B, Massies J: Ultra-violet GaN/Al0.5Ga0.5N quantum dot based light emitting diodes. J Cryst Growth 2013, 363: 282–286.
Nozik AJ: Quantum dot solar cells. Phys E 2002, 14: 115–120. 10.1016/S1386-9477(02)00374-0
Su X, Chakrabarti S, Bhattacharya P, Ariyawansa G, Perera AGU: A resonant tunneling quantum-dot infrared photodetector. IEEE J Quantum Electron 2005, 41: 974–979.
Su XH, Yang J, Bhattacharya P, Ariyawansa G, Perera AG: Terahertz detection with tunneling quantum dot intersublevel photodetector. Appl Phys Lett 2006, 89: 031117–1-031117–3.
Huang G, Yang J, Bhattacharya P, Ariyawansa G, Perera AG: A multicolor quantum dot intersublevel detector with photoresponse in the terahertz range. Appl Phys Lett 2008, 92: 011117–1-011117–3.
Kochman B, Stiff-Roberts AD, Chakrabarti S, Phillips JD, Krishna S, Singh J, Bhattacharya P: Absorption, carrier lifetime, and gain in InAs–GaAs quantum-dot infrared photodetectors. IEEE J Quantum Electron 2003, 39: 459–467. 10.1109/JQE.2002.808169
Rasooli Saghai H, Sadoogi N, Rostami A, Baghban H: Ultra-high detectivity room temperature THZ IR photodetector based on resonant tunneling spherical centered defect quantum dot (RT-SCDQD). Opt Commun 2009, 282: 3499–3508. 10.1016/j.optcom.2009.05.064
Asadpour SH, Golsanamlou Z, Rahimpour Soleimani H: Infrared and terahertz signal detection in a quantum dot nanostructure. Phys E 2013, 54: 45–52.
McDonald SA, Konstantatos G, Zhang S, Cyr PW, Klem EJD, Levina L, Sargent EH: Solution-processed PbS quantum dot infrared photodetectors and photovoltaics. Nat Mater 2005, 4: 138–142. 10.1038/nmat1299
Loss D, DiVincenzo DP: Quantum computation with quantum dots. Phys Rev A 1998, 57: 120–126. 10.1103/PhysRevA.57.120
Bose R, Johnson HT: Coulomb interaction energy in optical and quantum computing applications of self-assembled quantum dots. Microelectron Eng 2004, 75(1):43–53. 10.1016/j.mee.2003.11.008
Cristea M, Niculescu EC: Hydrogenic impurity states in CdSe/ZnS and ZnS/CdSe core-shell nanodots with dielectric mismatch. Eur Phys J B 2012, 85: 191.
Niculescu EC, Cristea M: Impurity states and photoionization cross section in CdSe/ZnS core–shell nanodots with dielectric confinement. J Lumin 2013, 135: 120–127.
Cristea M, Radu A, Niculescu EC: Electric field effect on the third-order nonlinear optical susceptibility in inverted core–shell nanodots with dielectric confinement. J Lumin 2013, 143: 592–599.
Wang C, Xiong G: Quadratic electro-optic effects and electro-absorption process in InGaN/GaN cylinder quantum dots. Microelectron J 2006, 37: 847–850. 10.1016/j.mejo.2006.03.007
Bahari A, Rahimi-Moghadam F: Quadratic electro-optic effect and electro-absorption process in CdSe–ZnS–CdSe structure. Phys E 2012, 44(4):782–785. 10.1016/j.physe.2011.11.028
Kaviani H, Asgari A: Investigation of self-focusing effects in wurtzite InGaN/GaN quantum dots. Optik 2013, 124(8):734–739. 10.1016/j.ijleo.2012.01.012
Vahedi A, Kouhi M, Rostami A: Third order susceptibility enhancement using GaN based composite nanoparticle. Optik 2013, 124(9):6669–6675.
Schooss D, Mews A, Eychmuller A, Weller H: Quantum-dot quantum well CdS/HgS/CdS: theory and experiment. Phys Rev B 1994, 49: 17072–17078. 10.1103/PhysRevB.49.17072
Wang LW, Williamson AJ, Zunger A, Jiang H, Singh J: Compression of the K.P. and direct diagonalization approaches to the electronic structure of InAs/GaAs quantum dots. Appl Phys Lett 2000, 76: 339–342. 10.1063/1.125747
Ngo CY, Yoon SF, Fan WJ, Chua SC: Effects of size and shape on electronic states of quantum dots. Phys Rev B 2006, 74: 245331.
Fang Y, Xiao M, Yao D: Quantum size dependent optical nutation in CdSe/ZnS/CdSe quantum dot quantum well. Phys E 2010, 42: 2178–2183. 10.1016/j.physe.2010.03.036
Griffiths DJ: Introduction to Quantum Mechanics. Boston: Addison-Wesley; 2004.
Asgari A, Kalafi M, Faraone L: The effects of GaN capping layer thickness on two-dimensional electron mobility in GaN/AlGaN/GaN heterostructures. Phys E 2005, 25: 431–437. 10.1016/j.physe.2004.07.002
Liu J, Bai Y, Xiong G: Studies of the second-order nonlinear optical susceptibilities of GaN/AlGaN quantum well. Phys E 2004, 23: 70–74. 10.1016/j.physe.2004.01.004
Boyd RW: Nonlinear Optics. New York: Academic; 1992.
Shen YR: The Principles of Nonlinear Optics. New York: Wiley; 2003.
Zhang X, Xiong G, Feng X: Well width-dependent third-order optical nonlinearities of a ZnS/CdSe cylindrical quantum dot quantum well. Phys E 2006, 33: 120–124. 10.1016/j.physe.2005.11.017
Takagahara T: Excitonic optical nonlinearity and exciton dynamics in semiconductor quantum dots. Phys Rev B 1987, 36: 9293–9296. 10.1103/PhysRevB.36.9293
Acknowledgements
The authors thank the Department of Physics, Tabriz Branch, Islamic Azad University, and the Department of Medical Nanotechnology, Faculty of Advanced Medical Science of Tabriz University for all the supports provided. This work is funded by the Grant 2011-0014246 of the National Research Foundation of Korea.
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MK conceived of the study and participated in its design and coordination. AV assisted in the numerical calculations. AA and YH participated in the sequence alignment and drafted the manuscript. SWJ supervised the whole study. All authors read and approved the final manuscript.
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Kouhi, M., Vahedi, A., Akbarzadeh, A. et al. Investigation of quadratic electro-optic effects and electro-absorption process in GaN/AlGaN spherical quantum dot. Nanoscale Res Lett 9, 131 (2014). https://doi.org/10.1186/1556-276X-9-131
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DOI: https://doi.org/10.1186/1556-276X-9-131