Observation of a superconducting glass state in granular superconducting diamond

Abstract

The magnetic field dependence of the superconductivity in nanocrystalline boron doped diamond thin films is reported. Evidence of a superconducting glass state is presented, as demonstrated by the observation of a quasi de Almeida-Thouless line in the phase diagram and a logarithmic time dependence of the magnetism. The position of the phase boundary in the H-T plane is determined from electrical transport data by detailed fitting to quasi-zero-dimensional fluctuation conductivity theory. This allows determination of the boundary between resistive and non-resistive behaviour to be made with greater precision than the standard ad hoc onset/midpoint/offset criterion. We attribute the glassy superconductivity to the morphological granularity of the diamond films.

Introduction

The experimental observation of a proposed superconducting glass state was first made by Müller, Takashige and Bednorz in powder samples of La₂CuO_4−y:Ba¹. The authors noted the existence of frustration in granular systems that gives rise to a “superconductive glass” that is equivalent to an XY spin-glass², demonstrating the existence of degenerate states. In line with the essential features of the analogous spin-glass system, the authors reported a logarithmic decay of the remanent magnetization, and an irreversibility line–the boundary in the H-T plane between reversibility and irreversibility in magnetization–which obeyed $H_{irr}\propto {(1-T/T_c)}^{3/2}$. This observed power law of the irreversibility line was likened to the de Almeida-Thouless line which separates the metastable and stable regions of the phase diagram in related models of spin-glasses³.

Similar behaviour regarding the irreversibility line and magnetic relaxation was subsequently observed in single crystal Y-Ba-Cu-O, and an alternative interpretation was proposed by Yeshurun and Malozemoff in the form of a thermally activated flux-creep model⁴. Tinkham extended this work and proposed a phenomenological model that included the effects of pinning and reproduced the observed power law⁵. Other theories purporting to explain the form of the irreversibility line in this kind of superconductor include vortex-lattice melting⁶ and the existence of a disordered vortex glass^7–9 state arising from random pinning sites. Importantly, these competing theories share in common the idea of a randomly varying superconducting order parameter, leading to a ubiquitous 3/2 power law in the irreversibility line. We will therefore refer to this behaviour as “glassy superconductivity” without concern for the details of any specific theory.

Whilst the majority of reports of irreversible magnetic behaviour have focused on high-T_c compounds, Oppermann¹⁰ has pointed out that the signatures of a glassy state should also be expected in the vicinity of a metal-insulator transition, in both low- and high-T_c materials. Additionally, the existence of an irreversibility line has been studied in low-T_c type II materials such as Nb₃Sn and Nb-Ti¹¹, Nb¹², MgB₂¹³, PbMo₆S₈ and Ba_0.25Pb_0.75BiO₃¹⁴. The irreversible behaviour in these metallic films has mainly been attributed to flux lattice melting.

In this paper, we describe the measurement of the magnetic field dependence of superconductivity in boron doped nanocrystalline diamond (BNCD) films, where the granularity may be controlled by the film thickness. We have found evidence of glassy superconductivity in the phase diagram, which we have confirmed with electrical resistivity and magnetic relaxation measurements. We observe a quasi de Almeida-Thouless-type line in H_irr(T), and confirm the proposed glassy superconductivity by observing a logarithmic decay of magnetism over time. This glassy dynamics can be attributed to frustration in a system of weakly coupled superconducting clusters, each of which acts as an individual $U(1)\cong O(2)$ spin². The BNCD films studied here have a granular morphology^15–18 similar to sintered powders, and are close to a metal-insulator transition^19–21, so that the observation of glassy superconductivity is perhaps not surprising. Nonetheless, this is a novel observation in BNCD films, made possible by detailed analysis of dimensional crossover in fluctuation conductivity¹⁸–fluctuation spectroscopy–which allows us to probe material properties that are governed by the morphological granularity of our films.

Results

Electrical resistance

Figure 1 displays the resistance as a function of temperature measured in an applied magnetic field in the range 0–4 T with field increments of 0.2 T. Closely spaced field increments of 0.02T (not shown in Fig. 1 for clarity, but present in Fig. 2) were also used below 0.2 T.

Figure 1.

Resistance as a function of temperature for applied magnetic fields in the range 0–4 T in 0.2 T increments. Fit lines (solid) through the data follow the analysis technique discussed in the text.

Figure 2.

Magnetic field as a function of transition temperature for a 564 nm thick BNCD film. Inset: rescaled H(T) clearly showing the H^2/3 power law behaviour.

We are able to make a very precise determination of T_c in these films by fitting to the resistance data using our understanding of the fluctuation conductivity. In a previous work¹⁸, we have shown that the fluctuation contribution to the conductivity - that is the conductivity due to finite-lifetime Cooper pairs above T_c - exhibits a dimensional cross-over into a quasi-zero-dimensional regime. In the approach to the transition, this diverges as σ_fl ~ (T − T_c)⁻³, in confirmation of a prediction by Lerner et al.²². In this region, the leading contribution to σ_fl comes from the lowest eigenvalue of the diffusion operator, −D∇², inside the Cooper pair propagator for a single grain. In the presence of a magnetic field, this operator becomes $-D{(\nabla +2ie\mathbf{A}/\hslash )}^2$, and its lowest eigenvalue increases as a function of magnetic field. This correction to the pair propagator has the sole effect of reducing the transition temperature as a function of magnetic field, T_c(H), so that σ_fl ~ (T − T_c(H))⁻³.

We first extract the fluctuation conductivity from the resistance data by subtracting the normal state conductivity, which has the form ${\sigma }_{\mathrm{n}}=a+b\sqrt{T}$. Then, to determine T_c, we fit the fluctuation conductivity to the quasi-zero-dimensional power law model, σ_fl ~ (T − T_c)⁻³. This form holds for the widest part of the superconducting transition and allows us to obtain T_c as the single fitting parameter. After finding T_c, we then further analyse the temperature dependence of the fluctuation conductivity, and observe two crossovers into three-dimensional intragrain and intergrain regions, both characterised by a σ_fl ~ (T − T_c)^−1/2 behaviour. The experimental R(T) curves can be well fitted using only the quasi-zero-dimensional dependence, σ_fl ~ (T − T_c)⁻³, since this is valid for the widest part of the resistive transition.

The fitting of T_c(H) using fluctuation conductivity is significantly more accurate than determining critical behaviour through the more common onset-midpoint-offset (90%–50%–10%) criterion¹³. Indeed, each R(T) trace in Fig. 1 is displayed along with the associated fit line, which shows an excellent agreement between the theoretical prediction and the experimental data. This agreement between theory and experiment strongly suggests that the broadening of the transition really is due to superconducting fluctuations rather than some other broadening effect coming from a distribution of local critical temperatures.

The resulting field induced transition temperature is shown in Fig. 2. It has been shown that this can be interpeted as the irreversibility line, H_irr(T)^11,14,23,24; as the magnetization becomes reversible, a zero voltage state is no longer supported, and a finite resistance is measured. Initially, at the higher temperature end of Fig. 2, there is a clear upturn in the H_irr(T) curve, which closely follows the quasi de Almeida-Thouless H^2/3 power law, as shown more clearly in the inset.

An important observation from the theory of Lerner et al.²² on which our theory is based is that for granular systems there are two distinct coherence lengths which must be considered; the coherence length associated with a Cooper pair which straddles a grain boundary through tunneling, ξ_t, and that for a Cooper pair contained within a single grain, ξ_g. These are related to the single-crystal diffusion constant, D, and the bulk effective diffusion constant, D_eff, through the standard formula (see Varlamov et al.²⁵ for example) ${\xi }_g=\sqrt{\pi \hslash D/8k_B{T}_c}$ and ${\xi }_t=\sqrt{\pi \hslash D_{\mathrm{eff}}/8k_B{T}_c}$. In our previous paper we used the location of cross-overs in the R(T) trace to estimate D ≈ 12 cm²/s and D_eff ≈ 0.6 cm²/s, which are comparable to measurements by more standard means. Based on these numbers we determine ξ_g ≈ 30 nm and ξ_t ≈ 7 nm. If we use the effective coherence length ξ_t to estimate the upper critical field using the standard formula $H_{c2}={\mathrm{\Phi }}_0/2\pi {\xi }^2$ we find an order of magnitude estimate 6.7 T which is comparable with estimates for similar samples¹⁹.

Magnetic relaxation

We believe that we are in a regime where we observe glassy superconductivity in this system. To further explore this, we have also measured the relaxation of the magnetization, and observed the logarithmic decay that is expected from the analogous frustrated model.

The procedure for measuring the magnetic relaxation described by Yeshurun, Malozemoff and Shaulov²⁶ was followed. The sample was cooled to the measurement temperature in zero applied field. A magnetic field smaller than the irreversibility field, but larger than the minimum sample magnetization, was then applied, followed by a step decrease that ensured a reversal of the flux profile. The values of these fields were determined by measurement of a magnetic hysteresis loop at the appropriate temperature. The magnetic moment was then monitored as a function of time by vibrating sample magnetometry, where the amplitude of sample translation was minimised to avoid possible field inhomogeneity.

The normalised magnetic relaxation at 2.2 K is shown in Fig. 3. For this measurement, after cooling in zero field, an initial applied field of 97 Oe was followed by a step decrease to 33 Oe. The red line is a linear fit to lnM as a function of lnt, which we later use to estimate the logarithmic derivative of the magnetic moment. We observe a logarithmic decay of the magnetic moment as expected for the analogous frustrated model to which we liken the observations.

Figure 3.

Magnetic relaxation measured at 2.2 K for a 564 nm thick BNCD film. The red line shows a linear fit of lnM versus lnt, performed after 1 minute to minimise the effect of instrumental transients. Similar logarithmic decay is observed over a range of temperatures up to T_c.

The normalized time-logarithmic slope of the magnetization, $S=-d\ln M(t)/d\ln t$, is plotted as a function of temperature in Fig. 4. We observe the appearance of a plateau region for which S is stable at around 0.020–0.035. This is highly noteworthy because a universal plateau, with S in precisely this range of values, is observed in a number of experiments in Y-Ba-Cu-O and was explained by Malozemoff and Fisher²⁷ as an effect of a vortex glass phase. An analogous plateau in S can be seen in other high temperature superconductors such as SmFeAsO_0.9F_0.1²⁸ or ceramic (Bi, Pb)-2223²⁹. At first sight it may seem odd that a universal feature associated with high temperature superconductors should be found also in diamond, a low temperature superconductor. However, the explanation put forward by Malozemoff and Fisher does not rely on the system in question being at high temperatures, but only on the existence of a dense environment of random pinning centres. The latter should certainly occur in any granular superconductor, including the BNCD films we consider here.

Figure 4.

Normalized time-logarithmic slope of the magnetization, S = −dlnM(t)/dlnt, for a 564 nm thick BNCD film as a function of temperature.

Discussion

Generally, reports of the field dependence of the resistive transition in BNCD to date have shown that the transition width broadens with applied magnetic field; the onset of the superconductivity has been shown to be less sensitive to the field than the lower temperature tail in the resistance that grows with increasing field^30–32. Scanning tunnelling microscopy of CVD-grown BNCD films well below T_c has shown that the temperature dependence of the energy gap in polycrystalline³³ and epitaxial³⁴ boron doped diamond samples both broadly agree with BCS-like superconductivity. In BNCD films, a strong correlation between the local superconductivity and the granular structure has been shown, with the plane of the grain boundaries approximately in the direction of film growth³³. The energy gap showed a smooth variation across a grain, which is believed to be indicative of slowly varying doping concentration. The grain boundaries, however, are reported as having predominantly metallic-like conductance. It is therefore appropriate to consider our BNCD sample as a disordered collection of coupled superconducting grains. We thus interpret the results presented here as likely being due to a superconducting glass arising from frustration in a model of weakly linked superconducting clusters, as described by Ebner and Stroud².

The samples studied here are not unique in terms of the existence of a quasi de Almeida-Thouless line in the H(T) diagram; there is some evidence in the literature that other BNCD samples show similar behaviour under the influence of a magnetic field^19,30,31,35, but this feature has never before been investigated in detail. While discussion of, and experiments pertaining to, glassy states in superconductors are common for high-T_c compounds, they are also expected to be observable in granular materials, or materials near the metal-insulator transition¹⁰. The BNCD samples studied here fall into both of these categories, and so it is perhaps unsurprising that this glassy behaviour manifests itself here. Indeed, evidence for a vortex glass ground state has recently been reported in amorphous indium oxide films³⁶, a similarly strongly disordered low T_c superconductor.

As an important side-note, it is common practice throughout the literature to calculate the coherence length in films such as these by comparing the H(T) curve to the Werthamer-Helfand-Hohenberg (WHH) theory³⁷ of the upper critical field^31,38. According to WHH theory, the H(T) curve should be linear near to T_c, which is evidently not the case in samples displaying this glassy behaviour due to the curvature of the quasi de Almeida-Thouless line. It follows that fitting to WHH theory may not be a reliable way to determine the coherence length, and studies doing this may need to be reconsidered.

Finally, the signature of glassy superconductivity observed here has potential consequences for the use of BNCD in low temperature device engineering. The high Young’s modulus of diamond–even in the form of nanocrystalline films³⁹–makes it a good candidate for the fabrication of high frequency nanoelectromechanical resonators with which to study the fundamentals of quantum mechanics in a macroscopic object^40,41. Recently, an anomalous temperature dependence of the dissipation in a superconducting nanoresonator was observed, and was suggested to arise from the dynamical vortex behaviour below T_c⁴². It is possible, therefore, that careful measurement of the temperature-dependent dissipation of a glassy superconducting nanoresonator⁴³ would show complementary behaviour to that observed in this study.

Conclusions

We have examined the magnetic field dependence of superconductivity in BNCD films. By determining the dependence of the transition temperature on increasing magnetic field, we have shown that the irreversibility field has the behaviour H_irr(T) ∝ (1 − T/T_c)^3/2. This observed power law, coupled with a logarithmic decay of the remanent magnetization, is attributed to a superconducting glass state resulting from the morphological granularity of our BNCD samples.

Methods

The BNCD film was grown on a 2″ diameter, 500 nm SiO₂-buffered (100) silicon wafer by microwave plasma assisted chemical vapour deposition⁴⁴. A dense population of nucleation sites on the substrate was obtained by ultrasonification in a monodisperse aqueous colloid of 5 nm diameter nanodiamond particles⁴⁵, which has been shown to be essential in the production of uniform and fully coalesced nanodiamond films. During growth, the temperature of the substrate was maintained at ~720 °C by a plasma composed of 3% methane in hydrogen, with trimethylboron as the source of boron (B/C ratio of 12800 ppm). The chamber pressure was 40 Torr and the microwave power was 3.5 kW. The carrier concentration is estimated to be >1 × 10²¹ cm⁻³, with an upper limit of 2.3 × 10²¹ cm⁻³ assuming a 100% incorporation efficiency from the gas phase. The results presented in this paper focus on a BNCD film shown by scanning electron microscopy to have a thickness of 564 nm and a mean grain diameter of 102 ± 24 nm, though other sample thicknesses show a qualitatively similar behaviour. The estimated surface roughness is approximately 45 nm RMS. In previous work, we have shown that the shape and magnitude of the superconducting transition is unaffected by the surface roughness of the film as controlled through chemical mechanical polishing⁴⁶.

All temperature dependent measurements relating to the magnetic field dependence of the superconductivity were made using a Quantum Design physical property measurement system. Resistance measurements were performed using silver paste contacts made to the sample surface in a four-wire Van der Pauw configuration. Vibrating sample magnetometry was used to measure the magnetization. All measurements were made with the magnetic field applied perpendicularly to the sample plane.

Author Contributions

G.M.K. conceived of the experiment and performed the transport measurements. G.M.K., J.M.W. and S.R.G. performed the magnetic relaxation measurements, S.M. grew the BNCD sample, J.M.F. and R.A.S. developed the theory to analyse the data, J.M.F. performed the data analysis, and S.R.G. and O.A.W. directed the project. G.M.K. and J.M.F. wrote the manuscript and it was reviewed by all authors.

Competing Interests

The authors declare no competing interests.