Abstract
Combining magnetic and superconducting functionalities enables lower energy spin transfer and magnetic switching in quantum computing and information storage, owing to the dissipationless nature of quasi-particle mediated supercurrents. Here, we put forward a system where emergent spin-ordering and diffusion of Cooper pairs are achieved at a non-intrinsically magnetic nor superconducting metallo-molecular interface. Electron transport, magnetometry and low-energy muon spin rotation are used to probe time-reversal symmetry breaking in these structures. By comparing the Meissner expulsion in a system including a Cu/C60 spin-converter interface to one without, we observe a paramagnetic contribution that can be explained due to the conversion of spin-singlet Cooper pair states into odd-frequency triplet states. These results demonstrate the potential of metallo-molecular interfaces to achieve singlet to triplet Cooper pair conversion, a capability not present in either metal or molecule separately that could be used in the generation and controlled diffusion of spin polarised dissipationless currents.
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Introduction
According to conventional theories on the superconducting condensate, ferromagnetism and superconductivity are antagonistic states of matter. This is due to the ferromagnetic exchange field imparting a pair-breaking effect upon conventional spin-singlet superconducting pair correlations that possess opposing spin -i.e. spin up/down electron pairs. However, local magnetic order emergent at metallo-molecular multilayers can be combined with superconducting proximity effects to generate a region where both magnetic exchange and superconducting pair diffusion are present. Organic superconducting molecules and ferromagnetic metal complexes have been used to chemically design materials where superconductivity and magnetism are shown to coexist1. The spin dynamics of molecular magnets are heavily influenced by the superconducting order of a lead substrate2. Evidence of equal-spin triplet-pairing p-wave symmetry in proximity systems, which feature adsorbed helical chiral molecules, shows the potential of molecular structures in manipulating the symmetry of pair correlations3,4. The realisation of super-spintronic devices requires the coalescence of both superconducting and ferromagnetic long-range order in a single system. Despite this, the theoretical prediction of odd-frequency spin-triplet pair states, with even spin parity, arising through the design of superconductor/ferromagnetic, allows for complete synergy between superconductivity and spintronics5,6,7,8,9.
Odd-frequency superconducting correlations have been probed successfully using transport measurements10,11, tunnelling spectroscopy12 and low-energy muon spin rotation (LE-μSR). The latter directly probes the paramagnetic Meissner screening generated by odd-frequency spin-triplet Cooper pairs13,14,15. Typical super-spintronic devices require the generation of a SZ = ±1 long-range spin-triplet component (LRTC) to preserve the superconducting correlations inside ferromagnetic layers16,17. Unlike spin-singlet and SZ = 0 spin-triplet pairs, the equal-spin pairing of the long-range spin-triplet component is no longer subject to pair-breaking mechanisms within ferromagnetic layers. These correlations are thus able to carry dissipationless spin information while facilitating the superconducting proximity of ferromagnets owing to their extended propagation length in spin-polarised materials.
For applications and research pathways into low power electronics and quantum computing, there are two drawbacks. Firstly, the need to grow complex compounds or magnetic materials with superconductors, which can have a significant impact, e.g. on the information coherence time of qubits18,19,20,21. Secondly, the superconducting/spin correlation can only be changed by growing new samples with different composition or structural design. At the interface between inorganic and molecular materials, unique phenomena can emerge, such as surface states with distinct electrical and magnetic properties31,32.
Low-energy muon spin spectroscopy in Single-Probe samples
The leakage of Cooper pairs through a magnetic metal has been shown to lead to the generation of spin-polarised odd-frequency pairs33,34. To determine the effect of a spin-converter molecular interface upon the superconducting order parameter pairing symmetry, we measure hybrid metallo-molecular systems with LE-μSR. The technique can probe directly the Meissner state and the presence of spin-ordering as a function of depth within the sample. We fabricated and measured two sets of samples, which we refer to as ‘Single-Probe’ and ‘Multi-Probe’. For both sample sets, a comparison is made between structures with and without a Cu/C60 spin-converter interface (IS–C). The Single-Probe samples had nominal, bottom-up, structures of:
Thicknesses in brackets are in nm. The single 50-nm Au layer is used to moderate the muon beam. We include a 50-nm superconducting film so that the sample is in the mesoscopic regime for sputtered Nb; its thickness is greater than the superconducting coherence length, (\(\xi \sim 10\) nm) while being less than the reported penetration depth (\(\lambda _0 > \) 90 nm)35,36. This ensures that the contribution to the µ+ precession signal from the conventional Meissner effect is minimised and no vortices can form in-plane. Because of a lack of electronic screening, muons stop** in the C60 film will form muonium, a hydrogen-like bound state37. In an applied transverse magnetic field (TF), the transitions between different spin configurations of the C60 muonium state happen on a timescale that is shorter than the instrument resolution. Therefore, in this geometry we are only sensitive to the precession of the diamagnetic μ+ particles stop** in the metallic layers.
The thicknesses of the C60 layers have been engineered in all samples so that the separation between Au and Nb is shorter than, or equal to, the Cooper pair propagation length we measure in C60 (ξEff ~ 30 nm). The emergence of spin order at Cu/C60 and its effect on the superconductor were probed first by magnetometry and low-temperature transport. The results are compared against the sample without the spin-converter interface. The onset of Meissner expulsion for the two samples occurs at very similar temperatures (Fig. 3a). However, the addition of the thin Cu layer leads to an emergent magnetic signal at RT due to magnetic hardening (Fig. 3b)23,25,38. The sample with the Cu/C60 interface has a moment per area of m = 27±1 μemu cm−2, which equates to a volume magnetisation of 90 ± 3 emu cm−3, assuming that the magnetic order is localised to the Cu. The sample without a Cu/C60 interface has a moment of m = 2 ± 1 μemu cm−2, consistent with a typical instrumental background.
a Moment vs. temperature scans show that the onset of Meissner screening in the two samples occurs at similarly high temperatures (>8.5 K). b Magnetic hysteresis loops measured at 300 K, showing a moment of 27 ± 1 μemu cm−2 (with Cu/C60 interfaces; orange triangles) and 2 ± 1 μemu cm−2 (without; purple dots). c The temperature dependence of the out of plane critical field, \({{H}}_{{\mathrm{c}}2 \bot }\left( {{T}} \right)\), for the two heterostructures gives similar Ginzberg-Landau coherence lengths. d Simulated magnetic flux profiles, <B><x>, where the green and pink functions model the expected flux expulsion for London penetration lengths of 313 (green line) and 218 nm (pink line), respectively. The implantation distributions, according to the muon stop** depths for all energies used are also shown. e The average local magnetic flux, <B>, measured at 2.5 K (orange diamonds) and 10 K (blue dots) and normalised to the flux density in the niobium layer at 10 K, BN. The London model gives penetration lengths of 313 nm (with Cu/C60) and 218 nm (without). Error bars are statistical variations over 5 million muon decay measurements.
By fitting the temperature dependence of the out of plane critical field, \(H_{c2 \bot }\left( T \right)\), we obtain coherence lengths of \(\xi _{ {\mathrm{GL}}}\)= 9.34 ± 0.02 (9.63 ± 0.02) nm for the sample without(with) the IS–C, Fig. 3c. These values are typical for sputtered Nb in the dirty limit \(l < \xi _0,l\) being the electron mean free path)39,40. The muon implantation depth is dependent upon its energy, Fig. 3d. Once thermalised, it undergoes spin precession about the local field until decaying into a positron, emitted preferentially along the muon spin direction. Five million of these events are captured to fit the time evolution of the muon precession in a 300 G transverse field. The average magnetic flux for each implantation energy,\(\langle B\rangle( E)\) is determined from the time-dependent polarisation of the muon, and then we use the stop** profiles to obtain \(\langle B\rangle \langle x \rangle\).41,42,43, with \(\langle x\rangle\) the average probing depth for each energy \(E\).
\(\langle B\rangle\langle x\rangle\) is normalised to the average field within the superconductor in the normal state, \(B_{\mathrm{N}}\), and plotted against the average implantation depth. As a first approximation, we chose to model the flux expulsion entirely within the Nb layer. Although superconducting correlations reside within the proximitised C60 and Au layers, their relative screening amplitudes are expected to be weak and the signal dominated by the superfluid pair density in Nb. The \(\langle B\rangle\langle x\rangle\) profile for the non-magnetic Single-Probe sample can be accurately described by a London model with \(\lambda \left( {2.5\,{\mathrm{K}}} \right) = 218\,{\mathrm{nm}}\), in good agreement with sputtered Nb films in the dirty limit35,44. However, when the spin-converter Cu/C60 layer is in proximity to the Nb surface, the \(\langle B\rangle\langle x\rangle\) fit now yields \(\lambda (2.5\,{\mathrm{K}}) = 313\,{\mathrm{nm}}\), representing a sizeable modification to the superconducting properties of this system (Fig. 3e).
If there were a pair-breaking effect due to the exchange energy of the spin-ordered Cu/C60 interface, then \(N_{\mathrm{s}}\) for the spin-converter sample would need to be roughly half that of the control S/M/N system to explain such an elongation of \(\lambda\), since \(\lambda ^{ - 2} \propto N_{\mathrm{s}}\). However, as demonstrated by the transport measurements in Fig. 3a, c, there is no suppression of superconductivity for the spin-converter sample. Instead, it has a slightly higher superconducting Tc. The reduced flux expulsion in the spin-converter interface may be the manifestation of an additional paramagnetic contribution quenching the diamagnetic Meissner effect.
Low-energy muon spin spectroscopy in Multi-Probe samples
Ferromagnets may result in an enhanced Meissner expulsion due to changes in the boundary conditions or proximity effects driven by the vector potential45,46,47. By contrast, the generation of odd-frequency spin-triplet pairing states at superconductor/ferromagnetic interfaces can suppress the conventional diamagnetic Meissner effect13. The supercurrent density, \({\boldsymbol{j}}\), arising due to a magnetic vector potential, \({\boldsymbol{A}}\), can be rewritten in terms of singlet (ns) and triplet densities (nt): \({\boldsymbol{j}} \propto \left( {n_ {\mathrm{s}} - n_ {\mathrm{t}}} \right)\)48. Therefore, in a system where odd-frequency correlations exist, a paramagnetic susceptibility (χ > 0) can develop locally if nt > ns14,15. If the \(n_{\mathrm{s}}/n_{\mathrm{t}}\) ratio varies spatially throughout the spin-converter sample, then at some specific depths a paramagnetic signal might emerge where \(n_{\mathrm{s}}/n_{\mathrm{t}} \,<\, 1\). In order to capture this contribution within \(B\left( E \right)\) we use multiple thin Au probe layers that create deterministic stop** locations for the muon particles, thus effectively increasing the depth resolution:
Transport measurements show excellent agreement between the two structures, with the Tc of both samples at ≳8.7 K – Fig. 4a. Supplementary Note 3 shows the optimisation of the local magnetic flux sensitivity, with the muon stop** profiles in Fig. S4. Hysteresis loops are shown in Fig. 4b, which demonstrates that the sample with the IS–C has a moment per area, m = 24 ± 1 μemu cm−2 – very similar to that measured in the previous set. The sample without Cu shows a background signal of m = 0.4 ± 0.2 μemu cm−2.
a The two samples have very similar superconducting transition temperatures (Tc). b Magnetic hysteresis loops at 300 K for the two Multi-Probe sister samples. The saturation magnetisation per unit area are 24 ± 1 μemu cm−2 (with Cu/C60; orange dots) and 0.4 ± 0.2 μemu cm−2 (without; purple triangles). c Simulated stop** profiles for the superconductor/molecular/normal metal (S/M/N) structure at 9 keV (green symbols) and 20 keV (black symbols). At 9 keV, no muons are implanted into the Nb film; this is also true for the superconductor/molecular/spin-converter interface (S/M/IS–C/M/N) structure in e. d Temperature dependence of the average local field, \(\langle{{B}}\rangle({{E}})\), in a 300 G applied transverse field for the S/M/N structure. Well below Tc, a small reduction in \(\langle{{B}}\rangle({{E}})\) is observed in the Au layer at 9 keV implantation energy. This small Meissner screening originates from the leakage of Cooper pair states through the C60 and into the Au layer. At 20 keV, muons stop exclusively in the Nb layer, and a large conventional Meissner effect is observed. e Simulated stop** profiles at 9 keV (red symbols) and 20 keV (blue symbols) show that the depth dependence of the muon implantation is mostly unaffected by the inclusion of the spin-converter layer. f The temperature dependence of the measured local field in a 300 G applied transverse field for the S/M/IS–C/M/N structure. Below Tc, an increase in \({\mathrm{B}}\) is observed in the Au layer at 9 keV (red symbols) due to the presence of odd-parity pairs. At 20 keV (blue symbols), the conventional Meissner effect is roughly half compared to the sample without the spin-converter Cu/C60 interface. Error bars are statistical variations over 5 million muon decay measurements.
Muon measurements were performed at 9 and 20 keV to probe local screening effects at the Au layer closest to the superconductor (Au1) and within the Nb layer, respectively, see Fig. 4c, e. At 9 keV, the highest fraction of thermalised μ+ particles (\(x_{{\mathrm{max}}}\)) in both control and spin-converter samples lies within the Au1 layer, with no muons stop** in the Nb. Therefore, we can decouple the signal arising from screening currents within the Au1 probe layer from the superconducting substrate. At 20 keV, \(x_{{\mathrm{max}}}\) lies 10–20 nm inside the Nb layer, and there is only a small contribution to the signal from the Au layers. See the Supplementary Notes 3 and 5 for further detail and comparisons between single and multi-probe structures.
The temperature dependence of \(\langle B(E)\rangle/B_{\mathrm{N}}\) for the sample without the spin-converter Cu/C60 interface is shown in Fig. 4d. There is a reduction in the internal field arising from the conventional Meissner effect as the sample is cooled through the critical temperature. For muons probing the Nb layer (20 keV), the Meissner effect results in a 2.41 ± 0.08 G reduction of the internal field going from 10 K to 2.7 K. When probing the Au layer at 9 keV, the internal field at 2.7 K shows a 0.21 ± 0.08 G reduction, consistent with the presence of even-frequency superconducting correlations in this region. See Supplementary Note 3 for the depolarisation dependence of the LE-μSR vs. temperature (Fig. S5).
We can simulate the \(\langle B\rangle (T)\) data at 20 keV using a quasi-classical (Q–C) framework. Here, spin-singlet superconducting correlations are described by Green functions. In the dirty limit, these Green functions satisfy the Usadel equation45,49. Within this framework, interfacial boundary conditions are imposed between the normal conductor (N) and superconductor (S) layer50. Once the Green functions are determined, we apply the linear response theory to calculate the screening current (and thus \(\langle B\rangle(T)\)) in response to small externally applied field – see Supplementary Note 5. The density of states of the Nb layer, tuned to achieve the flux expulsion measured at the lowest temperature, equates to a \(\lambda _0\) of 144 nm (S model). However, this simple model cannot replicate the B/BN (T) trend in the S/M/N system. Instead, we assume that the suppressed Tc observed in Fig. 2 is due to proximity-induced superconductivity in the C60 layer, this reduces the order parameter, \({{\Delta }}\), toward the Nb/C60 interface. We find then a density of states equating to a \(\lambda _0\) of 94 nm and a near-linear B (T) trend that fits well the experimental data – see Fig. 4d.
Figure 4f shows the temperature dependence of \(\langle B(E)\rangle/B_ {\mathrm{N}}\) for the sample with the spin-converter Cu/C60 interface. The reduction in the local field in the Nb film at 20 keV is less than half of what was observed in the control: 1±0.1 G at 2.7 K. The 9 keV measurements probing the Au layer now show a paramagnetic signal of 0.3 ± 0.1 G at 2.7 K. This sample also shows an anomalous temperature dependence of the Meissner effect, very different to the Q-C calculations. The Supplementary Note 5 explains further the Q-C simulation of the flux expulsion in Nb/C60/Au structures, see Fig. S6. The Tc of this sample is comparable to the control sample without Cu (Tc ~ 8.7 K), but there is not an immediate reduction in the local field below Tc as would be expected. Instead, \(\langle B(E)\rangle\) in Nb (20 keV) is only reduced w.r.t. the normal state once the sample is below 6 K (~0.7 Tc). The conversion of even-frequency superconducting correlations into odd-frequency correlations at the spin-converter Cu/C60 interface has given rise to a suppressed diamagnetic Meissner response in the niobium layer and a paramagnetic supercurrent in the Au layer, consistent with a majority odd-frequency pair density residing in this region of the heterostructure51,52,53,54,55.
A paramagnetic signal may arise due to other phenomena, such as instabilities brought about by \(\pi\)-states formed at superconductor/non-magnetic interfaces or inhomogeneities in the superconductor lattice56,57. Locally pinned flux in mesoscopic superconducting systems has produced an observable paramagnetic screening signal due to sample morphology58,59,60. In our experiments, our range of control samples rules out these paramagnetic contributions, as all samples share the same superconductor/molecular interface with consistent morphologies confirmed by XRR and TEM. Moreover, pinned flux or orbital paramagnetism in the near-surface region of the Nb layer would lead to a broadening of the field distribution below Tc. Should these phenomena be prevalent in our systems, we would expect a significant increase in the muon depolarisation rate below Tc for the spin-converter sample. As can be seen in the Supplementary Notes 3 and 5, this is not the case. Additionally, our choice of a 300 G transverse field should sufficiently quench the orbital paramagnetism possible at superconductor/non-magnetic interfaces61. Rather, the paramagnetic screening we observe that is concentrated in the Au layer is most likely the result of triplet correlations extending into this layer. Supplementary Note 6 and Fig. S7 show the field dependence of the spin susceptibility at 120 G and 300 G for different muon energies in the multi-probe sample.
Conclusions
The results presented here demonstrate that in thin-film form, superconducting correlations can be mediated across a molecular C60 layer of sufficiently small thickness. We suggest that changes to the C60 electronic structure, brought about by interfacial hybridisation and charge transfer, may allow for this proximity to manifest. With the addition of a spin-converter metallo-molecular interface, a reproducible paramagnetic screening response was observed by LE-µSR due to the conversion of spin-singlet Cooper pairs to of odd-frequency spin-triplet states at the magnetic Cu/C60 interface. The anomalous response of the sample flux profile in the superconducting state to both temperature and magnetic field provides a compelling case for the presence of unconventional superconducting states present in a hybrid metal/molecule superconducting system. A spin-selective ferromagnetic layer could be used in conjunction with the spin converter interface to generate the SZ= 1 long-range spin-triplet. The triplet filtering can be used for super-spintronics or in coherence and interferometry applications62,63. Given that the metallo-molecular interface charge transfer and interactions can be controlled via electrical or optical irradiation, this opens further avenues of research to produce, switch and control odd-frequency superconducting correlations for quantum computing in an intrinsically non-magnetic and non-superconducting system.
Methods
Thin film growth and characterisation
Metallic films were grown by DC magnetron sputtering, while C60 molecular films were thermally sublimed in situ at 450 °C. Deposition of all sample layers was performed under UHV with a base pressure of 10−8 Torr and partial pressure of oxygen of 10−10 Torr. Sputtering was performed in an Ar atmosphere at 2.4 Torr from targets with purities of Nb(99.999%), Cu(99.9999%) and Au(99.99%). Growing the heterostructure in this way leads to nanocrystalline C60 layers and polycrystalline metallic films64. The growth rate for these materials was calibrated by the fitting of Kiessig fringes measured by XRR. The NR data was obtained using the PolRef beamline at the ISIS Neutron and Muon Source, UK65.
Low-energy muon spin rotation analysis
For this study, two sets of samples were fabricated and measured on the µE4 beamline at the Paul Scherrer Institute, Switzerland66. Characterisation measurements were performed on ‘sister samples’ grown at the same time as the LEM samples but on 4 × 4 mm2 substrates, suitable for the SQUID VSM, and low-temperature measurements. The Ginzburg-Landau (GL) coherence length at 0 K, \(\xi _{ {\mathrm{GL}}}\), for the Single-Probe samples, was extracted using the following relationship;
where \(\phi _0\) is the flux quantum and \(H_{{\mathrm{C}}2 \bot }\left( T \right)\) is the out of plane critical field.
Samples used for LEM measurements are grown on 20 × 20 mm2 substrates which reduces the associated count time. The time-dependent polarisation (\(P\left( t \right)\)) of the muon can be described by
to yield the local field \(\langle B\rangle(E)\), depolarisation rate (\(\lambda _{{\mathrm{TF}}}\)), asymmetry (\(A_{\mu ^ + }\)) and phase (\(\varphi\)).\(\gamma _\mu\) is the gyromagnetic ratio of the muon. \(\varphi\) is the starting phase of the μ+ spin polarisation at time t = 0; this initial μ+ spin polarisation depends on the time of flight of the muon in the fringe field of the magnet, which in turn depends on the implantation energy. \(A_{\mu ^ + }\) will also be energy-dependent as it parametrises the magnitude of the μ+ precession signal. For implantation energies where a more significant proportion of the muons thermalise within C60, a reduction in \(A_{\mu ^ + }\) would be expected due to the formation of muonium. As both parameters are verified to be independent of temperature, they can be fixed at the value obtained in the normal state for each implantation energy. Therefore, only \(\langle B\rangle(E)\) and \(\lambda _{{\mathrm{TF}}}\) are affected by the onset of screening currents within the heterostructure.
Following on from the London equation, the expected flux profile (\(B(x)\)) within the superconductor is given by
where \(x\) is the position within the superconducting film, \(x = 0\) corresponds to the top surface of the Nb layer. \(d_{\mathrm{s}}\) is the Nb thickness. \(\lambda \left( T \right)\) is the temperature-dependent penetration depth and \(B_N\) is the flux outside the superconductor, which in this case, has been obtained from the normal state measurement at 10 K45. All data presented is publically available67.
Data availability
The data that support the findings of this study are available from https://doi.org/10.5518/852. The neutron reflectivity data are available from https://doi.org/10.5286/ISIS.E.RB1820617.
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Acknowledgements
This work was supported by EPSRC grant nos. EP/S030263/1, EP/M000923/1 and EP/K00512X/1. Experiments performed at the ISIS Pulsed Neutron and Muon Source were supported by a beamtime allocation from the Science and Technology Facilities Council experiment number RB 1820617. PSI LEM beamtime access via proposal IDs 20161840, 20171184 and 20190352.
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M.R. fabricated the samples, carried out transport, X-ray and neutron reflectivity, magnetometry and LE-µSR measurements and wrote the manuscript. A.W. grew samples and performed TEM measurements with the aid of the Leeds Electron Microscopy and Spectroscopy Centre. F.A.M., M.G.F., S.Lee, R.S., H.B. and T.P. contributed to the LE-µSR measurements and analysis. A.J.C., C.J.K and S.Langridge contributed to the neutron reflectivity measurements and analysis. T.M., M.A., G.B. and B.J.H. contributed toward the sample design, instrumentation and data analysis. O.C. was responsible for the project planning, contributed to the experimental work, supervised and managed the work.
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Rogers, M., Walton, A., Flokstra, M.G. et al. Spin-singlet to triplet Cooper pair converter interface. Commun Phys 4, 69 (2021). https://doi.org/10.1038/s42005-021-00567-7
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DOI: https://doi.org/10.1038/s42005-021-00567-7
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