GaAs:Mn Nanowires Grown by Molecular Beam Epitaxy of (Ga,Mn)As at MnAs Segregation Conditions

Sadowski, J.; Dłuźewski, P.; Kret, S.; Janik, E.; Łusakowska, E.; Kanski, J.; Presz, A.; Terki, F.; Charar, S.; Tang, Duyu

doi:10.1021/nl071190f

Cited by 52 publications

(66 citation statements)

References 31 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…Although the growth of monocrystalline GaMnAs layers using a high Mn flux is impossible at high temperatures, 11 1-D nanowire (NW) growth at a Mn/Ga flux ratio of several percent is possible, which has been demonstrated in several studies. [11][12][13][14] Although some studies have shown room temperature ferromagnetism, 14,15 the origin and mechanism of the reported magnetization are not clear.…”

Section: Introductionmentioning

confidence: 99%

“…[11][12][13][14] Although some studies have shown room temperature ferromagnetism, 14,15 the origin and mechanism of the reported magnetization are not clear. For example, the formation of ferromagnetic precipitates or clusters such as MnAs should be considered as a possible source of magnetism.…”

Section: Introductionmentioning

confidence: 99%

“…For example, the formation of ferromagnetic precipitates or clusters such as MnAs should be considered as a possible source of magnetism. 11,16,17 Recently, core-shell structured NWs consisting of GaAs/GaMnAs, 18 GaAs/MnAs, 19,20 and InGaAs/GaMnAs 21 have been considered as well. Some of these studies showed that low temperature grown GaMnAs shells can contain high Mn concentrations up to $5% and have ferromagnetic phase transitions above 20 K. 18,21 We have demonstrated previously 11,13 that it is possible to grow GaMnAs NWs by MBE at low temperatures (300-350 C) and if the growth temperature is slightly too high, the formation of MnAs nanoclusters occurs on the surface.…”

Section: Introductionmentioning

confidence: 99%

“…11,16,17 Recently, core-shell structured NWs consisting of GaAs/GaMnAs, 18 GaAs/MnAs, 19,20 and InGaAs/GaMnAs 21 have been considered as well. Some of these studies showed that low temperature grown GaMnAs shells can contain high Mn concentrations up to $5% and have ferromagnetic phase transitions above 20 K. 18,21 We have demonstrated previously 11,13 that it is possible to grow GaMnAs NWs by MBE at low temperatures (300-350 C) and if the growth temperature is slightly too high, the formation of MnAs nanoclusters occurs on the surface. However, due to high disorder in terms of NW orientation, crystallographic defects, and morphology, other growth regimes of Mn-doped GaAs NWs have been exploited: (i) Ga catalyzed NWs grown at high temperature on Si(100), 13 (ii) Ga catalyzed NWs grown at high temperature on Si(111), 22 and (iii) low-temperature grown GaMnAs shells on high-temperature grown Au-catalyzed GaAs NWs on GaAs(111)B.…”

Section: Introductionmentioning

confidence: 99%

See 3 more Smart Citations

Direct observation of doping incorporation pathways in self-catalytic GaMnAs nanowires

Kasama

Thuvander

Siusys

et al. 2015

Journal of Applied Physics

View full text Add to dashboard Cite

Publication date: 2015 Document VersionPublisher's PDF, also known as Version of record Link back to DTU Orbit Citation (APA): Kasama, T., Thuvander, M., Siusys, A., Gontard, L. C., Kovács, A., Yazdi, S., ... Sadowski, J. (2015) Doping mechanisms of Mn in GaAs nanowires (NWs) that have been grown self-catalytically at 600 C by molecular beam epitaxy (MBE) are investigated using advanced electron microscopy techniques and atom probe tomography. Mn is found to be incorporated primarily in the form of non-magnetic tetragonal Ga 0.82 Mn 0.18 nanocrystals in Ga catalyst droplets at the ends of the NWs, while trace amounts of Mn (22 6 4 at. ppm) are also distributed randomly in the NW bodies without forming clusters or precipitates. The nanocrystals are likely to form after switching off the reaction in the MBE chamber, since they are partially embedded in neck regions of the NWs. The Ga 0.82 Mn 0.18 nanocrystals and the low Mn concentration in the NW bodies are insufficient to induce a ferromagnetic phase transition, suggesting that it is difficult to have high Mn contents in GaAs even in 1-D NW growth via the vapor-liquid-solid process. V C 2015 AIP Publishing LLC.

show abstract

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 2 more Smart Citations

Direct observation of doping incorporation pathways in self-catalytic GaMnAs nanowires

Kasama

Thuvander

Siusys

et al. 2015

Journal of Applied Physics

View full text Add to dashboard Cite

show abstract

“…We note that in previous studies the growth of GaMnAs nanowires under typical NW, i.e., high temperature conditions, has been reported. [28][29][30] Sadowski et al 29 showed that the growth of GaMnAs at MnAs segregation conditions led to the formation of MnAs nanocluster acting as catalyst for the NW growth. The obtained NWs were strongly tapered with side branches.…”

mentioning

confidence: 99%

Ferromagnetic GaAs/GaMnAs Core−Shell Nanowires Grown by Molecular Beam Epitaxy

et al. 2009

View full text Add to dashboard Cite

GaAs/GaMnAs core-shell nanowires were grown by molecular beam epitaxy. The core GaAs nanowires were synthesized under typical nanowire growth conditions using gold as catalyst. For the GaMnAs shell the temperature was drastically reduced to achieve low-temperature growth conditions known to be crucial for high-quality GaMnAs. The GaMnAs shell grows epitaxially on the side facets of the core GaAs nanowires. A ferromagnetic transition temperature of 20 K is obtained. Magnetic anisotropy studies indicate a magnetic easy axis parallel to the nanowire axis.

show abstract

Escalating Ferromagnetic Order via Se‐Vacancies Near Vanadium in WSe₂ Monolayers

et al. 2022

View full text Add to dashboard Cite

as core materials for future spintronics given their potential for high Curie temperature (T C ) and efficient field-tunable magnetic properties. [1][2][3] Despite half-century-long research efforts, the following three primary issues remain unsolved: i) the uncertain origin of ferromagnetism, called phantom ferromagnetism, owing to a lack of structural analysis of nanodefects; [4,5] ii) solubility limit to only a few percent without forming aggregation; [6] and iii) activation of short-range antiferromagnetic transitions in the high-dopingconcentration regime, [7] which limits the improvement of the magnetic moment and T C .The recent emergence of magnetic order in 2D van der Waals layered materials, which is enabled by strong magnetic anisotropy, [8] has stimulated interest in 2D-DMSs owing to their exotic spindependent physical properties, including long spin-relaxation time, light-controlled magnetism, [9] and spin-valley locking, inherent to their atomically thin nature. [10][11][12] In particular, transition metal dichalcogenide (TMD) semiconductors with magnetic dopants synthesized via chemical vapor deposition (CVD) offer room-temperature T C and gate-tunable magnetism. [13][14][15] Although vanadium dopants in WSe 2 and WS 2 semiconductors have been successfully distributed randomly without aggregation to a relatively high doping concentration of approximately 10%, their saturation magnetization is still limited to approximately 10 −5 emu cm −2 , thus making further analysis and applications difficult. [14,15] While magnetism has been proposed for inducing various defects such as vacancies, [16] anti-sites, [17] and grain boundaries [18] in III-V, oxides, and nitride DMSs, the underlying mechanism of magnetism is little known mainly due to the lack of structural analysis. On the contrary, because of facile monolayer growth, a variety of defects, including transition metal and chalcogen vacancies in 2D-TMDs, can be precisely analyzed using state-of-the-art scanning transmission electron microscopy (STEM) with atomic elemental mapping. [19] This affords the possibility of elucidating the origins of magnetism from defects and further enhancing magnetic order by tailoring intrinsic defects and impurities in 2D-TMD semiconductors. Here, we present a comprehensive atomic analysis of Se-vacancy defects Magnetic order has been proposed to arise from a variety of defects, including vacancies, antisites, and grain boundaries, which are relevant in numerous electronics and spintronics applications. Nevertheless, its magnetism remains controversial due to the lack of structural analysis. The escalation of ferromagnetism in vanadium-doped WSe 2 monolayer is herein demonstrated by tailoring complex configurations of Se vacancies (Se Vac ) via post heat-treatment. Structural analysis of atomic defects is systematically performed using transmission electron microscopy (TEM), enabled by the monolayer nature. Temperature-dependent magnetoresistance hysteresis ensures enhanced magnetic order after high-temperature heat-tre...

show abstract

GaAs:Mn Nanowires Grown by Molecular Beam Epitaxy of (Ga,Mn)As at MnAs Segregation Conditions

Cited by 52 publications

References 31 publications

Direct observation of doping incorporation pathways in self-catalytic GaMnAs nanowires

Direct observation of doping incorporation pathways in self-catalytic GaMnAs nanowires

Ferromagnetic GaAs/GaMnAs Core−Shell Nanowires Grown by Molecular Beam Epitaxy

Escalating Ferromagnetic Order via Se‐Vacancies Near Vanadium in WSe₂ Monolayers

Contact Info

Product

Resources

About

GaAs:Mn Nanowires Grown by Molecular Beam Epitaxy of (Ga,Mn)As at MnAs Segregation Conditions

Cited by 52 publications

References 31 publications

Direct observation of doping incorporation pathways in self-catalytic GaMnAs nanowires

Direct observation of doping incorporation pathways in self-catalytic GaMnAs nanowires

Ferromagnetic GaAs/GaMnAs Core−Shell Nanowires Grown by Molecular Beam Epitaxy

Escalating Ferromagnetic Order via Se‐Vacancies Near Vanadium in WSe2 Monolayers

Contact Info

Product

Resources

About

Escalating Ferromagnetic Order via Se‐Vacancies Near Vanadium in WSe₂ Monolayers