Abstract
Most superconductors have an isotropic, single component order parameter and are well described by the standard (BCS) theory for superconductivity. Unconventional, multiple-component superconductors are exceptionally rare and are much less understood. Here, we combine scanning tunneling microscopy and angle-resolved macroscopic transport for studying the candidate chiral superconductor, 4Hb-TaS2. We reveal quasi-periodic one-dimensional modulations in the tunneling conductance accompanied by two-fold symmetric superconducting critical field. The strong modulation of the in-plane critical field, Hc2, points to a nematic, unconventional order parameter. However, the imaged vortex core is isotropic at low temperatures. We suggest a model that reconciles this apparent discrepancy and takes into account previously observed spontaneous time-reversal symmetry breaking at low temperatures. The model describes a competition between a dominating chiral superconducting order parameter and a nematic one. The latter emerges close to the normal phase. Our results strongly support the existence of two-component superconductivity in 4Hb-TaS2 and can provide valuable insights into other systems with coexistent charge order and superconductivity.
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Introduction
Superconductivity in metals and alloys is usually characterized by an isotropic order parameter. This isotropy stems from the short length scales of the charge screening and the electron-phonon interaction. On the other hand, unconventional superconductors have an anisotropic and possibly multiple-components order parameter, transforming non-trivially under the symmetry operation of the underlying crystal1,2,3. In practice, evidence for multi-component superconductivity has been reported in a few compounds, e.g., NbSe24, Bi2Se35,6,7,8,9, and iron-based superconductors10,11. A unique situation emerges in chiral superconductors when the order parameter is a time-reversal-symmetry-breaking linear combination of degenerate representations12. Chiral superconductivity is even more elusive, with possible candidates being UPt313,14,15, UTe216,17,18 and Sr2RuO419. The exact nature of the superconductivity in the latter is still under debate20.
Recently, mounting evidence points out that 4Hb-TaS2 hosts a chiral superconducting ground state21,22,23,24. However, clear proof for the two-component superconducting state is lacking, and the superconducting phase diagram is yet to be determined.
4Hb-TaS2 is a naturally occurring van der Waals heterostructure comprised of alternating 1T- and 1H-TaS2 layers (Fig. 1a), belonging to the P36/mmc hexagonal space group symmetry (#194). 1T-TaS2 is considered a Mott insulator and a quantum spin liquid candidate25,26,27,28. 2H-TaS2 is a superconductor with a critical temperature of 0.7 K29. 4Hb-TaS2 undergoes a charge density wave (CDW) transition at T = 315 K30, which is clearly observed as an abrupt increase in the resistance (see Fig. 1b) accompanied by a five-fold reduction of the Hall number (see inset of Fig. 1b and Supplementary Fig. S1). Nevertheless, the system remains metallic and undergoes a superconducting transition at Tc = 2.7 K, as can be seen in Fig. 1b.
In this work we combine macroscopic magneto-transport and scanning tunneling microscopy (STM) to discover a nematic superconducting state in 4Hb-TaS2 close to its superconducting transition temperature. We also propose a theoretical model to reconcile our findings with the observed breaking of time-reversal symmetry21.
Results
Each point in Fig. 1c is the 1T CDW super-cell, which dominates over the weaker 1H charge density modulations22. Surprisingly, we found modulations of the tunneling conductance in the form of highly oriented stripes with a separation of about ≈ 20 nm. These stripes break the C6 symmetry of the 4Hb-TaS2 crystal.
Remarkably, this symmetry breaking is manifested in the superconducting state. When rotating the magnetic field in the basal plane, parallel to the TaS2 planes of the sample, we observe significant two-fold modulations of the critical field Hc2 (Fig. 1d). We link the minimal critical field with the direction of the stripes as both are parallel to the crystal’s a-axis.
The stripes found by our STM data allow for nematic symmetry breaking in 4Hb-TaS2, including its superconducting state. Therefore, we interpret the two-fold critical field modulation as the signature of a multiple-component nematic superconducting order parameter, following Refs. 31,32,33,34.
Naively, an anisotropic Hc2 would result in an anisotropy of the vortex core35. However, the density of states in a vortex core at low temperatures is perfectly isotropic as seen in Fig. 1e. We argue that the observations of a nematic state and an isotropic vortex core can be reconciled by invoking a crossover from a chiral order parameter, which dominates at low temperatures, to a nematic one, appearing near Tc. The calculated zero field phase diagram is presented in Fig. 1f. Our model predicts a smaller anisotropy of Hc2 at low temperatures, as observed in the experiment and discussed further below.
We now focus on the characterization of the stripes and their possible origin. The stripes are well oriented across the entire sample and define a specific direction over a macroscopic length scale, roughly parallel to the crystal’s a-axis, as seen in Fig. 2a. Their direction persists even when crossing a CDW domain wall, as demonstrated in Fig. 1c. We focus on the regions with abundant stripes and observe a quasi-periodic modulation of ≈ 19.6 nm. In some rare regions no or only a single stripe is found, and the period is ill-defined.
We have performed local spectroscopic measurements on and off stripe, both in the normal and in the superconducting state well below Tc. For negative voltage biases, the density of states on a stripe differs from off a stripe (Fig 2b, c). This bias dependent difference suggests that the stripes represent a change in the local electronic density of states rather than just a topographic modulation. We further note that the superconducting gap itself, observed at low biases, remains the same on and off the stripes (Inset of Fig. 2c).
As mentioned above, when we rotate the magnetic field in the basal plane, a remarkable two-fold symmetry of the critical magnetic field Hc2 is detected, as seen in Fig. 3, and as detailed in Supplementary Fig. S6. The minimum of Hc2 is observed when the field is applied parallel to the crystal’s a-axis, similar to the direction of the stripes. Surprisingly, the anisotropy of the critical field is smaller as the temperature is decreased from Tc down to 1.8 K, and is much smaller at T = 0.4 K, hardly resolved from the data (see Supplementary Fig. S5).
Discussion
The anisotropy of the critical field does not depend on the direction of the applied measurements current. On the large single crystals, we applied current at four different directions, and found the resistance as function of the in-plane angle to have similar trend in all cases (see Fig. 3c). Moreover, the critical field variation in the thin flake did not depend on the direction of the current, as can be seen in Supplementary Fig. S2a. For more details about control experiments excluding spurious effects such as wobbling, see the Supplementary Information.
A straightforward explanation for the anisotropy of Hc2 is that it stems from a variation in the Josephson-vortex pinning due to the stripes. To test this conjecture, we model the stripes using a slow modulation of the inter-layer stacking configuration, yielding a variation of the perpendicular mass mz in a Ginzburg Landau (GL) theory along an in-plane coordinate, perpendicular to the observed stripes. Naturally, modulation of mz does not affect the round shape of the Abrikosov vortices in the plane. Solving the linearized GL equations, we generically find that the critical field is maximal parallel to the stripes. This is in contrast to our observations, ruling out this mechanism (see the Supplementary Information for details).
Moreover, slightly below the critical temperature we observe a clear in-plane rotational symmetry breaking, while at lower temperatures the superconducting state is much more isotropic (Supplementary Fig. S5), as seen in the round vortices (Fig. 1e) and the smaller variations in the in-plane critical field (Fig. 3a). We also note that 4Hb-TaS2 is different than most multi-component superconductors, where the nematic behavior is observed throughout the entire temperature range of the superconducting domain4,5,6.
Why does the imaged vortex core shows no anisotropy while the in-plane critical field strongly depends on the angle between the magnetic field and the crystal axis? We argue that this temperature dependence can arise from a competition between nematic and chiral superconductivity which we describe within a two-component GL theory33. This explanation describes our current results as well as the chiral superconducting ground state previously suggested in 4Hb-TaS221,23,24.
The two-component order parameter can be written as \({{{{{{{\mathbf{\eta }}}}}}}}=\eta (\begin{array}{c}\cos \alpha \\ \sin \alpha \,{e}^{i\gamma }\end{array})\), where η is the amplitude of the superconducting order parameter, and the angles α and γ parametrize the nematic and chiral phases. In a purely nematic state, either γ = 0 and α dictates the direction of nematicity and the resulting anisotropy, or α = 0. On the other hand, the purely chiral order, γ → ± π/2 and α = π/4, is isotropic. Deep in the superconducting state, the system is described by a chiral order parameter21, leading to isotropic vortices as reported here.
The origin of the emergent stripes is not fully understood. A possible scenario is that stacking two dimensional layers with a small mismatch and different CDW patterns generates a finite uniaxial strain (see supplementary material for more information). Regardless of the exact microscopic origin, we include this experimentally observed symmetry breaking via a ϵxx − ϵyy term in the GL theory. Solving the GL equations for different temperatures discussed in the supplementary material, we obtain that γ = π/2, although α varies with T. Fig. 1f shows that as the temperature increases and the order parameter is reduced, the strain term dominates to favor the nematic order near the critical temperature.
The transition we have modeled, which progresses from a fully nematic to a mixed chiral and nematic superconductivity, is anticipated to produce a slight kink in the specific heat, which would be very hard to detect experimentally. To simplify our model, we did not consider the possible presence of a dominant coexisting s-wave state or the contribution of excited quasi-particles, which would further diminish the observed kink in the specific heat (see the Supplementary Information for more details).
Following this model, our results can be understood as a competition between terms: at low temperatures, the order parameter is mostly chiral, in line with the isotropic vortex core in Fig. 1e and the almost isotropic Hc2 in Supplementary Fig. S5. At temperatures closer to Tc, the order parameter is mostly nematic, consistent with the observed two-fold angular dependence of the critical field seen in Fig. 3. This theory predicts that vortices gradually become anisotropic at higher temperatures as the order parameter becomes nematic.
To summarize, we find a microscopic stripe pattern in 4Hb-TaS2 and link it to the macroscopic two-fold symmetry of the superconducting critical field. The large variation in the critical field, of about 20%, implies possible existence of a nematic order parameter close to the normal state, which is allowed due to the strain field. We exclude a simpler explanation of Josephson-vortex pinning along the stripes that predicts a minimum in Hc2 opposite to our findings. We use a theoretical model to reconcile our observations of nematic superconductivity with the previously-suggested chiral superconducting ground state in the system. Future study is needed to understand the details of the microscopic mechanism responsible for the competition between chiral and nematic states suggested by our phenomenology.
Methods
Sample growth
High-quality single crystals of 4Hb-TaS2 were prepared using the chemical vapor transport method. Appropriate amounts of Ta and S were ground and mixed with a small amount of Se (1% of the S amount). The powder was sealed in a quartz ampule, and a small amount of iodine was added as a transport agent. The ampule was placed in a three-zone furnace such that the powder is in the hot zone. After 30 days, single crystals with a typical size of 5.0 mm × 5.0 mm × 0.1 mm grew in the cold zone of the furnace. The fact that the van der Waals stacking in 4Hb-TaS2 arrives in the form of a single crystal allows for clean, homogeneous and large samples.
Definition of the in-plane angle
We define zero in-plane angle as the direction parallel to the crystal’s a-axis in both transport and STM. In large crystals, we identify the crystal facet to establish the angle. For STM data, the angle is determined using the imaged lattice. However, in thin flakes of the crystal, where crystal axes identification is challenging, we define zero in-plane angle as the angle of the minimal critical field, aligning with our measurements in large crystals.
Transport measurements
Ohmic contacts were established by affixing platinum wires to the 4Hb-TaS2 single crystals using silver epoxy or by depositing aluminum onto flake samples cleaved using Scotch tape. For the larger samples, a current of approximately 1mA was applied using a Keithley 6221 current source, and the voltage drop was recorded using a Keithley 2182A nanovoltmeter. Measurements on the flake samples were conducted employing a standard lock-in technique with a Stanford SR830 lock-in amplifier, applying a current of 250 nA at a frequency of 37 Hz. High-field scans (Supplementary Fig. S5) were performed at the National High Magnetic Field Laboratory (NHMFL). The resistance was measured using a Lakeshore 372 resistance bridge with a current of 0.316 mA. In all of the resistance measurements the current was applied along the basal (ab-plane) plane of the sample. The critical field was defined as the the field in which the resistance is half of the normal state resistance. To determine the Hall signal we averaged two current orientations and anti-symmetrized the results with respect to the applied magnetic field.
Rotation platforms
Data in Figs. 1d, 3, and Supplementary Fig. S2 were collected in a cryogenic station with a one-axis rotator probe. The control experiment in Supplementary Fig. S3 used a piezo stack enabling two-axis rotation with continuous angle monitoring. High-field data in Supplementary Fig. S5 was obtained using a hybrid two-axis platform: an out-of-plane mechanical rotator and in-plane piezo rotation with a piezo actuator. The angle in the high-field facility was monitored by measuring three Hall sensors.
STM measurements
The samples were kept in an inert nitrogen environment before transferring to the load-lock of the STM chamber, exposing the samples to ambient conditions for a minimal amount of time. The samples were cleaved in the STM load-lock at ultra-high vacuum at room temperature. The cleaved crystals were then inserted directly to the 4 K sample stage of the STM head for spectroscopic measurements. Commercial PtIr tips were treated on a freshly prepared Cu(111) single crystal for the stability of the tips and then used for the measurements. All the spectroscopic data were measured using standard lock-in techniques with a frequency of 733 Hz. In Fig. 1c the measurement was performed at a constant current mode with set value of 200 pA. We interpret the change at the signal as originating from a change in conductance, and not due to a change in topography, as the stripes’ relative density of states changes with bias (Fig. 2b). In Figs. 1e, 2c the voltage was set in the range of 0.1–10 mV depending on the bias scan range, and the AC modulation varied between 2 mV to 200 mV. To ensure reproducibility, three different cleaves were performed (with three different tips) giving similar spectra.
Data availability
All data generated or analyzed during this study are included in this published article (and its supplementary information files).
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Acknowledgements
We thank M. Ben Shalom and J. Ruhman for useful discussions. A part of the work presented here was performed at the National High Magnetic Field Laboratory (NHMFL), supported by the National Science Foundation Cooperative Agreement no. DMR-1644779, the State of Florida and the DOE. We are indebted to David Graf for his valuable assistance at the high field laboratory. The experimental work performed at Tel Aviv university was supported by the Pazy Research Foundation Grant No. 326-1/22, Israel Science Foundation Grants No. 3079/20, 1711/23 and 476/22 the TAU Quantum Research Center and the Oren Family Chair for Experimental Physics. M.G. was supported by the Israel Science Foundation (ISF) and the Directorate for Defense Research and Development (DDR&D) Grant No. 3427/21 and by the US-Israel Binational Science Foundation (BSF) Grant No. 2020072. A.B. and E.S. acknowledge support from the European Research Council (ERC) grant agreement No. 951541, ARO (W911NF-20-1-0013). A. KL. acknowledges support from the Israel Science Foundation (ISF) and the Directorate for Defense Research and Development (DDR&D) Grant No 3467/21. The experimental work performed at the Technion was supported by the ISF Grant No. 1263/21. S.M present address is Department of Physics & Nanotechnology, SRM Institute of Science & Technology, Kattankulathur 603203, India.
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I.F. and A.KA. prepared the 4Hb-TaS2 single crystals. S.M., A.K.N, N.A., and H.B. performed and analyzed the STM measurements. M.G., A.B., E.S., and A.KL. proposed the theoretical explanation and performed the calculation of the phase diagrams, I.S., O.G., and I.M. performed the transport measurements. Y.D. conceived the experiment. All authors discussed the findings, wrote the manuscript and reviewed its final version.
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Silber, I., Mathimalar, S., Mangel, I. et al. Two-component nematic superconductivity in 4Hb-TaS2. Nat Commun 15, 824 (2024). https://doi.org/10.1038/s41467-024-45169-3
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DOI: https://doi.org/10.1038/s41467-024-45169-3
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