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Coherently photo-induced ferromagnetism in diluted magnetic semiconductors J. Fernandez-Rossier ( University of Alicante, UT ), C. Piermarocchi (MS), P.

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Presentation on theme: "Coherently photo-induced ferromagnetism in diluted magnetic semiconductors J. Fernandez-Rossier ( University of Alicante, UT ), C. Piermarocchi (MS), P."— Presentation transcript:

1 Coherently photo-induced ferromagnetism in diluted magnetic semiconductors J. Fernandez-Rossier ( University of Alicante, UT ), C. Piermarocchi (MS), P. Chen ( UCB ), L. J. Sham (UCSD), A.H. MacDonald (UT) Paramagnetic semiconductor (II,Mn)VI can become ferromagnetic when illuminated by coherent unpolarized light of frequency below the semiconductor band-gap.

2 EGEG EFEF Properties of the Diluted paramagnetic (II (1-x),Mn x )-VI (II (1-x),Mn x )-VI (Zn (1-x),Mn x )-Se (Zn (1-x),Mn x )-S (Cd (1-x),Mn x )-Te Mn-Mn interaction: only first neighbors. For x=0.012 0.002 coupled to nn (2%) 0.01 is free (80%) -  PARAMAGNET If doped with holes, FERROMAGNET at Tc<2 Kelvin

3 Laser features: Frequency below gap:  =E G -  L >0 No Photocarriers, no doping Intensity (  =d cv E 0 >0.1 meV) Polarization state: not relevant Coherently photo-induced ferromagnetism

4 This prediction is a logical consequence of: Experimentally established facts Theoretical concepts in agreement with experiments

5 =0 Exchange Interaction. Giant Spin Splitting Selection Rules LL j sd c Mn j pd c Mn B

6 Macroscopic Explanation of optical ferromagnetism Reactive optical energy, due to matter-laser interaction: U depends on : U(M) Ferromagnetism (  0) minimizes U (M) But entropy favours =0 Competition between reactive optical energy and entropy Electric Field of the Laser Real part of retarded Optical Response function

7 Entropic Penalty Paramagnetic Gain (Optical Energy) Functional of Carrier Density Matrix What is the density matrix of the laser driven (II,Mn)-VI semiconductor?

8 Density matrix: effect of the laser LL  Rotating Frame RWA E U (k) E L (k)  >  >(T 1 ) - 1 Coherent Occupation

9 No absorption= No real carriers  eff =  -|J|>0

10 Interaction“Bosonic Model” Laser MatterLinear response (*) h-Mn, e-MnMF VCA Electron-HoleAll orders e-e and h-hIrrelevant (linear response) Microscopic Theory: Relevant Interactions (*) Linear Response: Good if  >  OK, since  >|J|> and |J|>20 meV

11 Microscopic Theory: Bosonic Model

12 012 M -1.45 -1.44 -1.43 -1.42 G (10 -2 meV nm -3 ) (b) -0.4 -0.2 0 S (10 -2 meV nm -3 ) T=115 mK T=105 mK (a) -2012 M -1.2 U (10 -2 meV nm -3 ) 00.51 T /T C 0 1 2 M  =26 meV, T C =780 mK  =41 meV, T C =114 mK  =71 meV, T C =22 mK Results for (Zn 0.988,Mn 0.012 ) S

13 1.50 1.00 0.50 Transition Temperature for (Zn 0.988,Mn 0.012 ) S T c  2 T c  -3 Linear response fails there

14 Isothermal transitions for (Zn,Mn) S T=0.5 K Switching ferromagnetism on and off !!!

15 Materials and Lasers Important material properties: Robust Excitons Not much Mn (x=1%) (Zn,Mn)S, (Zn,Mn)Se (Zn,Mn)O ?? Laser properties: Tunable, around material band-gap Intense lasers T c <50 mK with cw laser Pulse duration longer than Switching time Switching time: interesting question !!!!

16 ORKKY vs coherently photo-induced FM j pd  j sd   The SAME than Bosonic Model (*) C. Piermarocchi, P. Chen, L.J. Sham and D. G. Steel PRL89, 167402 (2002)

17 Conclusions New way of making semiconductors ferromagnetic Ferromagnetism mediated by virtual carriers Originated by optical coherence Possible at T>1 Kelvin (with the right laser)

18 Phase Diagram Always absorbing T (  /J) Absorbing FM Coherent PM Always coherent PM FM T=1.5 K T=2.0 K

19 Interaction ‘BCS’ “Bosonic Model” Laser Matter All orders Linear response (*) h-Mn, e-Mn MF VCA Electron-Hole Pairing All orders Mn-Mn AF s-exc x replaced by x eff e-e and h-h Hartree-Fock Irrelevant (linear response) Microscopic Theory: Relevant Interactions * Linear Response: Good if  >  No absorption= No real carriers= Optical Coherence:  eff =  -|J|>0, where

20 Carrier mediated ferromagnetism Entropic Penalty Paramagnetic gain Functional of carrier density matrix What is the density matrix of the laser driven (II,Mn)-VI semiconductor?

21 BC AlSi NO PS GaGe InSn AsSe Sb II Zn Cd Hg IV V III VI Te EGEG EFEF II-VI Zn-Se Zn-S Cd-Te II BC AlSi NO PS GaGe InSn AsSe Sb IV V III VI Te Zn Cd Hg Mn EGEG EFEF Diluted paramagnetic semiconductor (II,Mn)-VI (Zn,Mn)-Se (Zn,Mn)-S (Cd,Mn)-Te Laser features: Frequency below gap:  =E G -  L >0 No Photocarriers Intense (  =d cv E 0 >0.1 meV) Non circularly polarized Coherently photo-induced ferromagnetism

22 II BC AlSi NO PS GaGe InSn AsSe Sb IV V III VI Te Zn Cd Hg Mn

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