Hydrostatic pressure and temperature effects on nonlinear optical rectification in a lens shape InAs/GaAs quantum dot
Identifieur interne : 000B70 ( Main/Repository ); précédent : 000B69; suivant : 000B71Hydrostatic pressure and temperature effects on nonlinear optical rectification in a lens shape InAs/GaAs quantum dot
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Abstract
We have performed theoretical calculation of the nonlinear optical rectification in a lens shape InAs/ GaAs quantum dot (0D). The combined effects of hydrostatic pressure and temperature on the nonlinear optical rectification in lens-shaped InAs QDs are studied under the compact density matrix formalism and the effective mass approximation. From our calculation, it is found that the subband energies and optical rectification susceptibility are quite sensitive to the applied hydrostatic pressure and temperature. The results show that the resonant peak of the optical rectification can be red-shifted or blue-shifted and their intensity also varied by external probes such as hydrostatic pressure and temperature. In addition, the oscillator strength is strongly affected by these parameters.
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<record><TEI><teiHeader><fileDesc><titleStmt><title xml:lang="en" level="a">Hydrostatic pressure and temperature effects on nonlinear optical rectification in a lens shape InAs/GaAs quantum dot</title><author><name sortKey="Bouzaiene, L" uniqKey="Bouzaiene L">L. Bouzaïene</name><affiliation wicri:level="1"><inist:fA14 i1="01"><s1>Laboratoire de Micro-optoélectronique et Nanostructures, Département de Physique, Faculté des Sciences de Monastir, Université de Monastir</s1><s3>TUN</s3><sZ>1 aut.</sZ><sZ>2 aut.</sZ><sZ>3 aut.</sZ><sZ>4 aut.</sZ><sZ>5 aut.</sZ></inist:fA14><country>Tunisie</country><wicri:noRegion>Laboratoire de Micro-optoélectronique et Nanostructures, Département de Physique, Faculté des Sciences de Monastir, Université de Monastir</wicri:noRegion></affiliation></author><author><name sortKey="Ben Mahrsia, R" uniqKey="Ben Mahrsia R">R. Ben Mahrsia</name><affiliation wicri:level="1"><inist:fA14 i1="01"><s1>Laboratoire de Micro-optoélectronique et Nanostructures, Département de Physique, Faculté des Sciences de Monastir, Université de Monastir</s1><s3>TUN</s3><sZ>1 aut.</sZ><sZ>2 aut.</sZ><sZ>3 aut.</sZ><sZ>4 aut.</sZ><sZ>5 aut.</sZ></inist:fA14><country>Tunisie</country><wicri:noRegion>Laboratoire de Micro-optoélectronique et Nanostructures, Département de Physique, Faculté des Sciences de Monastir, Université de Monastir</wicri:noRegion></affiliation></author><author><name sortKey="Baira, M" uniqKey="Baira M">M. Baira</name><affiliation wicri:level="1"><inist:fA14 i1="01"><s1>Laboratoire de Micro-optoélectronique et Nanostructures, Département de Physique, Faculté des Sciences de Monastir, Université de Monastir</s1><s3>TUN</s3><sZ>1 aut.</sZ><sZ>2 aut.</sZ><sZ>3 aut.</sZ><sZ>4 aut.</sZ><sZ>5 aut.</sZ></inist:fA14><country>Tunisie</country><wicri:noRegion>Laboratoire de Micro-optoélectronique et Nanostructures, Département de Physique, Faculté des Sciences de Monastir, Université de Monastir</wicri:noRegion></affiliation></author><author><name sortKey="Sfaxi, L" uniqKey="Sfaxi L">L. Sfaxi</name><affiliation wicri:level="1"><inist:fA14 i1="01"><s1>Laboratoire de Micro-optoélectronique et Nanostructures, Département de Physique, Faculté des Sciences de Monastir, Université de Monastir</s1><s3>TUN</s3><sZ>1 aut.</sZ><sZ>2 aut.</sZ><sZ>3 aut.</sZ><sZ>4 aut.</sZ><sZ>5 aut.</sZ></inist:fA14><country>Tunisie</country><wicri:noRegion>Laboratoire de Micro-optoélectronique et Nanostructures, Département de Physique, Faculté des Sciences de Monastir, Université de Monastir</wicri:noRegion></affiliation></author><author><name sortKey="Maaref, H" uniqKey="Maaref H">H. Maaref</name><affiliation wicri:level="1"><inist:fA14 i1="01"><s1>Laboratoire de Micro-optoélectronique et Nanostructures, Département de Physique, Faculté des Sciences de Monastir, Université de Monastir</s1><s3>TUN</s3><sZ>1 aut.</sZ><sZ>2 aut.</sZ><sZ>3 aut.</sZ><sZ>4 aut.</sZ><sZ>5 aut.</sZ></inist:fA14><country>Tunisie</country><wicri:noRegion>Laboratoire de Micro-optoélectronique et Nanostructures, Département de Physique, Faculté des Sciences de Monastir, Université de Monastir</wicri:noRegion></affiliation></author></titleStmt><publicationStmt><idno type="inist">13-0113073</idno><date when="2013">2013</date><idno type="stanalyst">PASCAL 13-0113073 INIST</idno><idno type="RBID">Pascal:13-0113073</idno><idno type="wicri:Area/Main/Corpus">001155</idno><idno type="wicri:Area/Main/Repository">000B70</idno></publicationStmt><seriesStmt><idno type="ISSN">0022-2313</idno><title level="j" type="abbreviated">J. lumin.</title><title level="j" type="main">Journal of luminescence</title></seriesStmt></fileDesc><profileDesc><textClass><keywords scheme="KwdEn" xml:lang="en"><term>Density matrix</term><term>Effective mass model</term><term>Gallium arsenides</term><term>Hydrostatic pressure</term><term>Indium arsenides</term><term>Nonlinear optical susceptibility</term><term>Nonlinear optics</term><term>Optical rectification</term><term>Oscillator strengths</term><term>Semiconductor quantum dots</term><term>Temperature effects</term></keywords><keywords scheme="Pascal" xml:lang="fr"><term>Pression hydrostatique</term><term>Effet température</term><term>Optique non linéaire</term><term>Rectification optique</term><term>Point quantique semiconducteur</term><term>Susceptibilité optique non linéaire</term><term>Matrice densité</term><term>Modèle masse effective</term><term>Arséniure d'indium</term><term>Arséniure de gallium</term><term>Force oscillateur</term><term>InAs</term><term>GaAs</term><term>4265A</term><term>4270N</term></keywords></textClass></profileDesc></teiHeader><front><div type="abstract" xml:lang="en">We have performed theoretical calculation of the nonlinear optical rectification in a lens shape InAs/ GaAs quantum dot (0D). The combined effects of hydrostatic pressure and temperature on the nonlinear optical rectification in lens-shaped InAs QDs are studied under the compact density matrix formalism and the effective mass approximation. From our calculation, it is found that the subband energies and optical rectification susceptibility are quite sensitive to the applied hydrostatic pressure and temperature. The results show that the resonant peak of the optical rectification can be red-shifted or blue-shifted and their intensity also varied by external probes such as hydrostatic pressure and temperature. In addition, the oscillator strength is strongly affected by these parameters.</div></front></TEI><inist><standard h6="B"><pA><fA01 i1="01" i2="1"><s0>0022-2313</s0></fA01><fA02 i1="01"><s0>JLUMA8</s0></fA02><fA03 i2="1"><s0>J. lumin.</s0></fA03><fA05><s2>135</s2></fA05><fA08 i1="01" i2="1" l="ENG"><s1>Hydrostatic pressure and temperature effects on nonlinear optical rectification in a lens shape InAs/GaAs quantum dot</s1></fA08><fA11 i1="01" i2="1"><s1>BOUZAÏENE (L.)</s1></fA11><fA11 i1="02" i2="1"><s1>BEN MAHRSIA (R.)</s1></fA11><fA11 i1="03" i2="1"><s1>BAIRA (M.)</s1></fA11><fA11 i1="04" i2="1"><s1>SFAXI (L.)</s1></fA11><fA11 i1="05" i2="1"><s1>MAAREF (H.)</s1></fA11><fA14 i1="01"><s1>Laboratoire de Micro-optoélectronique et Nanostructures, Département de Physique, Faculté des Sciences de Monastir, Université de Monastir</s1><s3>TUN</s3><sZ>1 aut.</sZ><sZ>2 aut.</sZ><sZ>3 aut.</sZ><sZ>4 aut.</sZ><sZ>5 aut.</sZ></fA14><fA20><s1>271-275</s1></fA20><fA21><s1>2013</s1></fA21><fA23 i1="01"><s0>ENG</s0></fA23><fA43 i1="01"><s1>INIST</s1><s2>14666</s2><s5>354000182565200450</s5></fA43><fA44><s0>0000</s0><s1>© 2013 INIST-CNRS. All rights reserved.</s1></fA44><fA45><s0>22 ref.</s0></fA45><fA47 i1="01" i2="1"><s0>13-0113073</s0></fA47><fA60><s1>P</s1></fA60><fA61><s0>A</s0></fA61><fA64 i1="01" i2="1"><s0>Journal of luminescence</s0></fA64><fA66 i1="01"><s0>NLD</s0></fA66><fC01 i1="01" l="ENG"><s0>We have performed theoretical calculation of the nonlinear optical rectification in a lens shape InAs/ GaAs quantum dot (0D). The combined effects of hydrostatic pressure and temperature on the nonlinear optical rectification in lens-shaped InAs QDs are studied under the compact density matrix formalism and the effective mass approximation. From our calculation, it is found that the subband energies and optical rectification susceptibility are quite sensitive to the applied hydrostatic pressure and temperature. The results show that the resonant peak of the optical rectification can be red-shifted or blue-shifted and their intensity also varied by external probes such as hydrostatic pressure and temperature. In addition, the oscillator strength is strongly affected by these parameters.</s0></fC01><fC02 i1="01" i2="3"><s0>001B40B65A</s0></fC02><fC02 i1="02" i2="3"><s0>001B40B70N</s0></fC02><fC03 i1="01" i2="3" l="FRE"><s0>Pression hydrostatique</s0><s5>01</s5></fC03><fC03 i1="01" i2="3" l="ENG"><s0>Hydrostatic pressure</s0><s5>01</s5></fC03><fC03 i1="02" i2="3" l="FRE"><s0>Effet température</s0><s5>02</s5></fC03><fC03 i1="02" i2="3" l="ENG"><s0>Temperature effects</s0><s5>02</s5></fC03><fC03 i1="03" i2="3" l="FRE"><s0>Optique non linéaire</s0><s5>03</s5></fC03><fC03 i1="03" i2="3" l="ENG"><s0>Nonlinear optics</s0><s5>03</s5></fC03><fC03 i1="04" i2="3" l="FRE"><s0>Rectification optique</s0><s5>04</s5></fC03><fC03 i1="04" i2="3" l="ENG"><s0>Optical rectification</s0><s5>04</s5></fC03><fC03 i1="05" i2="3" l="FRE"><s0>Point quantique semiconducteur</s0><s5>05</s5></fC03><fC03 i1="05" i2="3" l="ENG"><s0>Semiconductor quantum dots</s0><s5>05</s5></fC03><fC03 i1="06" i2="3" l="FRE"><s0>Susceptibilité optique non linéaire</s0><s5>06</s5></fC03><fC03 i1="06" i2="3" l="ENG"><s0>Nonlinear optical susceptibility</s0><s5>06</s5></fC03><fC03 i1="07" i2="3" l="FRE"><s0>Matrice densité</s0><s5>08</s5></fC03><fC03 i1="07" i2="3" l="ENG"><s0>Density matrix</s0><s5>08</s5></fC03><fC03 i1="08" i2="X" l="FRE"><s0>Modèle masse effective</s0><s5>09</s5></fC03><fC03 i1="08" i2="X" l="ENG"><s0>Effective mass model</s0><s5>09</s5></fC03><fC03 i1="08" i2="X" l="SPA"><s0>Modelo masa efectiva</s0><s5>09</s5></fC03><fC03 i1="09" i2="3" l="FRE"><s0>Arséniure d'indium</s0><s2>NK</s2><s5>10</s5></fC03><fC03 i1="09" i2="3" l="ENG"><s0>Indium arsenides</s0><s2>NK</s2><s5>10</s5></fC03><fC03 i1="10" i2="3" l="FRE"><s0>Arséniure de gallium</s0><s2>NK</s2><s5>12</s5></fC03><fC03 i1="10" i2="3" l="ENG"><s0>Gallium arsenides</s0><s2>NK</s2><s5>12</s5></fC03><fC03 i1="11" i2="3" l="FRE"><s0>Force oscillateur</s0><s5>13</s5></fC03><fC03 i1="11" i2="3" l="ENG"><s0>Oscillator strengths</s0><s5>13</s5></fC03><fC03 i1="12" i2="3" l="FRE"><s0>InAs</s0><s4>INC</s4><s5>76</s5></fC03><fC03 i1="13" i2="3" l="FRE"><s0>GaAs</s0><s4>INC</s4><s5>77</s5></fC03><fC03 i1="14" i2="3" l="FRE"><s0>4265A</s0><s4>INC</s4><s5>78</s5></fC03><fC03 i1="15" i2="3" l="FRE"><s0>4270N</s0><s4>INC</s4><s5>79</s5></fC03><fN21><s1>084</s1></fN21></pA></standard></inist></record>Pour manipuler ce document sous Unix (Dilib)
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