Magnetic measurements on the spin-glass behavior in the bulk II-VI diluted magnetic semiconductor (DMS) ZnMnTe were made on two crystals of concentrations x = 0.43 and 0.55 taken from the same boule. Magnetization and density functional theory studies have shown paramagnetic behavior in both samples between 30 and 400 K. Below 30 K, there is a prominent peak at Tc = 15 and 23.6 K for concentrations x = 0.43 and 0.55, respectively. The splitting of the field cooled (FC) and zero field cooled (ZFC) data below this peak is indicative of a transition to a spin-glass state at low temperature for semiconductors. Therefore, through the p− and d− orbits hybridization a magnetic exchange produces the spin-glass behavior seen in the DMS ZnMnTe

Alcantara, A.

Barrett, S.

Haraldsen, J. T.

Matev, D.

Miotkowski, I.

Pekarek, T.

Ramdas, A. K.

English

Project of Merit Winner
International Research Symposium Exhibitor and Honorable Mention
To gain insight into the spin-glass state of diluted magnetic semiconductors, we have examined the magnetic and electronic properties of Mn-doped ZnTe using density functional theory. Using a generalized gradient approximation, we investigate the electronic and magnetic properties for x=0, 0.25, and 0.50 doping levels using the magnetic moment of Mn2+ as guide for the dependence of the Hubbard onsite potential on the electronic structure as well as a geometry optimization to assure an anti-ferromagnetic (AFM) ground state which is consistent with a zero magnetic moment spin glass state. An onsite potential of up to 8 eV on the Mn 3d-orbitals is needed to harden the magnetic moment toward S = 5/2. From our analysis of the electronic structure evolution with doping and onsite potential, we confirm the semiconducting state of the Mn-doped ZnTe as well as show that the presence of Mn incorporated into the ZnTe matrix at the Zn lattice site produces magnetic interactions through the Te ions with a distinct Te-Mn pd-orbital hybridization. Furthermore, we show that this hybridization is activated with the Mn doping above 25%, which corresponds to the doping level in which the spin-glass transition begins to rise. Therefore, it is likely that the coupling of pd-orbital hybridization of the Mn and Te p-orbitals is a precursor to the spin-glass state

Pekarak, T.

UNF Digital Commons

Understanding the spin-glass state through the magnetic & electronic properties of Mn­doped ZnTe A. Alcantara1, S. Barrett1, D. Matev1, I. Miotkowski2, A.K. Ramdas2, T. Pekarek1, and J. T. Haraldsen1 1Department of Physics, University of North Florida, Jacksonville, Florida, USA Physics ABSTRACT: To gain insight into the spin-glass state of diluted magnetic semiconductors, we have examined the magnetic and electronic properties of Mn-doped ZnTe using density functional theory. Using a generalized gradient approximation, we investigate the electronic and magnetic properties for x=0, 0.25, and 0.50 doping levels using the magnetic moment of Mn2+ as guide for the dependence of the Hubbard onsite potential on the electronic structure as well as a geometry optimization to assure an anti­ferromagnetic (AFM) ground state which is consistent with a zero magnetic moment spin glass state. An onsite potential of up to 8 eV on the Mn 3d-orbitals is needed to harden the magnetic moment toward S = 5/2. From our analysis of the electronic structure evolution with doping and onsite potential, we confirm the semiconducting state of the Mn-doped Zn Te as well as show that the presence of Mn incorporated into the ZnTe matrix at the Zn lattice site produces magnetic interactions through the Te ions with a distinct Te-Mn pd­orbital hybridization. Furthermore, we show that this hybridization is activated with the Mn doping above 25%, which corresponds to the doping level in which the spin-glass transition begins to rise. Therefore, it is likely that the coupling of pd-orbital hybridization of the Mn and Te p -orbitals is a precursor to the spin­glass state. METHODS: The ab-initio calculations are performed through density functional theory by using the atomistic orbital approach implemented in Quantum Atomistix Toolkit (QuantumATK). Calculations are carried out within the spin­polarized generalized gradient approximation (SGGA) to the exchange-correlation functional (PBE) with a variable onsite potential. Hubbard U was used to assure the ground state magnetic moment of spin 5/2. Magnetization measurements (not shown) were performed using a Quantum Design MPMS XL 7 superconducting quantum interference device (SQUID) magnetometer. 25 20 � �15 10 5 0 0.0 <f Cl.) Cl.) � c::' :, � to :::, C, • 0.1 0.2 0.3 X 2Department of Physics, Purdue University, West Lafayette, Indiana, USA 0.4 0.5 0.6 5.25 ,----....--�-� - ---.-----, m agn eti c moment -::::---·-;:::::::­5.00 ,,-.... -;:::;;---64.75 ::t -+-25% -+-50% 4.50 4.25 '-----�--� -..__--�� 0 2 4 6 8 U (eV) 2.0 .--�----r--....---.--�--.-----, J.5 : 25% : 50% energy gap 0.0 '---�----'- -�-..__� _ _.__ _�___, 0 2 4 6 U (eV) (a) • • ' ', -, �. W·• • • • � (b) • • Physics Zn-blend structure XU WK L.,.10 .5 0 5 10·1 0 1 ·1 0 TOOS (AA>. Units) TDOS LOOS-Zn LOOS-Te (Arb, Un;IS) (Arb, Un;IS) (Arb, Un;ts) 0 ,., 0 t-& 0 LOOS.Zn LOOS.Te LOOS-Mn (AA>. Unds) (AA>. Unds) (Arb Uncs) It X "_. U •10 4 0 !I lfl O I •I O I 4 0 TDOS LOOS-Zn LOOS-Te LOOS.Mn (AA> Unls) (Arb Units) (AA>. Unis) (Arb Unfts) 

Understanding the spin-glass state through the magnetic & electronic properties of Mn-doped ZnTe

Non-Cognitive Predictors of Student Success:A Predictive Validity Comparison Between Domestic and International StudentsNon-Cognitive Predictors of Student Success:A Predictive Validity Comparison Between Domestic and International StudentsThe spin-glass nature of the Mn-doped ZnTeis produced through the magnetic exchange interactions and mediated by a p-and d- orbital hybridization.Non-Cognitive Predictors of Student Success:A Predictive Validity Comparison Between Domestic and International StudentsABSTRACT: To understand the spin-glass state of dilutedmagnetic semi-conductors, we haveexamined the magnetic properties of Zn1-xMnxTe using density functional theory andmagnetization measurements. Utilizing thegeneralized gradient approximation, weinvestigate the dependence of the Hubbardonsite potential on the magnetization andelectronic structure. We find that the groundstate magnetic preference isantiferromagnetic and that the onsite potentialis needed to harden the magnetic moment ofS = 5/2. Furthermore, the system is clearlysemi-conducting, which suggests that thespin-glass nature of the compound isproduced through the magnetic exchangeinteractions thr ugh the p- and d-orbitalhybridization.METHODS:The ab-initio calculations are performedbased on the density functional theory byusing the atomistic orbital approachimplemented in Quantum Atomistix Toolkit(QuantumATK). Calculations are carried outwithin the spin-polarized generalized gradientapproximation (SGGA) to the exchange-correlation functional (PBE) with a variableonsite potential. The Hubbard U was used toassure the ground state magnetic moment ofspin 5/2. Magnetization measurements (notshown) were performed using a QuantumDesign MPMS XL7 superconducting quantuminterference device (SQUID) magnetometer.Understanding the spin-glass state through the magnetic properties of Mn-doped ZnTeA . Alcantara1, S. Barrett1, D. Matev1, I. Miotkowski2, A.K. Ramdas2, T. Pekarek1, and J. T. Haraldsen11Department of Physics, University of North Florida, Jacksonville, Florida, USA2Department of Physics, Purdue University, West Lafayette, Indiana, USATake a picture to go to the  UNF Materials Theory websit e25% doping50% dopingZn-blend structurePhysics , .... ~-Magnetic m--on the 111.ywed Ill-VI dilullld ffl8SIM81ic Hmlcanduclar Ga, -AMn.S T, M, -~M. Dl/ffy, ondJ.Gomor ,,__., ___ ,,, ____ ,.....,,,,. B."-..--<fl'/qri<•""""""""'-,.-""'""""" I. Mlot- ond A. K. 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Understanding the spin-glass state through the magnetic properties of Mn-doped ZnTe

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Understanding the spin-glass state through the magnetic properties of Mn-doped ZnTe

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