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1. Odd-parity quasiparticle interference in the superconductive surface state of UTe2

   https://doi.org/10.1038/s41567-025-03000-w  

   Wang, Shuqiu; Zhussupbekov, Kuanysh; Carroll, Joseph P; Hu, Bin; Liu, Xiaolong; Pangburn, Emile; Crepieux, Adeline; Pepin, Catherine; Broyles, Christopher; Ran, Sheng; et al (October 2025, Nature Physics)

   Abstract Although no known material exhibits intrinsic topological superconductivity, where a spin-triplet electron pairing potential has odd parity, UTe₂is now the leading candidate. Generally, the parity of a superconducting order parameter can be established using Bogoliubov quasiparticle interference imaging. However, odd-parity superconductors should support a topological quasiparticle surface band at energies within the maximum superconducting energy gap. Quasiparticle interference should then be dominated by the electronic structure of the quasiparticle surface band and only reveal the characteristics of the bulk order parameter indirectly. Here we demonstrate that at the (0–11) cleave surface of UTe₂, a band of Bogoliubov quasiparticles appears only in the superconducting state. Performing high-resolution quasiparticle interference measurements then allows us to explore the dispersion of states in this superconductive surface band, showing that they exist only within the range of Fermi momenta projected onto the (0–11) surface. Finally, we develop a theoretical framework to predict the quasiparticle interference signatures of this surface band at the (0–11) surface. Its predictions are consistent with the experimental results if the bulk superconducting order parameter exhibits time-reversal conserving, odd-parity,a-axis nodal,B_3usymmetry. 

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2. Circuit quantum electrodynamics detection of induced two-fold anisotropic pairing in a hybrid superconductor–ferromagnet bilayer

   https://doi.org/10.1038/s41567-024-02613-x  

   Bøttcher, C_G L; Poniatowski, N R; Grankin, A; Wesson, M E; Yan, Z; Vool, U; Galitski, V M; Yacoby, A (October 2024, Nature Physics)

   Abstract Hybrid systems represent one of the frontiers in the study of unconventional superconductivity and are a promising platform to realize topological superconducting states. These materials are challenging to probe using many conventional measurement techniques because of their mesoscopic dimensions, and therefore require new experimental probes so that they can be successfully characterized. Here, we demonstrate a probe that enables us to measure the superfluid density of micrometre-size superconductors using microwave techniques drawn from circuit quantum electrodynamics. We apply this technique to a superconductor–ferromagnet bilayer and find that the proximity-induced superfluid density is two-fold anisotropic within the plane of the sample. It also exhibits power-law temperature scaling that is indicative of a nodal superconducting state. These experimental results are consistent with the theoretically predicted signatures of induced triplet pairing with a nodalp-wave order parameter. Moreover, we observe modifications to the microwave response at frequencies near the ferromagnetic resonance, suggesting a coupling between the spin dynamics and induced superconducting order in the ferromagnetic layer. Our experimental technique can be employed more widely, for example to study fragile unconventional superconductivity in low-dimensional materials such as van der Waals heterostructures. 

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3. Strong electron–phonon coupling in magic-angle twisted bilayer graphene

   https://doi.org/10.1038/s41586-024-08227-w  

   Chen, Cheng; Nuckolls, Kevin P; Ding, Shuhan; Miao, Wangqian; Wong, Dillon; Oh, Myungchul; Lee, Ryan L; He, Shanmei; Peng, Cheng; Pei, Ding; et al (December 2024, Nature)

   Abstract The unusual properties of superconductivity in magic-angle twisted bilayer graphene (MATBG) have sparked considerable research interest^1–13. However, despite the dedication of intensive experimental efforts and the proposal of several possible pairing mechanisms^14–24, the origin of its superconductivity remains elusive. Here, by utilizing angle-resolved photoemission spectroscopy with micrometre spatial resolution, we reveal flat-band replicas in superconducting MATBG, where MATBG is unaligned with its hexagonal boron nitride substrate¹¹. These replicas show uniform energy spacing, approximately 150 ± 15 meV apart, indicative of strong electron–boson coupling. Strikingly, these replicas are absent in non-superconducting twisted bilayer graphene (TBG) systems, either when MATBG is aligned to hexagonal boron nitride or when TBG deviates from the magic angle. Calculations suggest that the formation of these flat-band replicas in superconducting MATBG are attributed to the strong coupling between flat-band electrons and an optical phonon mode at the graphene K point, facilitated by intervalley scattering. These findings, although they do not necessarily put electron–phonon coupling as the main driving force for the superconductivity in MATBG, unravel the electronic structure inherent in superconducting MATBG, thereby providing crucial information for understanding the unusual electronic landscape from which its superconductivity is derived. 

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4. Superconducting States and Intertwined Orders in Metallic Altermagnets

   Zou, Xuan; Fernandes, Rafael M; Fradkin, Eduardo (March 2026, ArXiV)

   Altermagnets are a newly identified class of magnets with nodal spin-split band structures, providing a fertile platform for studying unconventional superconductivity and intertwined orders. Here we investigate multicomponent superconductivity and fluctuation-induced intertwined orders in an interacting -wave metallic altermagnet that is invariant under a combination of a fourfold rotation $$C_4$$ and time-reversal symmetry $$T$$ . Within mean-field theory, the superconducting ground-state manifold is described in terms of two equal-spin two-component p-wave gap functions $$(\Delta_A^x,\Delta_B^y)$$ and $$(\Delta_A^y,\Delta_B^x)$$, where $$A$$ and $$B$$ refer to the two spin-polarized Fermi surfaces related by symmetry. Because these two sets of gap functions condense at different temperatures, a rich phase diagram with multiple superconducting phase transitions emerges. Distinct fluctuations of sub-leading normal-state instabilities that compete with altermagnetism lift the degeneracy of the multicomponent pairing state in different ways. While nematic fluctuations enhance competition between distinct superconducting components and stabilize nematic superconducting phases, spin current-loop fluctuations promote coexistence and select a pair of chiral states. Our results uncover the pairing structure and elucidate how intertwined sub-leading fluctuations shape superconducting order in altermagnetic metals, suggesting a route toward realizing nematic and topological superconductivity. 

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5. Superconducting States and Intertwined Orders in Metallic Altermagnets

   Zou, Xuan; Fernandes, Rafael M; Fradkin, Eduardo (March 2026, Physical Review B)

   Altermagnets are a newly identified class of magnets with nodal spin-split band structures, providing a fertile platform for studying unconventional superconductivity and intertwined orders. Here we investigate multicomponent superconductivity and fluctuation-induced intertwined orders in an interacting -wave metallic altermagnet that is invariant under a combination of a fourfold rotation $$C_4$$ and time-reversal symmetry $$T$$ . Within mean-field theory, the superconducting ground-state manifold is described in terms of two equal-spin two-component p-wave gap functions $$(\Delta_A^x,\Delta_B^y)$$ and $$(\Delta_A^y,\Delta_B^x)$$, where $$A$$ and $$B$$ refer to the two spin-polarized Fermi surfaces related by symmetry. Because these two sets of gap functions condense at different temperatures, a rich phase diagram with multiple superconducting phase transitions emerges. Distinct fluctuations of sub-leading normal-state instabilities that compete with altermagnetism lift the degeneracy of the multicomponent pairing state in different ways. While nematic fluctuations enhance competition between distinct superconducting components and stabilize nematic superconducting phases, spin current-loop fluctuations promote coexistence and select a pair of chiral states. Our results uncover the pairing structure and elucidate how intertwined sub-leading fluctuations shape superconducting order in altermagnetic metals, suggesting a route toward realizing nematic and topological superconductivity. 

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