Abstract
Iron-chalcogenide superconductors have emerged as a promising Majorana platform for topological quantum computation. By combining topological band and superconductivity in a single material, they provide significant advantage to realize isolated Majorana zero modes. However, iron-chalcogenide superconductors, especially Fe(Te,Se), suffer from strong inhomogeneity which may hamper their practical application. In addition, some iron-pnictide superconductors have been demonstrated to have topological surface states, yet no Majorana zero mode has been observed inside their vortices, raising a question of universality about this new Majorana platform. In this work, through angle-resolved photoemission spectroscopy and scanning tunneling microscopy/spectroscopy measurement, we identify Dirac surface states and Majorana zero modes, respectively, for the first time in an iron-pnictide superconductor, CaKFe4As4. More strikingly, the multiple vortex bound states with integer-quantization sequences can be accurately reproduced by our model calculation, firmly establishing Majorana nature of the zero mode.
Subject terms: Electronic properties and materials, Superconducting properties and materials, Topological insulators
Iron-pnictide superconductors share similar topological band structure with iron-chalcogenide superconductors, but no Majorana modes have been observed in the former. Here, the authors observe both the superconducting Dirac surface states and Majorana zero modes inside its vortex cores in CaKFe4As4.
Introduction
The iron-chalcogenide superconductor Fe(Te,Se) and its analogous compounds have been found to be able to host isolated Majorana zero modes (MZMs), due to the unique combination of the large superconducting (SC) gap, small Fermi energy, and nontrivial band topology in a single material1–8. However, the intrinsic inhomogeneity in Fe(Te,Se) complicates the occurrence of MZMs, causing the topological trivial region in the material9–11, which brings obstacles for further studies of MZMs and explorations of topological quantum computing. In addition, another family of iron-based superconductors (FeSCs), iron pnictides (Fe-As), which usually have higher values of SC transition temperature (Tc) and more abundant crystal structure forms, has long been omitted from the studies of MZMs. While several Fe-As superconductors are predicted to have topological nontrivial Dirac surface states in the previous work, no experimental evidence of MZMs has yet been found12. It inspires us to explore a new Majorana-hosting material in the iron pnictide family, which might reveal new physical phenomena and also improve the potential utilization of MZMs.
In this work, we perform a comprehensive theoretical and experimental research on a new type Fe-As superconductor CaKFe4As4 that has a topological band inversion caused by the bilayer band folding. The crystal structure of CaKFe4As4 can be viewed as two different 122-type Fe-As superconductors CaFe2As2 and KFe2As2 inserted into one another (Fig. 1a)13, where this special structure not only induces high-Tc superconductivity (Tc = 35 K) by self-doping effect14 but also breaks the glide-mirror symmetry along the c-axis (Fig. 1a inset). Applying angle-resolved photoemission spectroscopy (ARPES) and the density functional theory (DFT) plus dynamical mean field theory (DMFT) calculation, our investigation indicates that the glide-mirror symmetry breaking together with electron correlations create a topological band inversion in CaKFe4As4. Further measurements confirm the existence of topological Dirac band and its SC state. In addition, by using scanning tunneling microscopy/spectroscopy (STM/S), we observe MZMs within integer-quantization sequence of Caroli–de Gennes–Matricon bound states (CBSs) inside a SC vortex core, which is identified as a topological hallmark of MZMs in the previous studies on Fe(Te,Se)2,9. More remarkably, the energy positions and spatial line profiles of multiple bound states can be accurately reproduced by our simple theoretical simulation with all experimental parameters. Our findings demonstrate that CaKFe4As4, with the homogeneous bulk and higher Tc, is a new material platform to host and manipulate MZMs.
Result
Topological band inversion in the bulk
The DFT plus DMFT calculations (Figs. 1b–d and 2a) confirm that a topological band inversion can be induced by the glide-mirror symmetry breaking. The glide-mirror symmetry, as seen in CaFe2As2, is broken due to the difference between Ca and K atoms on the opposite sides of Fe-As layer in CaKFe4As4 (Fig. 1a). Consequently, the Brillouin zone folds along Γ–Z, opening a large hybridization gap (~0.5 eV) at the crossing points of the folded 3dz2/4pz band, and pushes its lower branch below the dxz/yz band at Γ, causing a topological band inversion (Supplementary Fig. 1d–f). Finally, the spin–orbital coupling (SOC) opens a topological gap at the band crossing point between 3dz2/4pz and 3dxz/yz bands. We note that our DMFT calculation (Fig. 1b–d) incorporates a mass renormalization of ~5 compared to the simple DFT calculation15, indicating relatively strong correlations, which can reduce the Fermi energy and the coherence length (ξ0) in this material (details of our calculations are described in Supplementary Materials).
Experimentally, we first performed synchrotron-based ARPES measurements (hʋ = 21–45 eV, Texp = 18 K). Figure 1e shows the comparison between the measured Fermi surfaces (FSs) at photon energy of 35 eV (left) and the extracted FSs from DFT+DMFT calculation at the Z/A point (right). Self-hole-doping effect is reflected by the large areas of hole-like FSs16. Band dispersions near high-symmetry points were also measured (Fig. 1f–h), with a comparison to the DFT+DMFT results (Fig. 1j), showing a fairly good agreement between the two results. Importantly, the innermost hole-like band around Γ has a strong kz dispersion (Fig. 1f, g), so that the hole-like FS pocket around Z sinks well below the Fermi level (EF) at Γ, which is the consequence of the band inversion between 3dz2/4pz and 3dxz bands. In fact, a clear band dispersion along Γ–Z was observed by our ARPES (Fig. 1i), fully consistent with our band calculations (Fig. 1d).
Evidence of SC Dirac surface states
We next demonstrate the direct observation of the Dirac surface band around Γ (kx = ky = 0). The calculation of the surface state in CaKFe4As4 (Fig. 2a) shows that the Dirac-cone-type band structure exists inside the SOC gap with its Dirac point above EF, which may obstruct the ARPES technique in observing the Dirac-cone-like feature of the surface state. In order to identify the possible surface states, we implemented the synchrotron-based ARPES measurement on the samples with the in situ potassium (K) surface adsorption that has been proven to induce the effective electron-doping effect on the 122-type FeSC17. The experimental photon energy was set to 76 eV, which should be beneficial to detect the electron states of the sample surface when the mean free path of photon-emitted electrons should be small18,19. In addition, the band structure (Fig. 2b) in undoped CaKFe4As4 indicates that the selected kz is around the Γ point, while the 3dz2/4pz (tracked by the blue line) is far below EF. Since there should be a large energy separation between the bulk bands and the surface state near the Γ point from the DFT+DMFT calculation, it creates the condition to clearly measure the surface state. Inspiringly, we observed an extra band distinguished from the 3dz2/4pz band, both in the ARPES data (Fig. 2b) and the corresponding second-derivative plot (Fig. 2d), which displays the linear-like dispersion around EF and cannot be assigned to any bulk band as predicted by our calculation (Fig. 1c, d), suggesting that the newly observed band is the surface state.
To verify the existence of topological surface state, we utilized the potassium (K)-surface adsorption on the sample for 40 s. Note that the surface band dispersion is clearer in the K-surface dosing sample (Fig. 2c) than the undoped sample and displays a good linearity near EF. Moreover, an apparent Dirac-cone-like band can be clearly identified by the second-derivative data (Fig. 2e) and the MDC plot (Fig. 2f) of K-doped CaKFe4As4. We extracted the surface band dispersion under each doping level by a simple Lorentzian fit20 (the colored dashed lines in Fig. 2d, e). The parameters of the Dirac-cone-like bands are estimated by linearly matching on the tracked dispersions mentioned above (the solid lines in Fig. 2d, e), which suggests the energy of the Dirac point (ED) is ~20 meV and the Fermi momentum (kF) is ~0.025 π/a in undoped CaKFe4As4 (red solid line in Fig. 2d). Figure 2g displays the changing of ED with the K-surface dosing. The systematic shifting of ED implies the effective doping effect by the in situ K-surface adsorption. The result of the K-doped CaKFe4As4 indicates that the newly observed band in the undoped one (Fig. 2b) is the Dirac surface state, which may induce the topological vortex with MZM.
Then we used the high-resolution laser ARPES (hʋ ~ 7 eV) to measure the surface band in the SC state. There is a striking contrast between the sharp spectra in the SC state (Fig. 2h, i) and the broad spectra in the normal state (Supplementary Fig. 7a, b), which is similar to the case in Fe(Te,Se)21. From the two Fermi crossings (Figs. 2j, k, k1, k2 in Fig. 2h) near Γ, we can extract the values of two SC gap (5.9 meV for k1 and 7.5 meV for k2). Since the gap values in most FeSCs, including this material, roughly follow the Δ0cos(kx)cos(ky) formula20, when measured by ARPES, the SC gap at k1 (closer to Γ) is expected to be larger than the one at k2 if both gaps come from the bulk bands. However, our observation shows that the SC gap in the vicinity of Γ has a smaller size (5.9 < 7.5 meV), which also supports that this SC gap come from the surface band since the smaller SC gap on the topological surface state is likely a proximity SC gap induced by the bulk superconductivity, just as the case in Fe(Te,Se)1,2. Combining the band calculation, the band structure data of K-surface dosing and the SC gap measurements, our results strongly support that CaKFe4As4 hosts a topological surface state with its Dirac point just slightly above EF.
Characterization of sample surface by STM/S
Encouraged by the promising results from our ARPES measurements and band calculations, we conducted high-resolution (~0.3 meV) STM/S experiments at low temperature (Texp = 0.45 K) to directly search for the signal of MZM inside a vortex core of this superconductor. A typical cleaved surface shows a good atom-resolved topography revealing that the surface is formed by the As lattice22, with either Ca or K atoms or clusters scattered on top of it (Fig. 3a, b). We chose a flat region with few clusters of Ca or K on which the dI/dV spectra are homogenous (Fig. 3c) across a spatial line marked in Fig. 3a. The SC spectra have a main SC gap (Δ) of 5.8 meV, which is likely from the topological surface state with a gap value of 5.9 meV obtained by ARPES, since STM/S is mostly sensitive to the surface. The small bumps at ±3.4 meV are likely coming from the SC gap on the largest hole-like FS since a similar gap value was also observed by ARPES on that FS. The features of SC spectra are similar to the previous results23,24.
MZM within integer-quantized vortex-bound states
By applying a 2-T magnetic field along the c-axis, we clearly observed SC vortices on the surface (Fig. 3d). We focused on one vortex within a 20 × 20 nm2 area and measured dI/dV spectra along the white arrow across the vortex core (Fig. 3e). A robust zero-bias conductance peak (ZBCP) that does not split or shift as it crosses the vortex can be clearly seen in a line-cut intensity plot (Fig. 3f), and a waterfall-like dI/dV spectra plot (Fig. 3g). By utilizing an analytical Majorana wave function derived from Fu–Kane model2,7, the spatial line profile of the ZBCP is well fitted with the parameters of the Dirac surface state as shown in Fig. 3i (Δ = 5.8 meV, EF = 20.9 meV, ξ0 = 6.4 nm), which are highly consistent with our ARPES and STM data.
Besides the zero mode, there are multiple discrete peaks at finite energies inside the vortex core (Fig. 3h). It is natural to recognize these modes as the quantized CBSs when the electronic temperature (Teff ~ 0.69 K) is much smaller than the quantum limit temperature (TQL ~ TcΔ/EF ~ 10 K)25,26. We note that the intensity of CBSs is stronger at the negative energy side, consistent with the scenario that the Dirac point is above EF13. As demonstrated recently9, the CBSs with integer-quantized energy levels, coexisting with a robust MZM, are a hallmark of a Dirac-state-induced vortex-bound states, since the intrinsic π phase carried by the spin of surface Dirac fermions lead to an additional half-integer level shift7,27–30. To check this behavior, we used a multi-Gaussian fit to extract the accurate energy positions of discrete bound states inside the vortex (see Supplementary Fig. 2). We resolved seven discrete levels marked by L0, L±1, L±2, L±3 at the energies of 0, ±1.2, ±2.5, and ±3.6 meV, respectively, as shown in Fig. 4a. We displayed the extracted energies of the vortex-bound states at each spatial position onto the line-cut intensity plot (Fig. 4b) and also did a statistics analysis in a histogram plot (Fig. 4c), showing that the discrete vortex-bound states obey an integer quantization with the approximate form of 0: 1: 2: 3, which are derived from the integer angular momenta of vortex-bound states induced by the intrinsic π phase of Dirac surface states. Remarkably, we used a model calculation with the same parameter set (Δ = 5.8 meV, EF = 20.9 meV, ξ0 = 6.4 nm) to reproduce the level energies very well (Fig. 4d).
Characteristic spatial pattern and model calculation
Due to the high quality of dI/dV data measured in a vortex core, we are able to obtain clear observation of spatial patterns for the first four vortex-bound states, i.e., L0, L−1, L−2, and L−3 (Fig. 4e). We observed that both the MZM (L0) and the first-level CBS (L−1) have a solid-circle pattern with the maximum of intensity at the vortex center, while the other higher energy CBSs (L−2 and L−3) show hollow-ring patterns around the vortex center (more results including CBSs at the positive energy side are displayed in Supplementary Fig. 4). Note that, in an ordinary vortex, only one solid-circle pattern exists, as shown by the theoretical simulation in Supplementary Fig. 4. This phenomenon that both the MZM (L0) and the first-level CBS (L−1) possess the maximum-intensity-at-center spatial pattern simultaneously was demonstrated as a fingerprint of surface Dirac fermion-induced vortex-bound states in a topological vortex9. In order to simulate the spatial patterns in CaKFe4As4, we employed a general and direct numerical calculation7 based on the same set of parameters of the Dirac surface state (Δ = 5.8 meV, EF = 20.9 meV, ξ0 = 6.4 nm) used above. Unlike the simulation in the Fe(Te,Se) case, we reproduced the experimental results with excellent agreement (Fig. 4f, g) without any fine tuning of the gap profile around the vortex, which bodes well with the stoichiometric properties of the CaKFe4As4 bulk component.
We further note that, while MZM always retains a solid-circle pattern, the same kind of pattern for the first-level CBSs can be only retained on one side, with the other side having a hollow-ring pattern31. A positive (negative) Dirac point causes the solid-circle pattern on the negative (positive) side of first-level CBS. Indeed, we observed that the solid-circle pattern appears on the negative (L−1) side in CaKFe4As4, fully consistent with the theoretical simulation based on a Dirac point above EF (Supplementary Fig. 4). Therefore, all the main features of a topological vortex core, including the spatial line profile of MZM, level energies, and spatial patterns of discrete CBSs, can be fully reproduced by simple model calculations based on a same SC Dirac surface state. This establishes in a convincing manner that this high-Tc Fe-As bilayer superconductor, with glide-mirror symmetry breaking15, can host isolated MZMs on its surface, offering a new and more practical platform for exploring the properties of MZMs and manipulating them.
Methods
Materials and measurement
Single crystals of CaKFe4As4 were grown using the self-flux method, and the value of Tc was determined to be 35 K from magnetization and resistivity measurements. Clean surfaces for ARPES measurements were obtained by cleaving samples in situ in an ultrahigh vacuum better than 5 × 10−11 Torr. Synchrotron-based ARPES measurements were performed at the “Dreamline” beamline and BL03U of the Shanghai Synchrotron Radiation Facility with Scienta Omicron DA30L analyzers. The energy resolution of “Dreamline” beamline is ~10–15 meV and that of BL03U is ~30 meV. High-resolution laser ARPES measurements were performed at the Institute for Solid State Physics at the University of Tokyo on an ARPES system with a VG-Scienta HR8000 electron analyzer and a vacuum ultraviolet laser of 6.994 eV, with the energy resolution of ~3 meV. The samples used in STM experiments were cleaved in situ (Tcleave = 77 K) and immediately transferred to an STM head. Experiments were performed in an ultrahigh-vacuum (1 × 10−11 mbar) low-temperature (T ~ 0.45 K) STM system of USM-1300-3He with a vector (9z − 2x − 2y Tesla) magnet. Chemically etched tungsten tips were calibrated on Au (111) surface before measurement. Differential conductance (dI/dV) spectra were acquired by a standard lock-in amplifier at a frequency of 973.0 Hz under the zero-to-peak modulation voltage Vmod = 0.1 mV. The calibration and configurations of the STM system are shown in Supplementary Note 6. The setpoint of equipment of Figs. 3 and 4 is Vs = −5 mV, It = 200 pA, except Fig. 3a where Vs = −25 mV, It = 20 pA.
Supplementary information
Acknowledgements
We thank technical assistance from Y.-B. Huang, S.-Y. Gao, and J.-R. Huang on “Dreamline” synchrotron-based ARPES measurements and D.-W. Shen and Z.-C. Jiang on BL03U synchrotron-based ARPES measurements. This work at IOP is supported by grants from the National Natural Science Foundation of China (11888101, 61888102, 51991340), Chinese Academy of Sciences (XDB28000000, XDB07000000), the Ministry of Science and Technology of China (2016YFA0202300, 2019YFA0308500, and 2018YFA0305800), and Beijing Municipal Science & Technology Commission (No. Z191100007219012). The band calculations used high-performance computing clusters at BNU in Zhuhai and the National Supercomputer Center in Guangzhou, and Z.Y. is supported by NSFC (11674030), the Funds for the Central Universities (310421113), and the National Key Research and Development Program of China (2016YFA0302300). L.F. is supported by US DOE (DE-SC0019275). Laser ARPES work was supported by the JSPS KAKENHI (Grant Nos. JP18H01165, JP19F19030, and JP19H00651). G.-H.C. is supported by Funds for the Central Universities and the National Key Research and Development Program of China (2019FZA3004, 2017YFA0303002, and 2016YFA0300202).
Author contributions
H.D. and H.-J.G. designed the experiments. W.L. performed synchrotron-based ARPES measurement; W.L. and P.Z. performed the laser ARPES measurement with assistance from T.K. and S.S.; L.C. and W.L. carried out STM measurements with assistance from S.Z., L.K., H.C., G.L., F.Y., and S.D.; G.W. and Z.Y. performed the DFT+DMFT calculations of surface and bulk band structure; M.P. and L.F. provided theoretical model and simulations of STS results; Y.-B.L. and G.-H.C. synthesized and characterized CaKFe4As4 single crystals; W.L., L.C., and H.D. analyzed experimental data with inputs from all other authors. W.L. and L.C. plotted figures with inputs from all other authors. All the authors participated in writing the manuscript. H.D. and H.-J.G. supervised the project.
Data availability
The datasets that support the findings of this study are available from the corresponding author upon reasonable request.
Competing interests
The authors declare no competing interests.
Footnotes
Peer review information Nature Communications thanks the anonymous reviewer(s) for their contribution to the peer review of this work. Peer reviewer reports are available.
Publisher’s note Springer Nature remains neutral with regard to jurisdictional claims in published maps and institutional affiliations.
These authors contributed equally: Wenyao Liu, Lu Cao, Shiyu Zhu, Lingyuan Kong.
Contributor Information
Hong-Jun Gao, Email: hjgao@iphy.ac.cn.
Hong Ding, Email: dingh@iphy.ac.cn.
Supplementary information
Supplementary information is available for this paper at 10.1038/s41467-020-19487-1.
References
- 1.Zhang P, et al. Observation of topological superconductivity on the surface of an iron-based superconductor. Science. 2018;360:182–186. doi: 10.1126/science.aan4596. [DOI] [PubMed] [Google Scholar]
- 2.Wang D, et al. Evidence for Majorana bound states in an iron-based superconductor. Science. 2018;362:333–335. doi: 10.1126/science.aao1797. [DOI] [PubMed] [Google Scholar]
- 3.Liu Q, et al. Robust and clean Majorana zero mode in the vortex core of high-temperature superconductor (Li0.84Fe0.16)OHFeSe. Phys. Rev. X. 2018;8:041056. [Google Scholar]
- 4.Read N, et al. Paired states of fermions in two dimensions with breaking of parity and time-reversal symmetries and the fractional quantum Hall effect. Phys. Rev. B. 2000;61:10267–10297. doi: 10.1103/PhysRevB.61.10267. [DOI] [Google Scholar]
- 5.Kitaev AY. Unpaired Majorana fermions in quantum wires. Phys. Uspekhi. 2001;44:131–136. doi: 10.1070/1063-7869/44/10S/S29. [DOI] [Google Scholar]
- 6.Nayak C, et al. Non-Abelian anyons and topological quantum computation. Rev. Mod. Phys. 2008;80:1083–1159. doi: 10.1103/RevModPhys.80.1083. [DOI] [Google Scholar]
- 7.Fu L, Kane CL. Superconducting proximity effect and Majorana fermions at the surface of a topological insulator. Phys. Rev. Lett. 2008;100:096407. doi: 10.1103/PhysRevLett.100.096407. [DOI] [PubMed] [Google Scholar]
- 8.Mourik V, et al. Signatures of Majorana fermions in hybrid superconductor-semiconductor nanowire devices. Science. 2012;336:1003–1007. doi: 10.1126/science.1222360. [DOI] [PubMed] [Google Scholar]
- 9.Kong L, et al. Half-integer level shift of vortex bound states in an iron-based superconductor. Nat. Phys. 2019;15:1181–1187. doi: 10.1038/s41567-019-0630-5. [DOI] [Google Scholar]
- 10.Machida T, et al. Zero-energy vortex bound state in the superconducting topological surface state of Fe(Se,Te) Nat. Mater. 2019;18:811–815. doi: 10.1038/s41563-019-0397-1. [DOI] [PubMed] [Google Scholar]
- 11.He X-B, et al. Nanoscale chemical phase separation in FeTe0.55Se0.45 as seen via scanning tunneling spectroscopy. Phys. Rev. B. 2011;83:220502. doi: 10.1103/PhysRevB.83.220502. [DOI] [Google Scholar]
- 12.Zhang P, et al. Multiple topological states in iron-based superconductors. Nat. Phys. 2019;15:41–47. doi: 10.1038/s41567-018-0280-z. [DOI] [Google Scholar]
- 13.Akira I, et al. New-structure-type Fe-based superconductors: CaAFe4As4 (A = K, Rb, Cs) and SrAFe4As4 (A = Rb, Cs) J. Am. Chem. Soc. 2016;138:3410–3415. doi: 10.1021/jacs.5b12571. [DOI] [PubMed] [Google Scholar]
- 14.Meier WR, et al. Optimization of the crystal growth of the superconductor CaKFe4As4 from Fe-As rich solution in the FeAs-CaFe2As2-KFe2As2 system. Phys. Rev. Mater. 2017;1:013401. doi: 10.1103/PhysRevMaterials.1.013401. [DOI] [Google Scholar]
- 15.Lochner F, et al. Electronic properties, low-energy Hamiltonian and superconducting instabilities in CaKFe4As4. Phys. Rev. B. 2017;96:094521. doi: 10.1103/PhysRevB.96.094521. [DOI] [Google Scholar]
- 16.Canfield PC, et al. FeAs-based superconductivity: a case study of the effects of transition metal doping on BaFe2As2. Annu. Rev. Condens. Matter Phys. 2010;1:27–50. doi: 10.1146/annurev-conmatphys-070909-104041. [DOI] [Google Scholar]
- 17.Kyung WS, et al. Enhanced superconductivity in surface-electron-doped iron pnictide Ba(Fe1.94Co0.06)2As2. Nat. Mater. 2016;15:1233–1236. doi: 10.1038/nmat4728. [DOI] [PubMed] [Google Scholar]
- 18.Yeh, J. J. & Lindau, I. Atomic subshell photoionization cross sections and asymmetry parameters: 1⩽ Z ⩽ 103. Atomic Data Nucl. Data Tables32, 1–155 (1985).
- 19.Seah MP, Dench WA. Quantitative electron spectroscopy of surfaces: a standard data base for electron inelastic mean free paths in solids. Surf. Interf. Anal. 1979;1:2. doi: 10.1002/sia.740010103. [DOI] [Google Scholar]
- 20.Richard P, et al. ARPES measurements of the superconducting gap of Fe-based superconductors and their implications to the pairing mechanism. J. Phys. Condens. Matter. 2015;27:293203. doi: 10.1088/0953-8984/27/29/293203. [DOI] [PubMed] [Google Scholar]
- 21.Miao H, et al. Universal 2Δmax/kBTc scaling decoupled from the electronic coherence in iron-based superconductors. Phys. Rev. B. 2018;98:020502. doi: 10.1103/PhysRevB.98.020502. [DOI] [Google Scholar]
- 22.Gao M, et al. Surface structures of ternary iron arsenides AFe2As2. Phys. Rev. B. 2010;81:193409. doi: 10.1103/PhysRevB.81.193409. [DOI] [Google Scholar]
- 23.Cho K, et al. Nodeless multiband superconductivity in stoichiometric single-crystalline CaKFe4As4. Phys. Rev. B. 2017;95:100502. doi: 10.1103/PhysRevB.95.100502. [DOI] [Google Scholar]
- 24.Fente A, et al. Influence of multiband sign-changing superconductivity on vortex cores and vortex pinning in stoichiometric high-Tc CaKFe4As4. Phys. Rev. B. 2018;97:134501. doi: 10.1103/PhysRevB.97.134501. [DOI] [Google Scholar]
- 25.Hayashi N, et al. Low-lying quasiparticle excitations around a vortex core in quantum limit. Phys. Rev. Lett. 1998;80:2921. doi: 10.1103/PhysRevLett.80.2921. [DOI] [Google Scholar]
- 26.Chen M, et al. Discrete energy levels of Caroli-de Gennes-Martricon states in quantum limit in FeTe0.55Se0.45. Nat. Commun. 2018;9:970. doi: 10.1038/s41467-018-03404-8. [DOI] [PMC free article] [PubMed] [Google Scholar]
- 27.Alicea J. New directions in the pursuit of Majorana fermions in solid state systems. Rep. Prog. Phys. 2012;75:076501. doi: 10.1088/0034-4885/75/7/076501. [DOI] [PubMed] [Google Scholar]
- 28.Caroli C, de Gennes PG, Matricon J. Bound fermion states on a vortex line in a type II superconductor. Phys. Lett. 1964;9:307–309. doi: 10.1016/0031-9163(64)90375-0. [DOI] [Google Scholar]
- 29.Gygi F, Schluter M. Self-consistent electronic structure of a vortex line in a type-II superconductor. Phys. Rev. B. 1990;43:7609. doi: 10.1103/PhysRevB.43.7609. [DOI] [PubMed] [Google Scholar]
- 30.Berthod C. Vorticity and vortex-core states in type-II superconductors. Phys. Rev. B. 2005;71:134513. doi: 10.1103/PhysRevB.71.134513. [DOI] [Google Scholar]
- 31.Takuto K, Hu X. Evolution of density of states and a spin-resolved checkerboard-type pattern associated with the Majorana bound state. Phys. Rev. Lett. 2015;115:177001. doi: 10.1103/PhysRevLett.115.177001. [DOI] [PubMed] [Google Scholar]
- 32.Zhang P, et al. A precise method for visualizing dispersive features in image plots. Rev. Sci. Instrum. 2011;82:043712. doi: 10.1063/1.3585113. [DOI] [PubMed] [Google Scholar]
Associated Data
This section collects any data citations, data availability statements, or supplementary materials included in this article.
Supplementary Materials
Data Availability Statement
The datasets that support the findings of this study are available from the corresponding author upon reasonable request.