Andrea Cavalleri

Re-entrant unconventional superconductivity induced by rare-earth substitution in Nd1-xEuxNiO2 thin films

Nature Communications Springer Nature (2026)

Authors:

Dung Vu, Hangoo Lee, Daniele Nicoletti, Wenzheng Wei, Zheting Jin, Dmitry V Chichinadze, Michele Buzzi, Wenxin Li, Xinhao Yang, Rongting Wu, Christopher A Mizzi, Tiema Qian, Boris Maiorov, Alexey Suslov, Yu He, Cyprian Lewandowski, Sohrab Ismail-Beigi, Frederick J Walker, Andrea Cavalleri, Charles H Ahn

Abstract:

High temperature superconductivity is typically associated with strong coupling and a large superconducting gap, yet these characteristics have not been demonstrated in the nickelates. Here, we provide experimental evidence that Eu substitution in the spacer layer of Nd1-xEuxNiO2 (NENO) thin films enhances the superconducting gap, driving the system toward a strong-coupling regime. This is accompanied by a magnetic-exchange-driven magnetic-field-enhanced superconductivity. We investigate the upper critical magnetic field, Hc2, and the superconducting gap of superconducting NENO thin films with x = 0.2 to 0.35. Magnetoresistance measurements reveal magnetic-field-enhanced superconductivity in NENO films. We interpret this phenomenon as a result of an interaction between magnetic Eu ions and superconducting states in the Ni dx2-y2 orbital. The upper critical magnetic field strongly violates the weak-coupling Pauli limit. Infrared spectroscopy confirms a large gap-to-Tc ratio 2Δ/kBTc≃5−6$$2\Delta /{k}_{B}{T}_{{\rm{c}}}\simeq 5-6$$, indicating a stronger coupling pairing mechanism in NENO relative to the Sr-doped NdNiO2. The substitution of Eu in the rare-earth layer causes pronounced modifications of the superconducting gap and magnetic interactions in Nd-based nickelates, opening new pathways to engineer high-Tc superconductivity in infinite-layer nickelates.

Cavity-altered superconductivity

Nature Springer Nature 650:8103 (2026) 864-868

Authors:

Itai Keren, Tatiana A Webb, Shuai Zhang, Jikai Xu, Dihao Sun, Brian SY Kim, Dongbin Shin, Songtian S Zhang, Junhe Zhang, Giancarlo Pereira, Juntao Yao, Takuya Okugawa, Marios H Michael, Emil Viñas Boström, James H Edgar, Stuart Wolf, Matthew Julian, Rohit P Prasankumar, Kazuya Miyagawa, Kazushi Kanoda, Genda Gu, Matthew Cothrine, David Mandrus, Michele Buzzi, Andrea Cavalleri, Cory R Dean, Dante M Kennes, Andrew J Millis, Qiang Li, Michael A Sentef, Angel Rubio, Abhay N Pasupathy, DN Basov

Abstract:

Is it feasible to alter the ground-state properties of a material by engineering its electromagnetic environment? Inspired by theoretical predictions1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11–12, experimental realizations of such cavity-controlled properties without optical excitation are beginning to emerge13, 14, 15, 16, 17, 18–19. Here we devised and implemented a new platform to realize cavity-altered materials. Single crystals of hyperbolic van der Waals (vdW) compounds provide a resonant electromagnetic environment with enhanced density of photonic states and prominent mode confinement20, 21, 22, 23–24. We interfaced hexagonal boron nitride (hBN) with the molecular superconductor κ-(BEDT-TTF)2Cu[N(CN)2]Br (κ-ET). The frequencies of infrared hyperbolic modes (HMs) of hBN (refs. 25,26) match the infrared-active carbon–carbon (C=C) stretching molecular resonance of κ-ET implicated in superconductivity27. Nano-optical data supported by first-principles molecular Langevin dynamics simulations confirm the presence of resonant coupling between the hBN hyperbolic cavity modes and the C=C stretching mode in κ-ET. Meissner-effect measurements using magnetic force microscopy (MFM) demonstrate a strong suppression of superfluid density near the hBN/κ-ET interface. Non-resonant control heterostructures, including RuCl3/κ-ET and hBN/Bi2Sr2CaCu2O8+x (BSCCO), do not show the pronounced superfluid suppression. These observations suggest that hBN/κ-ET realizes a cavity-altered superconducting ground state. Our work highlights the potential of dark cavities devoid of external photons for engineering electronic ground-state properties of complex quantum materials.

Broadband single-shot THz sampling using reflection gratings

Optics Express 34:1 (2026) 153-161

Authors:

C Wu, M Buzzi, A Cavalleri

Abstract:

Single-shot electro-optic sampling (EOS) is a powerful method enabling the measurement of weak terahertz signals that would otherwise require prohibitively long acquisition times. This is generally achieved by encoding the EOS time delay into a spatial, angular, or frequency coordinate. In general, angular-encoding techniques operate well up to 3 THz but become more challenging for larger bandwidths, due to dispersion and imaging imperfections. Here, we demonstrate a reliable angular-encoding single-shot EOS implementation that reaches frequencies beyond 6 THz. Diffraction simulations are used to design the experimental setup and adapt this technique to commercial reflection gratings, removing the need for custom-built echelon mirrors. Furthermore, we show that, contrary to earlier reports, group delay dispersion from angular dispersion does not reduce the bandwidth of single-shot EOS.

Tunable narrowband THz generation in the organic crystal BNA.

Optics letters 51:4 (2026) 941-944

Authors:

D Pavićević, M Nishida, J Song, M Buzzi, A Cavalleri

Abstract:

The generation of tunable narrowband pulses is increasingly being pursued in terahertz science, for example, to study the nonlinear response of individual modes of solids and molecules. Here, we extend the chirp-and-delay method to achieve collinear phase-matched difference-frequency generation in the organic crystal N-benzyl-2-methyl-4-nitroaniline (BNA-S), which results in tunable narrowband terahertz pulses. In this configuration, the fundamental frequency of a Ti:sapphire amplifier is used-eliminating the need for optical parametric amplifiers typically required for THz generation in other organic crystals. Chirped-pulse excitation suppresses multiphoton absorption in BNA, improving stability and extending crystal lifetime. The source delivers THz transients tunable from ~0.25 THz to ~2 THz with adjustable spectral width.

Signatures of three-dimensional photoinduced superconductivity in YBa2Cu3O6.48

Physical Review B American Physical Society (APS) 112:21 (2025) 214522

Authors:

M Rosenberg, D Nicoletti, M Buzzi, A Iudica, C Putzke, Y Liu, B Keimer, A Cavalleri

Abstract:

Optical excitation of large-amplitude apical oxygen phonon oscillations has been shown to renormalize the electronic properties of $\mathrm{YB}{\mathrm{a}}_2\mathrm{C}{\mathrm{u}}_3{\mathrm{O}}_{6+x}$ , inducing a superconducting-like optical response above equilibrium $T_C$ . All of the evidence collected so far has been based on the changes of the terahertz frequency $c$ -axis response. In these measurements, the capacitive interlayer coupling was seen to transform into a superconducting-like inductive response. This assignment was strengthened by recent measurements of ultrafast magnetic field expulsion. Here, we report an experimental determination of the transient in-plane optical properties, which has so far been elusive due to the high equilibrium reflectivity and the need to evaluate minute changes in the optical response. We report the appearance of a photoinduced in-plane optical gap $2\mathrm{\Delta }\simeq 30\mathrm{c}{\mathrm{m}}^{-1}$ and a divergent imaginary conductivity, both consistent with photoinduced superconductivity. A global fit to these data suggests that in- and out-of-plane electronic properties never completely equilibrate during the dynamics.