About

Professor Vidya Madhavan is a faculty member in the Physics Department at the University of Illinois Urbana-Champaign, where she holds the titles of Department Head and Donald Biggar Willett Professor in Engineering. She received her bachelor's degree in metallurgical engineering from the Indian Institute of Technology, Chennai, in 1991, and a master of technology degree in solid state materials from the Indian Institute of Technology, New Delhi, in 1993. She earned her PhD from Boston University in 2000 and completed a postdoctoral appointment at the University of California, Berkeley, from 1999 to 2002. She joined the physics faculty at Boston College in 2002 and became a full professor at Illinois in 2014. Professor Madhavan's research investigates fundamental problems in quantum materials where interactions between spin, charge, and structural degrees of freedom lead to emergent phenomena. She employs advanced tools such as scanning tunneling microscopy (STM), scanning tunneling spectroscopy (STS), spin-polarized STM (SP-STM), and molecular beam epitaxy (MBE) to explore complex systems at the atomic scale. Her group conducts high-risk, high-reward experiments with the aim of discovering new phenomena, focusing on STM studies of complex oxides, monolayer films of topological materials, and transition metal dichalcogenides. Her work has significantly contributed to understanding unconventional and topological superconductors, correlated oxides, and topological crystalline insulators, among other quantum materials.

Research topics

• Condensed matter physics
• Physics
• Quantum mechanics
• Computer Science
• Materials science
• Optoelectronics
• Nanotechnology
• Theoretical physics

Selected publications

• Visualizing the low-energy electronic structure of the triplet superconductor UTe$_2$ through quasiparticle interference

  ArXiv.org · 2026-01-05

  articleOpen accessSenior author

  The identification, control and theoretical modelling of spin-triplet superconductors (STC) remain a central theme in quantum materials research. Intrinsic STC are rare but offer rich condensate properties and unique surface properties allowing insights into the nature of the spin-triplet order, and promising applications in quantum technologies. Owing to interactions, the order parameter in STCs can often be intertwined with other symmetry breaking orders like charge/spin density waves (CDW/SDW) or pair density waves (PDW) complicating their phase diagrams. UTe2 stands out as the only known odd-parity, STC that harbors such intertwined orders on the surface and possible topological surface states composed of Majorana fermions. While the (0-11) facet is the most heavily studied, the fermiology of this surface that gives rise to such exotic phenomena is still lacking and continues to be an area of active interest. Here, we employ low-temperature spectroscopic imaging to reveal the Fermi surface of UTe2 through quasiparticle interference. We find scattering originating from the uranium-derived bands that play a major role in the formation of the CDW and the PDW phases. Tunneling spectroscopy further reveals spectral signatures of the CDW gap, corroborating its onset temperature. Suppressing the CDW with a magnetic field, highlights the presence of small, circular Fermi pockets that disperse strongly near the Fermi energy. We discuss the nature of the interference patterns and the origin of the small Fermi pockets in the context of the calculated band structure and the unconventional CDW phase.

  PublisherOA PDF

• Visualizing the low-energy electronic structure of the triplet superconductor UTe$_2$ through quasiparticle interference

  arXiv (Cornell University) · 2026-01-05

  preprintOpen accessSenior author

  The identification, control and theoretical modelling of spin-triplet superconductors (STC) remain a central theme in quantum materials research. Intrinsic STC are rare but offer rich condensate properties and unique surface properties allowing insights into the nature of the spin-triplet order, and promising applications in quantum technologies. Owing to interactions, the order parameter in STCs can often be intertwined with other symmetry breaking orders like charge/spin density waves (CDW/SDW) or pair density waves (PDW) complicating their phase diagrams. UTe2 stands out as the only known odd-parity, STC that harbors such intertwined orders on the surface and possible topological surface states composed of Majorana fermions. While the (0-11) facet is the most heavily studied, the fermiology of this surface that gives rise to such exotic phenomena is still lacking and continues to be an area of active interest. Here, we employ low-temperature spectroscopic imaging to reveal the Fermi surface of UTe2 through quasiparticle interference. We find scattering originating from the uranium-derived bands that play a major role in the formation of the CDW and the PDW phases. Tunneling spectroscopy further reveals spectral signatures of the CDW gap, corroborating its onset temperature. Suppressing the CDW with a magnetic field, highlights the presence of small, circular Fermi pockets that disperse strongly near the Fermi energy. We discuss the nature of the interference patterns and the origin of the small Fermi pockets in the context of the calculated band structure and the unconventional CDW phase.

  PublisherDOI

• Mixed Triplet-Singlet Order Parameter in Decoupled Superconducting 1H Monolayers of Transition-Metal Dichalcogenides

  ArXiv.org · 2025-09-16

  preprintOpen accessSenior author

  Understanding the emergence of unconventional superconductivity, where the order parameter deviates from simple isotropic s-wave pairing, is a central puzzle in condensed matter physics. Transition-metal dichalcogenides (TMDCs), though generally regarded as conventional superconductors, display signatures of this unusual behavior and thus provide a particularly intriguing platform to explore how exotic states arise. Here we investigate the misfit compound (SnS)$_{1.15}$(TaS$_2$), a heterostructure composed of alternating SnS and 1H-TaS$_2$ layers. Using transport, photoemission, and scanning tunneling spectroscopy, we demonstrate that the SnS layers effectively decouple the TaS$_2$ into electronically isolated 1H sheets. In this limit, the tunneling density of states reveals a clear two-gap superconducting spectrum with T$_c \sim$ 3.1 K. A theoretical model based on lack of inversion symmetry and finite-range attraction reproduces the observed multi-gap structure as a mixed singlet-triplet state. These results establish misfit compounds as a powerful platform for studying unconventional superconductivity in isolated 1H layers and for realizing multiple uncoupled superconductors within a single crystal.

  PublisherOA PDFDOI

• Roadmap on atomically-engineered quantum platforms

  Nano Futures · 2025-06-20 · 4 citations

  articleOpen accessCorresponding

  Abstract Matter at the atomic-scale is inherently governed by the laws of quantum mechanics. This makes charges and spins confined to individual atoms—and interactions among them—an invaluable resource for fundamental research and quantum technologies alike. However, harnessing the inherent ‘quantumness’ of atomic-scale objects requires that they can be precisely engineered and addressed at the individual atomic level. Since its invention in the 1980s, scanning tunnelling microscopy (STM) has repeatedly demonstrated the unrivalled ability to not only resolve but manipulate matter at atomic length scales. Over the past decades, this has enabled the design and investigation of bottom-up tailored nanostructures as reliable and reproducible platforms to study designer quantum physics and chemistry, band topology, and collective phenomena. The vast range of STM-based techniques and modes of operation, as well as their combination with electromagnetic fields from the infrared to microwave spectral range, has even allowed for the precise control of individual charge and spin degrees of freedom. This roadmap reviews the most recent developments in the field of atomically-engineered quantum platforms and explores their potential in future fundamental research and quantum technologies.

  PublisherDOI

• Dynamic competition between phason and amplitudon observed by ultrafast multimodal scanning tunneling microscopy

  ArXiv.org · 2025-07-15

  preprintOpen accessSenior author

  The intertwining between two ordered states that arise from the same interactions is reflected in the dynamics of their coupled collective excitations. While the equilibrium phase diagram resulting from such intertwined orders has been extensively studied, the dynamic competition between non-equilibrium modes is a largely unexplored territory. Here, we introduce a multimodal STM-based pump-probe technique, that combines ultrafast tunneling microscopy (USTM), ultrafast point-contact spectroscopy (UPC), and optical pump-probe reflectance (OPPR) on femtosecond timescale, all within a single instrument. Using this platform, we investigate the collective excitations of the unconventional charge density wave insulator (TaSe4)2I. Our UPC measurements reveal charge oscillations at 0.22 THz, with a temperature dependence that matches the theoretically predicted behavior of the long-sought massive phason gaining mass through the Anderson-Higgs mechanism. Unexpectedly, the data also reveals a second mode at 0.11 THz exhibiting similar temperature and polarization dependence with comparable mode intensity. These features, along with the robust 1/2 frequency ratio locking suggest that the 0.11 THz phason is a 'daughter mode' that arises from the splitting of the 0.22 THz massive phason into two massless phasons via parametric amplification, analogous to the decay of a neutral pion into two photons. Strikingly, comparison with OPPR data reveals that the daughter phason competes with and suppresses the amplitudon at proximate frequency. Our studies reveal an unexplored mechanism for the generation and extinction of collective excitations in quantum materials and pave the way for a microscopic understanding of ultrafast phenomena.

  PublisherOA PDFDOI

• Discovery of a 1D edge mode in a Magnetic Topological semimetal

  ArXiv.org · 2025-06-10

  preprintOpen accessSenior author

  In rare-earth monopnictides like NdBi, the interplay between magnetism and topology results in an extremely unusual topological semimetal phase which simultaneously hosts Weyl points with Fermi arcs as well as massive and massless Dirac cones. A central question in this class of materials is whether ferromagnetic surfaces with gapped Dirac cones can also host robust well-defined chiral edge states. In this study, we use spin-polarized scanning tunneling microscopy (SP-STM) and spectroscopy to investigate the correlation between the magnetic and topological properties of NdBi. By combining SP-STM imaging with quasiparticle interference, we identify distinct signatures of both antiferromagnetic and ferromagnetic surface terminations and correlate them with their respective band structures. Crucially, we demonstrate that step edges on the ferromagnetic surface which serve as magnetic domain walls host well-defined one-dimensional (1D) edge modes that vanish above the Néel temperature. Our findings position NdBi as a promising platform for further explorations of 1D chiral edge modes and future realizations of Majorana states in proximitized rare-earth monopnictides.

  PublisherOA PDFDOI

• Axionic tunneling from a topological Kondo insulator

  ArXiv.org · 2025-12-04

  preprintOpen access

  Discoveries over the past two decades have revealed the remarkable ability of quantum materials to emulate relativistic properties of the vacuum, from Dirac cones in graphene to the Weyl surface states of topological insulators. Yet the most elusive consequence of topology in quantum matter is the axionic $E\cdot B$ term in the electromagnetic response. Here we report a direct signature of axionic physics obtained through scanning tunneling microscopy (STM). Although recent STM experiments using SmB$_6$ nanowires have been interpreted as evidence for spin-polarized currents arising from topological surface states, we show that the observed spin polarization instead originates from axionic electrodynamics. Our analysis reveals a striking voltage-induced magnetization: extremely small voltages ($\sim$ 30 meV) generate tip moments of order 0.1 $μ_B$ that reverse sign with the applied bias. The magnitude, tunability, and reversibility of this signal are consistent with an axionic $E \cdot B$ coupling, and fully account for the magnetic component of the tip density of states, ruling out static magnetism. Millivolt-scale control of spin polarization in a tunnel junction provides a new route for probing axionic electrodynamics and opens avenues for future STM and spintronics applications.

  PublisherOA PDFDOI

• Reply to "Limitations of detecting structural changes and time-reversal symmetry breaking in scanning tunneling microscopy experiments"

  ArXiv.org · 2025-10-01

  preprintOpen accessSenior author

  In their comment, the authors attribute our observations of light- and magnetic-field-induced manipulation of the CDW state in RbV3Sb5 to random experimental artifacts such as tip changes, drift, and scan conditions, concluding that no intrinsic effect exists. In this reply, we clarify three points. First, our reported magnetic-field-induced CDW switching has been independently replicated in multiple STM studies and corroborated by transport measurements. Second, in our data, the switching of CDW intensities and Bragg vector ratios exhibit high fidelity (nearly 100 $\%$), and this cannot be explained by random artifacts. Lastly, we disprove the comment's unsubstantiated claim about magnetic field values by showing a system-dependent correlation between z-piezo shift and magnetic field. Taken together, our Reply reaffirms the reproducibility and intrinsic nature of light and magnetic field induced CDW manipulation in RbV3Sb5.

  PublisherOA PDFDOI

• Floquet–Bloch manipulation of the Dirac gap in a topological antiferromagnet

  Nature Physics · 2025-01-21 · 12 citations

  article
  PublisherDOI

• Ultrafast optical control of charge orders in kagome metals

  arXiv (Cornell University) · 2024-11-15

  preprintOpen access

  We show that ultrafast optical pump pulses provide effective control over charge orders in the kagome metals $A$V$_3$Sb$_5$ with $A=$ K, Rb, and Cs. Starting from the real charge density waves (rCDWs) at the $p$-type Van Hove singularity, we conduct a thorough analysis of the post-pump dynamics by time-dependent Hartree-Fock theory. Our analysis uncovers distinct dynamical phenomena under linearly and circularly polarized pumps. Linearly polarized pumps induce directional preferences in the rCDWs, accompanied by an enhancement in the flat band. Unexpectedly, charge nematicity also emerges and receives maximal enhancement at a resonant pump frequency, which we understand with a Rabi-oscillation-like model. On the other hand, circularly polarized pumps suppress the rCDWs uniformly and triggers imaginary CDWs (iCDWs) with charge loop currents. Our results can be directly compared to the pump-probe experiments on the kagome metals $A$V$_3$Sb$_5$.

  PublisherOA PDFDOI

Recent grants

• Emergent Physics in Correlated, Spin-orbit Coupled Materials

  NSF · $396k · 2013–2016

• CAREER: Spin-Spin Interactions, Magnetic Order and Low-Dimensional Effects in Magnetic Semiconductors: Education and Research at the Nanoscale with Spin-Polarized STM

  NSF · $520k · 2007–2013

• Nanoscale Studies of Surface Doping Effects and Superconductivity in Fe-based Superconductors and Iridates

  NSF · $450k · 2016–2019

• Quasiparticles in Mott Insulators, Strange Metals and Spin liquids probed by Low Temperature Spectroscopic-Imaging Scanning Tunneling Microscopy

  NSF · $624k · 2020–2023

• Development and nanoscale characterization of back-gated topological devices

  NSF · $360k · 2012–2016

Frequent coauthors

• Yoshinori Okada

  Okinawa Institute of Science and Technology Graduate University

  45 shared

• Daniel Walkup

  Physical Measurement Laboratory

  43 shared

• Pachamuthu Balakrishnan

  Saveetha University

  37 shared

• Zhenyu Wang

  Chinese Academy of Sciences

  35 shared

• Sunil S. Solomon

  Johns Hopkins University

  33 shared

• Michael F. Crommie

  Kavli Energy NanoScience Institute

  28 shared

• T. Jamneala

  Broadcom (United States)

  28 shared

• Hsin Lin

  26 shared

Labs

• Madhavan Research GroupPI

Awards & honors

• Nobel Laureates
• Nordsieck Award
• Davis Award
• Gary Kelly Staff Excellence Award
• Celia Mathews Elliott Prize for Writing in Science and Engin…