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Description
This open access book represents an outstanding contribution to the study of light matter interaction in quantum materials. It establishes that van der Waals heterostructures naturally act as terahertz plasmonic cavities, in which confined electromagnetic modes strongly couple to electronic excitations. This discovery reframes the low-energy electrodynamics of two-dimensional materials and provides a foundation for exploring cavity-mediated quantum phenomena in the solid state. Equally significant is the development of an on-chip terahertz spectroscopy platform capable of measuring the optical conductivity of gate-tunable two-dimensional materials in the near field. This experimental advance overcomes longstanding diffraction and sensitivity limits, opening new routes to probe collective excitations in micro-structured quantum material devices. This book is exemplary in its combination of conceptual depth, technical precision, and clarity of presentation. It is likely to serve as a reference for future studies of cavity-coupled and non-equilibrium phenomena in low-dimensional systems.
Introduction: Van der Waals materials.- Fundamentals of on-chip THz spectroscopy.- Fabrication protocol for on-chip THz devices.- Measuring on-chip THz devices.- Extracting the near-field optical conductivity.- THz electrodynamics of graphite heterostructures.- Cavity engineering of quantum materials.- Self-cavity coupling between graphene and its graphite gate.- Conclusion.- Outlook: Cavity sensing and control of quantum phases in 2D materials.
Gunda Kipp completed her undergraduate and master studies in Physics at the University of Hamburg, Germany, including one semester at Uppsala University in Sweden. She was awarded the Otto Stern Prize for the best Master s thesis in 2019. Gunda then continued as a doctoral researcher in experimental condensed matter physics at the Max Planck Institute for the Structure and Dynamics of Matter in Hamburg under the supervision of Prof. Dr. James McIver. She received her Ph.D. from the University of Hamburg in 2025. In January 2026 she transitioned to a postdoctoral position at ETH Zurich, where she continues her research on controlling strongly correlated phases in van der Waals heterostructures through cavity-engineered quantum fluctuations.
