Native point defects and their implications for the Dirac point gap at MnBi2Te4(0001)

Abstract: We study the surface crystalline and electronic structures of the antiferromagnetic topological insulator MnBi2Te4 using scanning tunneling microscopy/spectroscopy (STM/S), micro(μ)-laser angle-resolved photoemission spectroscopy (ARPES), and density functional theory calculations. Our STM images reveal native point defects at the surface that we identify as BiTe antisites and MnBi substitutions. Bulk X-ray diffraction further evidences the presence of the Mn-Bi intermixing. Overall, our characterizations sugg… Show more

“…The change in the effective magnetic moment can be developed, for instance, due to the substitution defects like Mn/Bi or Mn/Te [46], when the magnetic Mn atoms are replaced by nonmagnetic ones. On the other hand, Mn atoms on the Te atomic sites have opposite magnetic moment orientation that also leads to a decrease of total exchange field acting on TSSs.…”

“…The resulting shift of the TSSs localization towards the second lower-lying SL, which is characterized by the opposite orientation of the Mn magnetic moments, can lead to compensation of the effective out-of-plane magnetic moment in the TSSs localization region and the corresponding shrinking of the Dirac gap. Similarly, a change in the Dirac gap size can occur due to the presence and accumulation of various surface defects of different concentrations [36,39,46], including possible adsorption of residual gas molecules, which can cause the changes in the TSSs localization resulting in modulation of the energy gap at the DP [36,39].…”

“…The calculation results will be analyzed in comparison with the experimental dispersions measured by ARPES. The experimental basis for such variation of calculation parameters can be: (i) surface relaxation processes leading to a change in the SvdW interval [38], (ii) the formation of Mn/Bi type substitution defects, which reduce the exchange field in the region of localization of the TSSs [46], and (iii) the formation of various types of defects in the near-surface region that may change the surface potential gradient, which can be taken into account by artificial variation of the SOC strength for the surface atoms [36,39]. At the same time, such a change in the parameters of the theoretical model can also include the situation of changing the composition of the sample surface by replacing some of the atoms in the near-surface layer with atoms possessing a lower atomic SOC, which may be important in the formation of synthetic layered topological structures.…”

Factors influencing the energy gap in topological states of antiferromagnetic MnBi$_2$Te$_4$

“…The change in the effective magnetic moment can be developed, for instance, due to the substitution defects like Mn/Bi or Mn/Te [46], when the magnetic Mn atoms are replaced by nonmagnetic ones. On the other hand, Mn atoms on the Te atomic sites have opposite magnetic moment orientation that also leads to a decrease of total exchange field acting on TSSs.…”

“…The resulting shift of the TSSs localization towards the second lower-lying SL, which is characterized by the opposite orientation of the Mn magnetic moments, can lead to compensation of the effective out-of-plane magnetic moment in the TSSs localization region and the corresponding shrinking of the Dirac gap. Similarly, a change in the Dirac gap size can occur due to the presence and accumulation of various surface defects of different concentrations [36,39,46], including possible adsorption of residual gas molecules, which can cause the changes in the TSSs localization resulting in modulation of the energy gap at the DP [36,39].…”

“…The calculation results will be analyzed in comparison with the experimental dispersions measured by ARPES. The experimental basis for such variation of calculation parameters can be: (i) surface relaxation processes leading to a change in the SvdW interval [38], (ii) the formation of Mn/Bi type substitution defects, which reduce the exchange field in the region of localization of the TSSs [46], and (iii) the formation of various types of defects in the near-surface region that may change the surface potential gradient, which can be taken into account by artificial variation of the SOC strength for the surface atoms [36,39]. At the same time, such a change in the parameters of the theoretical model can also include the situation of changing the composition of the sample surface by replacing some of the atoms in the near-surface layer with atoms possessing a lower atomic SOC, which may be important in the formation of synthetic layered topological structures.…”

Factors influencing the energy gap in topological states of antiferromagnetic MnBi$_2$Te$_4$

“…In contrast, the TSS electrons on the 1-BT termination are localized to the top BT layer and spatially separate from the magnetic MBT layer, leading to a gapless Dirac point. Gap opening in the MnBi 2 n Te 3 n +1 compound family has been highly controversial. ,,,,,,,,,,,− Specifically on MnBi 6 Te 10 , a 60 meV gap was reported in the AFM phase in contrast to the results from all other ARPES studies on MnBi 6 Te 10 ,,, including ours. However, this gap persists well above the magnetic ordering temperature and is likely due to extrinsic reasons such as local impurities.…”

Delicate Ferromagnetism in MnBi₆Te₁₀

“…To address the discrepancy between experiment and theory, several candidate mechanisms based on either surface magnetic reconstruction, surface structural relaxation, or surface-bulk band hybridization have been proposed [15,18,20,22,[28][29][30][31][32][33][34], among which the surface magnetic reconstruction is most extensively discussed. The ground state of bulk materials has the A-type anti-ferromagnetic configuration [intralayer ferromagnetic (FM) and interlayer anti-ferromagnetic (AFM)] for n = 0, 1, 2 and FM configuration for n ≥ 3 due to the intensely weakening of the interlayer AFM supersuperexchange coupling [35][36][37].…”

Momentum-inversion symmetry breaking on the Fermi surface of magnetic topological insulators