Abstract
Superconductor-ferromagnet interfaces in two-dimensional heterostructures present a unique opportunity to study the interplay between superconductivity and ferromagnetism. The realization of such nanoscale heterostructures in van der Waals (vdW) crystals remains largely unexplored due to the challenge of making atomically-sharp interfaces from their layered structures. Here, we build a vdW ferromagnetic Josephson junction (JJ) by inserting a few-layer ferromagnetic insulator Cr2Ge2Te6 into two layers of superconductor NbSe2. The critical current and corresponding junction resistance exhibit a hysteretic and oscillatory behavior against in-plane magnetic fields, manifesting itself as a strong Josephson coupling state. Also, we observe a central minimum of critical current in some JJ devices as well as a nontrivial phase shift in SQUID structures, evidencing the coexistence of 0 and π phase in the junction region. Our study paves the way to exploring sensitive probes of weak magnetism and multifunctional building-blocks for phase-related superconducting circuits using vdW heterostructures.
Similar content being viewed by others
Introduction
Recently, two-dimensional (2D) van der Waals (vdW) crystals have been widely investigated on their heterostructures1,2 by integrating disparate materials, promoting the exploration of unusual phenomena such as charge transfer3 and proximity effect4,5,6. By taking advantage of excluding the dangling bonds and lattice mismatch at surfaces, high-performance nanodevices have also been demonstrated in electronics7 and spintronics8. Among these, the discovery of intrinsic layered superconductors (S)9 and ferromagnets (F)10,11,12 whose properties vary in layer numbers paves the way to further exploiting such an incompatible order-parameter system. As such, the design of S–F heterostructures mainly focuses on the proximity effect-dominant coupling like Josephson junctions (JJ) with ferromagnetic barriers. With atomically flat and magnetically sharp interfaces, this type of functional nanodevices may potentially serve as critical components for superconducting quantum circuits13 or memories14.
In a ferromagnetic JJ, exchange energy (Eex) in magnets imposes a finite momentum to Cooper pairs, leading to a modulation of spatially damped oscillations of superconducting order parameter when penetrating the ferromagnetic barrier over the decay length scale15. Depending on the JJ barrier thickness, the ground state can either be a 0-junction with equal superconducting phases on both sides or a π-junction where the phases differ by π. Consistent with theoretical predictions, experiments have shown the presence of 0-π transitions by tuning the F-layer thickness in metallic or alloyed magnets16,17, as well as 0-π JJ structures18 with a corporate area consisting of these two ground states, providing the potential for an arbitrary φ-phase control19 in superconducting electronics. Except for the mentioned above, magnetic insulators in JJs are also fascinating for their spin filtering tunnel behaviors20, in which a pure second-harmonic current phase relation21 and macroscopic quantum tunneling22 have been realized. The nondissipative and low-decoherence nature makes it a promising tool in future applications. Also, inspired by the recent progress in the graphene-based micromagnetometry23, the JJ technique can be analogically developed to probe the weak magnetism of vdW magnetic insulators, because of its sensitivity to the spin-dependent Josephson tunneling process when applied as a tunnel barrier.
In this work, we report the construction of 2D-vdW JJs with ferromagnetic insulating barriers. Layered dichalcogenide 2H-NbSe2 is an excellent vdW superconductor for its robust superconductivity24, which has previously been selected to form highly transparent JJs25,26 and also been known to couple effectively to vdW tunnel barriers27. For the other, we choose intrinsic ferromagnetic semiconductor Cr2Ge2Te6 with a bulk Curie temperature (TCurie) of ~61 K28 and a narrow gap ~0.38 eV29 as an intermediate layer, whose easy axis points out of the cleaved plane. The JJ shows a typical Fraunhofer pattern manifesting a strong Josephson coupling state. Besides, the observed hysteresis of critical current (Ic) along with the corresponding junction resistance (R) against field sweep ascribes to the barrier’s magnetism. The measured hysteresis depends on the maximum applied field (Bmax), implying an evolutionary magnetization process of the barrier remanent magnetic moment. Meanwhile, the hysteretic behavior only appears when the JJs are in the superconducting state. We also find a central minimum of Ic patterns in some devices as a typical 0-π JJ signature, evidencing the coexistence of both 0 and π phase in the whole junction area. Also, a nontrivial ground-state phase φ is observed when employing a SQUID structure to detect the phase shift in this system. The possibility of incorporating inhomogeneities in the magnetizations can give rise to the superposition of 0-π state via tunneling process, and the asymmetric supercurrent distribution responding to the external magnetic field can be originated from the multi-domain state in the few-layer Cr2Ge2Te6.
Results
Basic characterizations of vdW JJs
Ferromagnetic JJ devices are fabricated by a dry-transfer technique30, which produces a clean interface via vdW coupling between layers. Figure 1a is the top and side view of the layered structures of 2H-NbSe2 and Cr2Ge2Te6, respectively. Figure 1b is a schematic illustration of the device structure with a four-terminal measurement configuration, where NbSe2 flakes are placed on the top and bottom and few-layer Cr2Ge2Te6 acts as an insulating barrier. The whole stack is fabricated on a silicon substrate capping of 285-nm SiO2. We choose a laminated vertical junction structure that is suitable for a relatively small piece of exfoliated Cr2Ge2Te6. Figure 1c displays a false-color scanning electron microscope (SEM) image of device #01 with three layers labeled by the dashed lines, and the height profile of intermediate Cr2Ge2Te6 flake is around 6.5 ± 0.4 nm measured by the atomic force microscope (AFM), beneath a flat junction area (S) of ~14.2 μm2. The entire fabrication process is performed in a glove box. A carefully controlled procedure assisted by the stepper motor is applied to eliminate the bubbles and surface oxidation, making it a high-quality vdW interface.
The JJ characteristics are first investigated below the superconducting critical temperature (Tc) of the NbSe2 crystals. Figure 1d shows typical current-voltage (IV) curves of junction device #01 at 0.1 K under zero field, with a hysteretic behavior in the charge (Ic) and retrap (Ir) current situations revealing a tunnel junction described by Resistively–Capacitively Shunted-Junction (RCSJ) model, however, the small Stewart-McCumber parameter (βc) of ~1.9 is derived from the Ir/Ic ratio of ~0.9 indicating a faintly underdamped regime which seems abnormal for an insulating barrier. The normal state resistance (Rn) is 10.6 Ω obtained from the linear part of its IV curves. In Fig. 1e, a contour plot of junction differential resistance (dV/dI) as a function of bias current (I) and in-plane field (B∥) is presented. Periodic oscillations of Ic from the Fraunhofer pattern correspond well to its in-plane R, as the positions of Ic minima are the same as those of R maxima. The periodicity of Ic oscillation ΔB ~4.2 mT is given by an integer flux quantum Φ0 in the effective area (Seff), from which we can obtain the effective junction length (d + 2λ) ~82.1−98.5 nm (d is the barrier thickness and λ is the London penetration depth of NbSe2 electrodes) with the junction width W ~5–6 μm (perpendicular to the field direction), for the area is not so regular. The Josephson penetration depth \({\lambda }_{{{{{{\rm{J}}}}}}}=\sqrt{\hslash /2{\mu }_{0}e(d+2\lambda ){J}_{{{{{{\rm{c}}}}}}}}\) is estimated to be 27.4–30.0 μm at 0.1 K which is much larger than the junction’s lateral size, where ℏ is the reduced Planck’s constant, μ0 is the vacuum permeability, e is the electron charge and Jc (~353.5 A cm−2) is the critical current density. Thus our devices should be treated as small JJs. Also, clear second-order oscillations are seen at higher bias due to Fiske resonance31 when the a.c. Josephson frequency equals the eigenfrequency of electromagnetic oscillations in this cavity, proving a well-defined JJ through the vdW stacking. Returning to the cavity nature of our JJ, the specific capacitance Cs can be also derived from the first voltage position V1 (0.57 mV) of the Fiske steps and the plasma frequency ωp, calculated as 22.3–26.9 fF μm−2 which has the similar magnitude as obtained for Cr2Ge2Te632 (Cs ~5.5–21.8 fF μm−2, the dielectric constant ε is ~4–16). And the parameter βc is given by the relationship \({\beta }_{{{{{{\rm{c}}}}}}}=2e{I}_{{{{{{\rm{c}}}}}}}{R}_{{{{{{\rm{n}}}}}}}^{2}C/\hslash\) as 5.4–6.7, larger than the estimation using the RCSJ model due to thermal activation or noises in the external circuits of IV measurements33, making it complicated to evaluate the internal dissipation.
Evolution of the magnetic barrier in JJs
For an unsaturated magnetic barrier, it is feasible to continuously reverse its orientations at a lower magnetic field. In Fig. 2, we present a comparison of Fraunhofer oscillation patterns of device #01 (~6.5 nm) when the field starts from different Bmax. Initially, it was magnetized to 9 mT at 0.1 K, then descended from positive to negative fields at −9 mT and eventually returned. The separated sweep branches in Fig. 2a give the central maximal Ic offsets at −0.6 mT and 0.3 mT, respectively. The total flux enclosed in the junction is the sum of the external flux and additional flux generated by the barrier magnetic moment, the latter of which reverses smoothly at a low magnetic field, resulting in a hysteresis window of 0.9 mT. The shape of patterns is slightly distorted under the magnetized process, as the field widths of the first side-lobes of the pattern are not exactly the same as those at opposite field directions, consistent with the model of a field-dependent magnetic moment in a hysteresis loop. The hysteresis observed in zero-bias R is equivalent to Ic (Fig. 2b). Next, we magnetized the device to 15 mT and repeated the same measurement at the higher applied field. Figure 2c shows that the positions of zero-flux Ic shift to −2 mT and 0.8 mT, resulting in a larger window of 2.8 mT. Estimations from Ic and R measurements both give accordant sizes of hysteresis.
To further understand the evolution of barrier magnetization (M), first, we obtain its hysteretic in-plane R (log-plot is used to clarify zero R) with a Bmax of 100 mT at 0.1 K (see the upper panel in Fig. 3a), in which the flux-induced oscillations in R persist when the supercurrent is unmeasurable at higher fields. The coincidence over ±75 mT of these two sweep directions reveals a saturation field of its moment. Empirically, we can correspond each minimum/maximum of R to half-integer/integer flux quantum trapped in the junction34 (see the lower panel in Fig. 3a). Therefore, the M of the barrier can be reconstructed from the equation \(\varPhi =4\pi MW{d}_{{{{{{\rm{F}}}}}}}+{\varPhi }_{{{{{{\rm{H}}}}}}}\) (dF is the thickness of the ferromagnetic interlayer), where Φ is the sum-up flux embedded in a JJ and ΦH is generated by the external field. Meanwhile, the largest hysteresis (ΔBmax), estimated from the central position of zero-order minimum R, can also be regarded as a quantitative index for this nanoflake’s in-plane magnetization (in device #01, ΔBmax is 9.3 mT when fully saturated to 100 mT). Next, we show the plot of ΔBmax varying with Bmax at 0.1 K in Fig. 3b, from which we find that ΔBmax is proportional to Bmax and nearly converges above 90 mT.
We also investigate the hysteretic behavior with thermal excitation, conjointly resolving the features about how hysteresis vanishes above the superconducting Tc. Figure 3c depicts the hysteretic in-plane R of the same device compared between the superconducting state and normal state. The hysteresis shrinks in R amplitude and magnetic field range as temperature increases and finally disappears above Tc since it is non-superconducting, which seems contradictory to the fact that Cr2Ge2Te6 at 6.5 K is still in the ferromagnetic state, as the hysteresis originates from its remanence. For detailed analyses, we measure the variation of ΔBmax as a function of temperature with a Bmax of 27 mT along with the normalized R under zero field (Fig. 3d). The value of ΔBmax remains almost unchanged below 2 K and then gradually decreases when warming up to 5.5 K. Nevertheless, the discrepancies in the curves of 6 and 6.2 K turn to become illegible around zero field causing a sudden drop of ΔBmax (see Supplementary Fig. 5). Therefore, we assume that ΔBmax here can denote the magnitude of Josephson interference. The reduction of ΔBmax is predominantly determined by thermal fluctuation above 2 K, where the phase coherence between the two separated superconductors is suppressed at high temperatures near Tc. This assumption is further supported by the bias-dependent experiments. A set of hysteretic R loops at d.c. bias current varying from 0 to 200 μA is shown in Fig. 3e, from which ΔBmax is obtained when the junction is driven into several superconducting states (qualitatively distinguished in the 0 mT dV/dI curve). We can observe an identical ΔBmax around 3.3 mT (within the error bar) below 100 μA, in line with our expectations that ΔBmax is only influenced by a specific Bmax before saturation at a specific temperature. Besides, the deviation between two directional sweeps is practically unidentifiable at a high bias of 200 μA and 400 μA (see Supplementary Fig. 6) in good agreement with a relatively small ΔBmax measured above 6 K, as a consequence of the main contribution to the junction R from the normal state R of superconductor NbSe2.
Evidence of π phase coupling
For those spin-singlet pairing superconductors, the presence of a π-JJ owing to the orbital effect in a metallic barrier requires direct exchange interactions and a comparable F-layer thickness to the oscillation wavelength. The Josephson phase is correlated through the whole junction. As the spontaneous flux penetrations into 0 and π phase parts produce a counterproductive effect, they will conjointly result in a central minimum of Ic instead of a maximum value either in absolute 0-JJs or π-JJs. Nevertheless, the realization of a π-JJ in the tunneling regime with the use of ferromagnetic insulators has been proposed theoretically on the atomic scale model35, but still waited for more explicit explorations. Here, we first find similar signatures of 0-π JJs in our devices which may also be the evidence of a φ-phase state. Figure 4a is the consequent non-Fraunhofer patterns of device #02 (the area S ~19.6 μm2) in the range of ±30 mT, whose barrier thickness is around 10.5 ± 0.3 nm. Extracted Ic values at a positive bias (Ic+) are given in Fig. 4b and the hysteresis with regard to the opposite sweeping direction is around 3 mT, acquired from the valley positions of the central minimum of Ic. Besides, the two sweeping branch curves of Ic coincide above 30 mT, implying a smaller in-plane magnetic remanence of a thicker Cr2Ge2Te6 than that of a thinner one measured in device #01.
The birth of a negative supercurrent in the insulator JJs is worthy of discussion. In analogy to the resonant tunneling process of Cooper pairs coupled by a single-level interacting quantum dot36, the spin-order of the Cooper pair transferring through a single electron with a given spin orientation will be reversed to conserve the momentum, resulting in a significant change of the single pairing state to a π-shift through fourth-order co-tunneling process (Fig. 4c). When extended to a tunnel barrier with inhomogeneous magnetizations, if the momentum of a Cooper pair is parallel to the same direction as the spin orientation in Cr2Ge2Te6, a segment of π phase coupling tunneling, therefore, inhibits the positive supercurrent from the normal 0 phase. As illustrated in Fig. 4d, junction region with precisely perpendicular magnetizations will result in π-JJs while other parts whose magnetizations are tilted away will form the rest 0-JJs. Another feasibility is to consider the magnetic activity of the barrier assuming nonuniform exchange interactions, inspired by the recent evidence of an incomplete 0-π transition in thick spin-filter JJs37. The spin-mixing angles for different transport channels are close to π as the barrier thickness increases exceeding the superconductor’s coherence length perpendicular to the layers (ξ0 ~2–3 nm38), which also implies a spin-triplet correlation. Besides, compared with the long junction of a stepped F-layer barrier, we didn’t observe a tiered flake of Cr2Ge2Te6 with distinguished two regions of different thickness in our JJs, whereas the nonconventional Fraunhofer patterns could be introduced by a magnetization texture of 0-π stacks with inhomogeneous exchange field39.
To further detect the phase shift in our systems, we also take phase-sensitive measurements employing a SQUID structure40 consisting of an SFS JJ (NbSe2/Cr2Ge2Te6) and a reference JJ (NbSe2/NbSe2). Details of the fabrication process are given in “Methods”. Figure 5a displays the false-color SEM image of SQUID #04, and its transport results as SQUID oscillations in Ic measured at 1.85 K are presented in Fig. 5b. The SQUID Ic as a function of magnetic flux Φ is counted through the SQUID loop (17.5 μm2) as the sum of the empty areas (5.9 μm2) and screening areas (11.6 μm2), agreed with the area calculated from the oscillation period of 0.118 mT, as shown in Fig. 5c. To extract the phase of the SQUID #04, we have calibrated the measurement systems through a NbSe2 SQUID on the same substrate to define the zero magnetic field, the data of which is also plotted in Fig. 5c. Under this condition we can find that the position of maximum Ic in the central period of SQUID #04 is deviated from the zero magnetic field, providing one nontrivial phase φ = 148.6° rather than a 0 or π phase by a fit with sine relation. It is known that a JJ with an arbitrary value φ of the phase should possess doubly degenerate ground states ±φ, however, the high damping environment in our JJs prohibits us to observe the other phase and its corresponding lower Ic following the specific bias sweeping sequences19.
In addition to the phase shift addressed in SQUID #04, we then measure its Ic in the variation of temperature and surprisingly find a nonmonotonic dependence which is likely to be an induced 0-π transition occurring at T ~0.8 Tc in this device, as shown in Fig. 5d. The thickness of the barrier is about 3.5 ± 0.7 nm. The shape of the Ic(T) curve is a more standard cusp-like 0-π transition with a higher weight of the s-wave singlet component, corresponding to the relatively low values of disorder and spin-mixing effects in this thin barrier. Compared to the similar phenomenon in GdN-based spin-filter JJs introduced above, the interfacial inhomogeneities, the high spin-filter efficiency of the barrier, and a large spin-mixing angle will result in the stronger magnetic activities in these magnetic JJs, in which the deviations of Ic from the conventional Ambegaokar–Baratoff (AB) behavior41 are more evident for thicker barrier samples. More investigations on the regime adapted for full-range thickness are needed to explore how the ground-state phase evolutes and the realistic micromagnetic nature of barriers could be taken into account.
Discussion
Our experiments on ferromagnetic JJs via vdW connection demonstrate a hysteretic supercurrent and resistance behavior, dominated by the barrier magnetization related to the Bmax and temperature. Since the unsaturated barrier moment can reverse smoothly at low fields, the supercurrent here follows a continuous modulation by the external flux shown in Ic measurements above. However, with progressive magnetization to a higher field, the Josephson tunneling process tends to become fragile, as the emergence of breakpoints in Ic causes a discontinuous pattern (see Supplementary Figs. 7 and 8). In device #01, the discontinuity starts from 23 mT, with an evident signature of abrupt changes of Ic between two flanks of a breakpoint. Another feature is the irreversibility of the whole pattern as the breakpoints persist when the field sweeps back. Detailed characterizations are performed in the Supplementary Information. This phenomenon might be associated with the layered spin structures of Cr2Ge2Te6, accounting for its enhanced interlayer coupling at high fields, that the barrier magnetization will resist external changes, thus a larger step of the applied field is required to overcome such a potential. When the fully-aligned spins start to flip back, the spin interactions between separated layers prevent it from a smooth reverse leading to the observed irreversibility. Besides, pinned spins of the ferromagnetic layer adjacent to the superconducting layer may also be restricted due to their 2D circumstances, strongly modulated by impurities and obstacles at two heterointerfaces.
Referring to the shape of unconventional Fraunhofer patterns, it should be mentioned that the influence of Abrikosov vortex42 from superconductor electrodes trapped in the JJ can introduce anomalous phase shifts as well, leading to similar observations. There are two criteria to distinguish that, one is the vortex-induced hysteresis that is opposite to remanent magnetization43,44, which is contradictory to our observations. The other can be inferred from the symmetry of its interference pattern. For a conventional JJ, Ic should be symmetric with respect to Ic+(B) = Ic−(B) and Ic(+B) = Ic(−B). Distorted Ic patterns by the vortex will naturally accord with the former formula, yet neither of them has been satisfied in our devices’ results. The crossing dashed lines in Fig. 4e reveal that the symmetry of our JJs could only be preserved when both considering the current and magnetic field inversion operations. Furthermore, deviated from a symmetric 0-π junction model, we find several remarkable asymmetries of the Ic patterns in our data. First, the nonzero central minimum of Ic can be originated from the asymmetry in 0 and π phase critical current densities. Besides, unequal Ic values and lobe widths of the two halves of subsequent peaks around the central valley should ascribe to different field-dependent flux penetration to 0 and π parts, introduced by the barrier in-plane magnetization18. Last, the nonequivalent periodic dependence of Ic oscillations compared between the positive and negative field applied halves (6 and 13 mT, marked in Fig. 4b) indicates a strong modulation by inhomogeneous local magnetizations. The nature of a possible multi-domain state in Cr2Ge2Te645 with randomly distributed magnetizations is expected to generate such asymmetries in this ferromagnetic barrier. The pinning of the domains can be reconfigured under the external in-plane magnetic field in the two halves, therein resulting in the observed variations of the central minimum as well as a successive maximum of Ic values with regard to the opposite field sweeping directions. Similar behaviors also perform in another device #03 (S ~23.5 μm2) (Fig. 4f) whose barrier thickness is of the same magnitude of around 11 ± 0.5 nm, giving the hysteresis of around 2 mT with a Bmax of 50 mT. Both two devices in this part have a comparative Ic background due to the finite-voltage criterion effect.
Also, we want to discuss the comparisons of JJ characteristics varying in barrier thickness. For a thinner barrier, the temperature dependence of IcRn product (Vc) of device #01 (~6.5 nm) is a well fit to AB relation for an insulating barrier. The calculated zero temperature Vc0 ~0.51 mV is much smaller than the theoretical maximum value of πΔ/2e = 1.57 mV (Δ ~1 meV is the gap value of bulk NbSe2), showing a strong suppression by the magnetic barrier on Josephson current for the phase differences acquired by spin-up or spin-down electrons. Compared to the suppression, we find an apparent excess supercurrent over the AB relation fit at low temperature (see Supplementary Fig. 9) in the thicker Josephson device #03 (~11 nm). The IcRn product measured at 0.5 K exceeds the calculated limit from the AB relation fit. The gradual deviation between the data and AB values below 4.6 K is similar to former studies in NbN/GdN/NbN JJs20. Nevertheless, we didn’t observe any evidence of 0-π transition in its temperature dependence. Considering our material systems, the equilibrium domain size of Cr2Ge2Te6 is probably larger in ultrathin nanoflakes, while the formation of multidomains is observed in the thicker sample with a smaller domain size. Further discussions on the correlation between the domain size and the film thickness are presented in Supplementary Information. Aware of the discrepancy in barrier thickness, the relative size of domain walls would introduce a notable magnetic inhomogeneity that implies the reduction of exchange energy seen by the Cooper pairs, therein promoting the enhancement of Josephson current in thicker samples46.
We would refocus on the validity of using the JJ structure to probe magnetism in atomic vdW materials. Few experiments have shown a direct study of ferromagnetic semiconductors or insulators via transport measurements, particularly limited at low temperatures. Like previously reported structures of tunneling magnetoresistance (TMR)47 or spin–orbit torque (SOT)48 devices for the same goal, the JJ is also a potential structure for its high sensitivity to minor variations in the response of external magnetic fields, because of a dramatic transition between the normal and superconducting states. The thought of employing flux quantization as an in-situ magnetometer proves it to be a precise technique to trace the evolution process of its barrier magnetization.
To conclude, we report the realizations of Josephson junctions based on 2D van der Waals superconductor NbSe2 and ferromagnet Cr2Ge2Te6. We demonstrate that such hysteretic behavior of supercurrent and magnetoresistance is predominantly induced by the magnetic barrier remanence, therefore the hysteresis can be modulated by the maximum applied field and temperature. Moreover, we observe 0-π JJs signatures which are the evidence of π phase coupling in this crystalline vdW heterostructure, possibly attributed to a momentum-conserving tunneling process through the region with multidirectional magnetizations. And the layered structure of the barrier can generate an anomalous tunneling effect for its internal interlayer coupling. The stacked nanojunctions are of great potential to investigate vdW coupling in layers, and further expectations on dissipationless spin-active or switchable φ-phase JJs can be accomplished in the use of other insulating magnets like CrI3 or CrCl3 with intrinsic anisotropic magnetization.
Methods
Crystal growth
A high-quality crystal of bulk NbSe2 was grown via the chemical vapor transport method with iodine as the transport agent. A stoichiometric ratio of Nb and Se powders (with 0.2% excess of Se) were evacuated and sealed in a quartz tube with 0.1 g iodine flakes and then placed in a two-zone furnace in a temperature gradient from 730 °C to 770 °C for 2 weeks. Single-crystals of Cr2Ge2Te6 were synthesized using the Te self-flux method. The raw powders of Cr, Ge, and Te (with a ratio of 1:4:20) were mixed and kept at 950 °C for 6 h, and the mixture was then cooled at a rate of 2 °C/h, followed by centrifugation at 500 °C to get its bulk material.
Device fabrication
The heterostructure devices were fabricated through a dry-transfer method in the glove box (H2O, O2 <0.1 ppm). 2H-NbSe2 and Cr2Ge2Te6 flakes were first mechanically exfoliated onto polydimethylsiloxane (PDMS) stamps with rough identifications of thickness by optical microscope, and next stacked onto a Si substrate capped with a 285-nm-thick SiO2 layer slowly, controlled by a stepper motor. A piece of flat hBN could be placed on the top to cover the whole stack to protect the sample from further oxidation. The multiterminal electrical contacts were patterned by a standard e-beam lithography technique and subsequently deposited of Cr/Au (5/70 nm) via magnetron sputtering. The process for a SQUID is a little different. During the assembly, the middle Cr2Ge2Te6 layer was partially covered along one side of the bottom NbSe2 flake, then the top NbSe2 was placed onto these two parts with Cr2Ge2Te6 in beneath or not. To define the SQUID structure, we used e-beam lithography to prepare the patterned masks. Redundant parts were finally removed by reactive ion etching with a mixture of SF6 and O2.
Transport measurements
The transport measurements were carried out in two Physical Property Measurement Systems (PPMS, Quantum Design), one equipped with a dilution refrigerator with the temperature down to 50 mK and the other without down to 1.85 K. The transport properties were acquired using lock-in amplifiers (SR 830) and Agilent 2912 meters. In differential resistance measurements, a small a.c. excitation was generated from the lock-in amplifier output voltage in combination with a larger d.c. bias applied by Agilent 2912 through a 100 kΩ resistor, and the differential voltage was measured at a low frequency (<40 Hz). In magneto-transport measurements, the field direction was parallel to the substrate, therefore perpendicular to the current flowing across the barrier from top to bottom superconductors.
Analysis of the JJ capacitance from Fiske steps
To get the capacitance of the JJ31, first, the voltage positions Vn of Fiske resonance is given as Vn = nΦ0c/2W, where c is Swihart velocity and W is the junction width. Using the Josephson penetration depth λJ determined from the Fraunhofer pattern, the plasma frequency of a JJ is obtained as ωp/2π = c/λJ. Moreover, the plasma frequency is defined as ωp = 1/τp = [2eJc/ℏCs]1/2 where τp is the time constant, therefore we could acquire the specific capacitance Cs.
Ambegaokar–Baratoff theory
Also, to research the temperature dependence of our JJs, we used the AB theory41 to fit the data, expressed as Ic(T)Rn = (πΔ(T)/2e)·tanh[Δ(T)/2kBT], where Δ(T) is the superconducting gap calculated from BCS theory and kB is the Boltzmann constant.
Data availability
The data that support the plots within this paper and other findings of this study are available from the corresponding author upon reasonable request.
References
Geim, A. K. & Grigorieva, I. V. Van der Waals heterostructures. Nature 499, 419–425 (2013).
Liu, Y. et al. Van der Waals heterostructures and devices. Nat. Rev. Mater. 1, 16042 (2016).
Lee, C.-H. et al. Atomically thin p–n junctions with van der Waals heterointerfaces. Nat. Nanotechnol. 9, 676–681 (2014).
Avsar, A. et al. Spin–orbit proximity effect in graphene. Nat. Commun. 5, 4875 (2014).
Zhong, D. et al. Van der Waals engineering of ferromagnetic semiconductor heterostructures for spin and valleytronics. Sci. Adv. 3, e1603113 (2017).
Benítez, L. A. et al. Tunable room-temperature spin galvanic and spin Hall effects in van der Waals heterostructures. Nat. Mater. 19, 170–175 (2020).
Choi, K., Lee, Y. T. & Im, S. Two-dimensional van der Waals nanosheet devices for future electronics and photonics. Nano Today 11, 626–643 (2016).
Fert, A. Nobel lecture: origin, development, and future of spintronics. Rev. Mod. Phys. 80, 1517–1530 (2008).
Staley, N. E. et al. Electric field effect on superconductivity in atomically thin flakes of NbSe2. Phys. Rev. B 80, 184505 (2009).
Huang, B. et al. Layer-dependent ferromagnetism in a van der Waals crystal down to the monolayer limit. Nature 546, 270–273 (2017).
Gong, C. et al. Discovery of intrinsic ferromagnetism in two-dimensional van der Waals crystals. Nature 546, 265–269 (2017).
Deng, Y. et al. Gate-tunable room-temperature ferromagnetism in two-dimensional Fe3GeTe2. Nature 563, 94–99 (2018).
Gingrich, E. C. et al. Controllable 0–π Josephson junctions containing a ferromagnetic spin valve. Nat. Phys. 12, 564–567 (2016).
Baek, B., Rippard, W. H., Benz, S. P., Russek, S. E. & Dresselhaus, P. D. Hybrid superconducting-magnetic memory device using competing order parameters. Nat. Commun. 5, 3888 (2014).
Buzdin, A. I. Proximity effects in superconductor-ferromagnet heterostructures. Rev. Mod. Phys. 77, 935–976 (2005).
Ryazanov, V. V. et al. Coupling of two superconductors through a ferromagnet: evidence for a π junction. Phys. Rev. Lett. 86, 2427–2430 (2001).
Kontos, T. et al. Josephson junction through a thin ferromagnetic layer: negative coupling. Phys. Rev. Lett. 89, 137007 (2002).
Kemmler, M. et al. Magnetic interference patterns in 0-π superconductor/insulator/ferromagnet/superconductor Josephson junctions: effects of asymmetry between 0 and π regions. Phys. Rev. B 81, 054522 (2010).
Sickinger, H. et al. Experimental evidence of a φ Josephson junction. Phys. Rev. Lett. 109, 107002 (2012).
Senapati, K., Blamire, M. G. & Barber, Z. H. Spin-filter Josephson junctions. Nat. Mater. 10, 849–852 (2011).
Pal, A., Barber, Z. H., Robinson, J. W. A. & Blamire, M. G. Pure second harmonic current-phase relation in spin-filter Josephson junctions. Nat. Commun. 5, 3340 (2014).
Massarotti, D. et al. Macroscopic quantum tunnelling in spin filter ferromagnetic Josephson junctions. Nat. Commun. 6, 1–6 (2015).
Kim, M. et al. Micromagnetometry of two-dimensional ferromagnets. Nat. Electron. 2, 457–463 (2019).
Frindt, R. F. Superconductivity in ultrathin NbSe2 layers. Phys. Rev. Lett. 28, 299–301 (1972).
Yabuki, N. et al. Supercurrent in van der Waals Josephson junction. Nat. Commun. 7, 10616 (2016).
Kim, M. et al. Strong proximity Josephson coupling in vertically stacked NbSe2–graphene–NbSe2 van der Waals junctions. Nano Lett. 17, 6125–6130 (2017).
Dvir, T. et al. Spectroscopy of bulk and few-layer superconducting NbSe2 with van der Waals tunnel junctions. Nat. Commun. 9, 598 (2018).
Carteaux, V., Brunet, D., Ouvrard, G. & Andre, G. Crystallographic, magnetic and electronic structures of a new layered ferromagnetic compound Cr2Ge2Te6. J. Phys. Condens. Matter 7, 69–87 (1995).
Li, Y. F. et al. Electronic structure of ferromagnetic semiconductor CrGeTe3 by angle-resolved photoemission spectroscopy. Phys. Rev. B 98, 125127 (2018).
Wang, L. et al. One-dimensional electrical contact to a two-dimensional material. Science 342, 614 (2013).
Wild, G., Probst, C., Marx, A. & Gross, R. Josephson coupling and Fiske dynamics in ferromagnetic tunnel junctions. Eur. Phys. J. B 78, 509–523 (2010).
Escolar, J. et al. Anisotropic magnetoconductance and Coulomb blockade in defect engineered Cr2Ge2Te6 van der Waals heterostructures. Phys. Rev. B 100, 054420 (2019).
Kautz, R. L. & Martinis, J. M. Noise-affected I-V curves in small hysteretic Josephson junctions. Phys. Rev. B 42, 9903 (1990).
Bol’ginov, V. V., Stolyarov, V. S., Sobanin, D. S., Karpovich, A. L. & Ryazanov, V. V. Magnetic switches based on Nb-PdFe-Nb Josephson junctions with a magnetically soft ferromagnetic interlayer. JETP Lett. 95, 366–371 (2012).
Kawabata, S., Asano, Y., Tanaka, Y., Golubov, A. A. & Kashiwaya, S. Josephson π state in a ferromagnetic insulator. Phys. Rev. Lett. 104, 117002 (2010).
van Dam, J. A., Nazarov, Y. V., Bakkers, E. P. A. M., De Franceschi, S. & Kouwenhoven, L. P. Supercurrent reversal in quantum dots. Nature 442, 667–670 (2006).
Caruso, R. et al. Tuning of magnetic activity in spin-filter Josephson junctions towards spin-triplet transport. Phys. Rev. Lett. 122, 047002 (2019).
Banerjee, S. S. et al. Magnetic phase diagram of anisotropic superconductor 2H-NbSe2. Phys. B Condens. Matter 237–238, 315–317 (1997).
Alidoust, M., Sewell, G. & Linder, J. Non-Fraunhofer interference pattern in inhomogeneous ferromagnetic Josephson junctions. Phys. Rev. Lett. 108, 037001 (2012).
Guichard, W. et al. Phase sensitive experiments in ferromagnetic-based Josephson junctions. Phys. Rev. Lett. 90, 167001 (2003).
Ambegaokar, V. & Baratoff, A. Tunneling between superconductors. Phys. Rev. Lett. 10, 486–489 (1963).
Golod, T., Rydh, A. & Krasnov, V. M. Detection of the phase shift from a single Abrikosov vortex. Phys. Rev. Lett. 104, 227003 (2010).
Golod, T., Pagliero, A. & Krasnov, V. M. Two mechanisms of Josephson phase shift generation by an Abrikosov vortex. Phys. Rev. B 100, 174511 (2019).
Krasnov, V. M. Josephson junctions in a local inhomogeneous magnetic field. Phys. Rev. B 101, 144507 (2020).
Han, M.-G. et al. Topological magnetic-spin textures in two-dimensional van der Waals Cr2Ge2Te6. Nano Lett. 19, 7859–7865 (2019).
Bergeret, F. S., Volkov, A. F. & Efetov, K. B. Enhancement of the Josephson current by an exchange field in superconductor-ferromagnet structures. Phys. Rev. Lett. 86, 3140–3143 (2001).
Song, T. et al. Giant tunneling magnetoresistance in spin-filter van der Waals heterostructures. Science 360, 1214–1218 (2018).
Lohmann, M. et al. Probing magnetism in insulating Cr2Ge2Te6 by induced anomalous Hall effect in Pt. Nano Lett. 19, 2397–2403 (2019).
Acknowledgements
This work was supported by the National Natural Science Foundation of China (51772310, 11934005, and 11874116), the National Key Research and Development Program of China (Grant No. 2017YFA0303302 and 2018YFA0305601), the Science and Technology Commission of Shanghai (Grant No. 19511120500), the Shanghai Municipal Science and Technology Major Project (Grant No. 2019SHZDZX01), and the Program of Shanghai Academic/Technology Research Leader (Grant No. 20XD1400200). E.Z. acknowledges support from China Postdoctoral Innovative Talents Support Program (Grant No. BX20190085) and China Postdoctoral Science Foundation (Grant No. 2019M661331). Part of the sample fabrication was performed at Fudan Nano-fabrication Laboratory. We sincerely thank Dr. Ce Huang from Fudan University for tremendous help to all results. We thank Xuejian Gao from Prof. Kam Tuen Law’s group from Hong Kong University of Science and Technology for helpful discussion on the Josephson interference mechanism.
Author information
Authors and Affiliations
Contributions
F.X. conceived the ideas and supervised the overall research. Z.J. and Y.Z. synthesized high-quality NbSe2 bulk samples. X.S. synthesized high-quality Cr2Ge2Te6 bulk samples. L.A., Z.J., and Y.Z. fabricated the nanodevices. L.A. and E.Z. performed the PPMS measurements and data analysis. X.X., Y.Y., and X.C. provided the curve fitting. S.L., Z.L., and P.L. carried out the SEM, AFM, and SQUID measurements. T.Z. performed the Kerr rotation measurements. X.K. and Z.H. provided in-depth discussions of vdW physics. J.Y. and S.D. provided high-quality boron nitride samples and helped with some material characterization. L.A. and F.X. wrote the paper with assistance from all other co-authors.
Corresponding authors
Ethics declarations
Competing interests
The authors declare no competing interests.
Additional information
Peer review information Nature Communications thanks Jianming Lu and the other, 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.
Supplementary information
Rights and permissions
Open Access This article is licensed under a Creative Commons Attribution 4.0 International License, which permits use, sharing, adaptation, distribution and reproduction in any medium or format, as long as you give appropriate credit to the original author(s) and the source, provide a link to the Creative Commons license, and indicate if changes were made. The images or other third party material in this article are included in the article’s Creative Commons license, unless indicated otherwise in a credit line to the material. If material is not included in the article’s Creative Commons license and your intended use is not permitted by statutory regulation or exceeds the permitted use, you will need to obtain permission directly from the copyright holder. To view a copy of this license, visit http://creativecommons.org/licenses/by/4.0/.
About this article
Cite this article
Ai, L., Zhang, E., Yang, J. et al. Van der Waals ferromagnetic Josephson junctions. Nat Commun 12, 6580 (2021). https://doi.org/10.1038/s41467-021-26946-w
Received:
Accepted:
Published:
DOI: https://doi.org/10.1038/s41467-021-26946-w
- Springer Nature Limited
This article is cited by
-
2D Magnetic heterostructures: spintronics and quantum future
npj Spintronics (2024)
-
DNA as a perfect quantum computer based on the quantum physics principles
Scientific Reports (2024)
-
Nanoscale spin ordering and spin screening effects in tunnel ferromagnetic Josephson junctions
Communications Materials (2024)
-
Probing local magnetic states in the van der Waals ferromagnet Fe4GeTe2 by a vector-field magnetic force microscope
Journal of Materials Science (2024)
-
Long-range skin Josephson supercurrent across a van der Waals ferromagnet
Nature Communications (2023)