Experimental probing of exchange interactions between localized spins in the dilute magnetic insulator (Ga,Mn)N

Abstract: The sign, magnitude, and range of the exchange couplings between pairs of Mn ions is determined for (Ga,Mn)N and (Ga,Mn)N:Si with x 3%. The samples have been grown by metalorganic vapor phase epitaxy and characterized by secondary-ion mass spectroscopy; high-resolution transmission electron microscopy with capabilities allowing for chemical analysis, including the annular dark-field mode and electron energy loss spectroscopy; high-resolution and synchrotron x-ray diffraction; synchrotron extended x-ray absorpt… Show more

“…These higher resistances are only partially due to the reduced size of the mesa. Actually, in an ideal case, the insulating (Ga,Mn)N middle layer [4] is expected to block the current through the whole stack, and only a tunneling current weakly dependent on the mesa size should be observed. In contrast, from all tested structures only the smaller size mesas exhibit a noticeable increased resistance and nonlinear I-V characteristics.…”

“…The importance of GaN-based compounds and heterostructures stems from the growing significance of wide band-gap materials in conventional electronics, particularly in opto-and high power electronics. The established a strong mid-gap Fermi-level pinning and a lack of a depletion layer, in combination with its insulating character due to a strong electron trapping by mid-gap Mn 2+ /Mn 3+ level [4,5] and a sizable dielectric strength of 5 MV/cm [6], point at (Ga,Mn)N as insulating buffer material for applications in (high power) nitride devices and make it an ideal building block for spin harnessing structures like spin filters [7] and resonant tunneling devices [8]. Besides these technologically relevant concepts, the spin imbalance in these systems may allow probing spin-orbit coupling, quantum Hall effects, and pairing in unconventional superconductors [9].…”

Two-Probe Measurements of Electron Transport in GaN:Si/(Ga,Mn)N/GaN:Si Spin Filter Structures

“…These higher resistances are only partially due to the reduced size of the mesa. Actually, in an ideal case, the insulating (Ga,Mn)N middle layer [4] is expected to block the current through the whole stack, and only a tunneling current weakly dependent on the mesa size should be observed. In contrast, from all tested structures only the smaller size mesas exhibit a noticeable increased resistance and nonlinear I-V characteristics.…”

“…The importance of GaN-based compounds and heterostructures stems from the growing significance of wide band-gap materials in conventional electronics, particularly in opto-and high power electronics. The established a strong mid-gap Fermi-level pinning and a lack of a depletion layer, in combination with its insulating character due to a strong electron trapping by mid-gap Mn 2+ /Mn 3+ level [4,5] and a sizable dielectric strength of 5 MV/cm [6], point at (Ga,Mn)N as insulating buffer material for applications in (high power) nitride devices and make it an ideal building block for spin harnessing structures like spin filters [7] and resonant tunneling devices [8]. Besides these technologically relevant concepts, the spin imbalance in these systems may allow probing spin-orbit coupling, quantum Hall effects, and pairing in unconventional superconductors [9].…”

Two-Probe Measurements of Electron Transport in GaN:Si/(Ga,Mn)N/GaN:Si Spin Filter Structures

“…Dilute magnetic insulators constitute an emerging class of magnetic semiconductors in which rather than the p-d Zener mechanism [1], ferromagnetic superexchange accounts for the coupling between diluted transition metal (TM) spins [2]. Due to its compatibility with IIInitrides that have reached the status of the most important semiconductors next to Si, particularly attractive is Ga 1−x Mn x N, in which there are no itinerant holes but nevertheless ferromagnetic spin-spin interactions are observed [2].…”

“…Due to its compatibility with IIInitrides that have reached the status of the most important semiconductors next to Si, particularly attractive is Ga 1−x Mn x N, in which there are no itinerant holes but nevertheless ferromagnetic spin-spin interactions are observed [2].…”

“…A high degree of crystallinity, a random distribution of the Mn ions, and a weak degree of compensation by residual donors were checked in these samples by a range of electron microscopy, synchrotron radiation, ion beam, optical, and magnetic resonance techniques [2,3,5].…”

Theory of ferromagnetism driven by superexchange in dilute magnetic semi-conductors

Semiconductors