Abstract
The excitations responsible for producing high-temperature superconductivity in the copper oxides have yet to be identified. Two promising candidates are collective spin excitations and phonons1. A recent argument against spin excitations is based on their inability to explain structures observed in electronic spectroscopies such as photoemission2,3,4,5 and optical conductivity6,7. Here, we use inelastic neutron scattering to demonstrate that collective spin excitations in optimally doped La2−xSrxCuO4 are more structured than previously thought. The excitations have a two-component structure with a low-frequency component strongest around 18 meV and a broader component peaking near 40–70 meV. The second component carries most of the spectral weight and its energy matches structures observed in photoemission2,3,4,5 in the range 50–90 meV. Our results demonstrate that collective spin excitations can explain features of electronic spectroscopies and are therefore likely to be strongly coupled to the electron quasiparticles.
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Since their discovery, considerable progress has been made in understanding the properties of the high-critical-temperature, Tc, cuprate superconductors. We know, for example, that the superconductivity involves Cooper pairs, but with d-wave rather than the s-wave pairing of conventional Bardeen–Cooper–Schrieffer (BCS) superconductors. One outstanding issue is the pairing mechanism itself. For conventional superconductors, identifying the bosonic excitations that strongly couple to the electron quasiparticles played a pivotal role in confirming the phonon-mediated pairing mechanism8,9. In the case of the copper oxide superconductors, electronic spectroscopies such as angle-resolved photoemission (ARPES) and infrared optical conductivity measurements6,7 have revealed structures in the low-energy electronic excitations, which may reflect coupling to bosonic excitations. ARPES measurements on Bi2Sr2CaCu2O8, Bi2Sr2CuO6 and La2−xSrxCuO4 have shown rapid changes or ‘kinks’ in the quasiparticle dispersion, E(k), for energies in the range 50–80 meV (refs 2–5). These features in ARPES have been interpreted in terms of coupling to phonon modes5. However, the ARPES measurements do not distinguish between coupling to lattice and spin excitations. Identifying phonons as the strongly coupled bosons is not without its difficulties: we must explain what is special about the phonons in the cuprates; interactions with phonons do not naturally explain other important properties of the cuprates, such as the large linear temperature dependence of the normal-state resistivity at optimal doping and the origin of d-wave symmetry of the superconducting gap itself.
The interpretation of the kinks and other features in electronic spectroscopies2,3,4,5,6,7 in terms of coupling to collective spin excitations10 has been hampered by the lack of magnetic spectroscopy data. Most neutron scattering data refer to YBa2Cu3O6+x, a compound for which ARPES data are scarce. Although ARPES kinks have also been reported in La2−xSrxCuO4, comparison with neutron scattering is restricted by the fact that high-resolution studies in this compound have only been made for energies below the relevant 50–80 meV energy window11,12,13,14. At these and higher energies of relevance, only coarsely averaged data are available15, precluding a detailed comparison with electronic spectroscopies. Here, we report a high-resolution neutron scattering study of the magnetic excitations in optimally doped La2−xSrxCuO4 (x=0.16,Tc=38.5 K) designed to fill this gap in our knowledge. For our experiments, we have grown new single crystals by a floating-zone technique and assembled a sample with a total mass of 48.5 g (see the Supplementary Information). The experiments were carried out using the MAPS spectrometer at the ISIS spallation neutron source, Rutherford–Appleton Laboratory. MAPS has an order of magnitude better momentum resolution than the MARI instrument used for the previous high-energy study15.
The parent compound La2CuO4 of the La2−xSrxCuO4 superconducting series exhibits antiferromagnetic order with an ordering wavevector of Q2D=(1/2,1/2). Doping induces superconductivity and causes low-frequency incommensurate fluctuations11,12 to develop with wavevectors Q2D=(1/2,1/2±δ) and (1/2±δ,1/2). These excitations broaden13 and disperse inwards initially towards (1/2, 1/2) (ref. 14) with increasing energy.
Neutron spectroscopy provides a direct probe of the magnetic response function χ′′(Q,ω). Figure 1a–h shows wavevector-dependent images of the magnetic response at various energies demonstrating how it evolves with energy. At low energies, E=10 meV (Fig. 1a), we observe the low-energy incommensurate excitations11,12,13,14. As the energy is increased, E=18 meV (Fig. 1b), the response becomes stronger, the pattern fills in along the line connecting the nearest-neighbour incommensurate peaks and the incommensurability δ decreases. For E=25 meV (Fig. 1c), the intensity of the pattern is noticeably attenuated. On further increasing to E=41 meV (Fig. 1d), the response ‘recovers’, becoming more intense again, but is now peaked at the commensurate wavevector (1/2, 1/2). At higher energy E=90 meV (Fig. 1f), the structure resembles a square box with the corners pointing along the (110)-type directions, that is, towards the Brillouin zone centre. Thus, the square pattern is rotated 45∘ with respect to the low-energy response (for example, Fig. 1b). A similar high-energy response has been observed in underdoped YBa2Cu3O6+x (refs 16, 17) and the stripe-ordered composition La1.875Ba0.125CuO4 (ref. 18). Thus, a rotated continuum seems to be a universal feature of the cuprates.
To make our analysis quantitative, we fitted a modified lorentzian cross-section previously used to describe the cuprates and other systems19 to the data:
with
where κ(ω) is an inverse correlation length, the position of the four peaks is specified by δ, and λ controls the shape of the pattern (λ=4 corresponds to four distinct peaks and λ=0 corresponds to a pattern with circular symmetry). Further details of the experimental method and analysis are given in the Supplementary Information.
Figure 1i–p shows plots of the fitted model response for the same energies as Fig. 1a–h. Another way of displaying the results is to take constant energy cuts through our data set. Figure 2 shows cuts along the dashed trajectory in Fig. 1 for various energies together with fits of our model response (equation (1)) convolved with the experimental resolution. The good agreement between the data and fits allows us to use the parameters derived from the fits (Fig. 3) to interpret our results. To distinguish between magnetic and phonon scattering, the experiment was carried out at a number of incident energies. This means that the same in-plane momentum (h,k) could be probed with a variety of l (momentum perpendicular to plane) values and strong phonons isolated. The fact that data collected with different incident energies yield similar results confirms the validity of our analysis. We have expressed the strength of the spin fluctuations in terms of the local or wavevector-averaged susceptibility determined from the fitted cross-section. The local susceptibility, χ′′(ω), is a measure of the density of magnetic excitations for a given energy.
Figure 3a shows one of the key results of this work: the magnetic response of La1.84Sr0.16CuO4 has a two-component structure. The lower-energy peak corresponds to the incommensurate structure that is rapidly attenuated above 20 meV. The higher-energy structure is peaked at (1/2, 1/2) for E≈40–50 meV and broadens out with increasing energy above this. Although the wavevector-averaged susceptibility, χ′′(ω), of the higher-frequency component is peaked around 50 meV, it has a long tail with a measurable response at the highest energies probed (E=155 meV) in this experiment.
It is interesting to compare the present results with those obtained on La1.875Ba0.125CuO4 (ref. 18). La1.875Ba0.125CuO4 is stripe ordered with Bragg peaks corresponding to spin and charge order20 and is only weakly superconducting with Tc<6 K, whereas La1.84Sr0.16CuO4 is superconducting with Tc=38.5 K and has no observable spin or charge order. For a given energy, both compositions show broadly similar structures in their χ′′(Q,ω) patterns. The energy dependence of the response as characterized by χ′′(ω) is very different in the two compositions. La1.875Ba0.125CuO4 (ref. 18) shows a peak in χ′′(ω) centred on zero energy, which is probably connected to excitations owing to the magnetic order present in this compound. For E>15 meV, χ′′(ω) increases to a broad maximum at about 60 meV. In contrast, in La1.84Sr0.16CuO4, as E is increased from zero, χ′′(ω) rises from zero to a sharp maximum at 18 meV, followed by a dip at 25 meV and a second broader maximum at 50 meV. Above about 60 meV, both compositions show similar responses, with χ′′(ω) decreasing slowly with ω. The difference in the responses of the two materials below 60 meV is not surprising given that La1.875Ba0.125CuO4 is magnetically (and charge) ordered and therefore must have excitations reflecting this ordered state.
Given the markedly different characteristics of the two components that make up the magnetic response in La1.84Sr0.16CuO4, it is likely that they have different origins. One possible interpretation is that the lower-energy incommensurate structure is due to quasiparticle (electron–hole) pair creation, which might be calculated from an underlying band structure21,22, whereas the higher-energy structure is due to the residual antiferromagnetic interactions. It is instructive to compare the magnetic response at optimal doping with that of the antiferromagnetic parent compound La2CuO4 (ref. 23). In La2CuO4, χ′′(ω) is approximately constant over the energy range probed here (0–160 meV) with χ′′(ω)≈1.7 μB2 eV−1 f.u.−1. Thus, the effect of doping is to suppress the high-energy response (ℏω>50 meV) and enhance the response at lower frequencies, creating a double-peak structure. Figure 3c shows that the high-energy part of the response disperses with increasing energy. Constant energy cuts through the data yield two peaks (see Fig. 2) that are reminiscent of spin waves in the parent compound La2CuO4. We may use the high-energy dispersion to estimate an effective Heisenberg exchange constant, J, which quantifies the strength of the coupling between the copper spins. Using the fitted values of |δ| in Fig. 3c for E>40 meV, we estimate the gradient to be dE/dδ=510±50 meV Å. This may then be compared with the standard expression for the spin-wave velocity in a square lattice antiferromagnet, , where Zc, S and a are the quantum renormalization, spin and lattice parameter respectively. We find that the effective exchange constant for La1.84Sr0.16CuO4 is J=81±9 meV. This is substantially reduced compared with that of the parent compound La2CuO4, where J=146±4 meV (ref. 23).
We now compare our measurements of the magnetic excitations with electronic spectroscopy carried out on cuprate superconductors with the same energy scale. The energy of the 50 meV peak matches the energy range (40–70 meV) where ARPES measurements5 in the same compound La2−xSrxCuO4 show rapid changes or kinks in the quasiparticle dispersion E(k). Theory10 has no difficulty in explaining kinks and related features around the underlying Fermi surface through coupling to spin excitations that are strongest near (1/2, 1/2). In the alternative scenario where phonons are the most strongly coupled boson modes, we would expect a priori that there would be a series of kinks corresponding to different phonons. Coupling to the spin excitations seems to provide a more natural explanation for the kink, because there is a single feature in the spin excitations with the required energy scale. At higher energies, ARPES measurements suggest that the quasiparticles are coupled to bosonic excitations with energies up to at least 300 meV (ref. 24). This would match the high-energy tail of the collective spin excitations in Fig. 3a. These energies are well above the phonon cutoff of about 85 meV. Other electronic spectroscopy data are not available for La2−xSrxCuO4. However, we may make comparisons with other systems. Infrared optical conductivity measurements on YBa2Cu3O6+x (ref. 25) and Bi2Sr2Ca0.92Y0.08Cu2O8+δ (ref. 26) provide evidence of coupling to high-energy bosons in the range of the 50 meV excitations reported here. The infrared optical conductivity measurements also suggest the existence of bosons at higher energies, consistent with the present experiment. It should be noted that the magnetic excitations reported here do not seem to be related to the lattice modes recently observed by scanning tunnelling microscopy27 in Bi2Sr2CaCu2O8+δ. These lattice modes are associated with the wavevector q≈(0.2,0), rather than q≈(1/2,1/2).
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We acknowledge financial support from the EPSRC.
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Vignolle, B., Hayden, S., McMorrow, D. et al. Two energy scales in the spin excitations of the high-temperature superconductor La2−xSrxCuO4. Nature Phys 3, 163–167 (2007). https://doi.org/10.1038/nphys546
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DOI: https://doi.org/10.1038/nphys546
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