Room‐Temperature Ferromagnetism in MoTe₂ by Post‐Growth Incorporation of Vanadium Impurities

Abstract: potentially to exploit them in spintronics applications. Such potential applications of magnetic vdW materials have recently sparked considerable interest in investigating magnetism of bulk ferromagnetic materials thinned to a single layer [1][2][3][4] or the emergence of ferromagnetism of paramagnetic bulk materials at the monolayer limit. [5,6] In addition, defect-and dopant-induced ferromagnetism has been predicted theoretically. [7][8][9][10][11][12] Recent experimental results suggest that 1T-2H phase bou… Show more

“…The magnetic properties of pristine and V-doped WS 2 monolayer samples were measured by a vibrating sample magnetometer. To exclude unwanted effects on the magnetization versus magnetic field (M-H) loops that can arise from the SiO 2 substrate and the double-sided carbon tape used to hold the sample (see Figure S8, Supporting Information) and from subtracting diamagnetic backgrounds (see Figure S9, Supporting Information), [33,34] Figure 2e-h presents smoothed as-measured M-H loops at 300 K, and we deduced the saturation magnetization (M S ) and coercive field (H C ) directly from these loops. The pristine WS 2 sample exhibits a weak ferromagnetic signal, which we tentatively ascribe to undercoordinated sulfur atoms at crystallographic defects (e.g., edges), [35] on a diamagnetic background.…”

“…The ferromagnetism observed in V-doped samples is too strong to originate from edge effects, and its dependence on vanadium concentration suggests an origin in local magnetic moments associated with unpaired electrons in vanadium d orbitals. [16,18,33] The 2 at% WS 2 sample shows large, clear hysteresis loops at all temperatures from which M S and H C (Figure 2i) are extracted and plotted as a function of temperature (the M-H loops are close to square when rotated to account for the diamagnetic background). We performed magnetic measurements on three V:WS 2 samples for each concentration and obtained reproducible results ( Figure S10, Supporting Information).…”

Monolayer Vanadium‐Doped Tungsten Disulfide: A Room‐Temperature Dilute Magnetic Semiconductor

“…The magnetic properties of pristine and V-doped WS 2 monolayer samples were measured by a vibrating sample magnetometer. To exclude unwanted effects on the magnetization versus magnetic field (M-H) loops that can arise from the SiO 2 substrate and the double-sided carbon tape used to hold the sample (see Figure S8, Supporting Information) and from subtracting diamagnetic backgrounds (see Figure S9, Supporting Information), [33,34] Figure 2e-h presents smoothed as-measured M-H loops at 300 K, and we deduced the saturation magnetization (M S ) and coercive field (H C ) directly from these loops. The pristine WS 2 sample exhibits a weak ferromagnetic signal, which we tentatively ascribe to undercoordinated sulfur atoms at crystallographic defects (e.g., edges), [35] on a diamagnetic background.…”

“…The ferromagnetism observed in V-doped samples is too strong to originate from edge effects, and its dependence on vanadium concentration suggests an origin in local magnetic moments associated with unpaired electrons in vanadium d orbitals. [16,18,33] The 2 at% WS 2 sample shows large, clear hysteresis loops at all temperatures from which M S and H C (Figure 2i) are extracted and plotted as a function of temperature (the M-H loops are close to square when rotated to account for the diamagnetic background). We performed magnetic measurements on three V:WS 2 samples for each concentration and obtained reproducible results ( Figure S10, Supporting Information).…”

Monolayer Vanadium‐Doped Tungsten Disulfide: A Room‐Temperature Dilute Magnetic Semiconductor

“…Although being constrained by solubility and chemical stability, transition metal elements can be doped to some extent into monolayer TMDs, but ferromagnetism was not demonstrated [17][18][19] . Nevertheless, enhanced doping concentration of 2% Mn in Mn: MoS 2 monolayers grown on a graphene substrate 17 and 1% rhenium (Re) in Re:MoS 2 monolayer exhibited suppression of defect-bound emission at low temperatures, demonstrating the feasibility of realizing in situ doping of TMD monolayers 20,21 . Employing a direct vapor-phase method, ferromagnetism was reported for Fe:SnS 2 monolayer with a T C of 31 K and a saturation magnetization of 3.5 emu g −1 .…”

“…However, in this approach, mechanical exfoliation is required after growing bulk crystals, which is not scalable. A recent study shows post-growth incorporation of V into MoTe 2 monolayer with a small saturation magnetization of 0.6 µemu cm −2 , giving rise to room-temperature ferromagnetism, but only in the form of small, randomly distributed clusters that are not uniform 21 . Another technique is based on ion implantation and the idea of co-doping, giving rise to very high saturation magnetization values of 60.62 emu g −1 , but ferromagnetism is limited to a T C around 10 K (ref.…”

Enabling room temperature ferromagnetism in monolayer MoS2 via in situ iron-doping

“…A few years later, scientists began studying the effects of depositing magnetic impurities into non-magnetic 2D semiconductors during MBE growth [71,82,83]. There has been many theoretical predictions about magnetic doping of Mn, Cr, and V into TMDCs such as MoS 2 [84], which is a motivating factor for attempting these studies.…”

Molecular Beam Epitaxy and High-Pressure Studies of van der Waals Magnets