Electric field control of room temperature ferromagnetism in III-N dilute magnetic semiconductor films

Nepal, Neeraj; Luen, M. Oliver; Zavada, J. M.; Bedair, S. M.; Frajtag, Pavel; El‐Masry, N. A.

doi:10.1063/1.3110963

Cited by 28 publications

(20 citation statements)

References 16 publications

(15 reference statements)

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“…Indeed, a number of experiments have shown that an increased hole concentration in Ga 1−x Mn x N from codoping with p-type elements such as Mg improves the ferromagnetic properties. 28,[53][54][55] The difficulty in achieving an efficient p-type doping of GaN ensures that this method of encouraging ferromagnetism in Ga 1−x Mn x N remains a significant challenge.…”

Section: Discussionmentioning

confidence: 99%

Nearest-neighbor Mn antiferromagnetic exchange inGa1−xMnxN

et al. 2010

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We analyze the magnetic behavior of well-characterized, precipitate-free Ga 1−x Mn x N thin films containing Mn at higher levels than previously attained; up to x = 0.36. This level is above the percolation threshold x c for nearest-neighbor cations, such that exchange between nearest neighbors will dominate the magnetic response. The susceptibility decreases as the Mn content increases up to and beyond x c , as an increasing fraction of the Mn experiences antiferromagnetic exchange. The dominance of antiferromagnetic behavior at higher Mn concentrations and the total lack of evidence for ferromagnetic ordering even above x c demonstrates that the nature of the exchange between Mn 2+ ions in GaN is antiferromagnetic.

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Section: Discussionmentioning

confidence: 99%

Nearest-neighbor Mn antiferromagnetic exchange inGa1−xMnxN

et al. 2010

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“…With the manipulation of carrier spins, a new generation of nonvolatile (green) computing systems could be eventually developed for many low-power-dissipation applications in all fields, including sensor network, health monitoring, information, and sustainable wireless system. Since Datta and Das [131] first introduced the concept of spin FETs in 1990, enormous efforts were dedicated to creating a device wherein the carrier transport is modulated by electrostatic control of carrier spins [2,20,22,23,[132][133][134][135][136]. To understand and exploit this controllability, several theoretical models were proposed to explain the ferromagnetic coupling in DMS on a microscopic scale (also elaborated in the theoretical section): the Zener Kinetic-exchange [10], double-exchange [137], and the RKKY interaction [138,139].…”

Section: Electric-field-controlled Ferromagnetismmentioning

confidence: 99%

“…In these materials, high magnetic impurity concentrations are needed due to the lack of longrange interaction among magnetic spins. However, there have been only limited reports on the carrier mediated effect in the wide band gap materials at room temperature [20][21][22]. Though considerable amount of work has been done on III-V and II-VI DMSs [2,23], the lack of high T c and the difficulty in achieving electric field modulated ferromagnetism (carrier-mediated ferromagnetism) at or above room temperature deters them from being considered for semiconductor integration.…”

Section: Introductionmentioning

confidence: 99%

Magnetic Mn-Doped Ge Nanostructures

Xiu

2012

ISRN Condensed Matter Physics

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With the seemly limit of scaling on CMOS microelectronics fast approaching, spintronics has received enormous attention as it promises next-generation nanometric magnetoelectronic devices; particularly, the electric field control of ferromagnetic transition in dilute magnetic semiconductor (DMS) systems offers the magnetoelectronic devices a potential for low power consumption and low variability. Special attention has been given to technologically important group IV semiconductor based DMSs, with a prominent position for Mn doped Ge. In this paper, we will first review the current theoretical understanding on the ferromagnetism in MnxGe1−x DMS, pointing out the possible physics models underlying the complicated ferromagnetic behavior of MnxGe1−x. Then we carry out detailed analysis of MnxGe1−x thin films and nanostructures grown by molecular beam epitaxy. We show that with zero and one dimension quantum structures, superior magnetic properties of MnxGe1−x compared with bulk films can be obtained. More importantly, with MnxGe1−x nanostructures, such as quantum dots, we demonstrate a field controlled ferromagnetism up to 100 K. Finally we provide a prospective of the future development of ferromagnetic field effect transistors and magnetic tunneling junctions/memories using dilute and metallic MnxGe1−x dots, respectively. We also point out the bottleneck problems in these fields and rendering possible solutions to realize practical spintronic devices.

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“…In these materials, high magnetic impurity concentrations are needed due to the lack of long-range interaction among magnetic spins. However, there have been only limited reports on the carrier mediated effect in the wide band gap materials at room temperature (Nepal et al, 2009, Kanki et al, 2006, Philip et al, 2006. Though considerable amount of work has been done on III-V and II-VI DMSs , Chiba et al, 2006a, the lack of high T c and the difficulty in achieving electric field modulated ferromagnetism (carrier mediated ferromagnetism) at or above room temperature deters them from being considered for semiconductor integration.…”

Section: Introductionmentioning

confidence: 99%

“…With the manipulation of carrier spins, a new generation of nonvolatile (green) computing systems could be eventually developed for many low-powerdissipation applications in all fields, including sensor network, health monitoring, information, sustainable wireless system, etc. Since Datta and Das (Datta and Das, 1990) first introduced the concept of spin FETs in 1990, enormous efforts were dedicated to creating a device wherein the carrier transport is modulated by electrostatic control of carrier spins (Philip et al, 2006, Appelbaum and Monsma, 2007, Chiba et al, 2006a, Nazmul et al, 2004, Nepal et al, 2009, Koo et al, 2009, Chiba et al, 2008, Boukari et al, 2002. To understand and exploit this controllability, several theoretical models were proposed to explain the ferromagnetic coupling in DMS on a microscopic scale (also elaborated in the theoretical section): the Zener Kinetic-exchange (Jungwirth et al, 2006), double-exchange , the RKKY interaction (Matsukura et al, 1998, Yagi et al, 2001).…”

Section: Introductionmentioning

confidence: 99%