Maia Vergniory

Last updated
Maia Vergniory
Born
Maia Garcia Vergniory
Alma mater University of the Basque Country
Joseph Fourier University
Scientific career
Fields Electronic structure
Magnetism
Spin
Metals
Topological insulators [1]
InstitutionsDonostia International Physics Center
Ikerbasque
Max Planck Institute for Chemical Physics of Solids
Thesis Gorputz anitzen eta banda-egituraren efektuak egoera elektroniko kitzikatuen zein oio higikorren eta gainazal solidoen arteko elkerrekintzaren gainean  (2008)
Doctoral advisor Jose Maria Pitarke de la Torre and Pedro Miguel Echenique
Website maiagv-dipc.org OOjs UI icon edit-ltr-progressive.svg

Maia Garcia Vergniory is a Spanish computational physicist who is a group leader at the Max Planck Institute for Chemical Physics of Solids. [1] Her work in topological quantum chemistry investigates the phases of topological materials. [2] She was elected Fellow of the American Physical Society in 2022. [3]

Contents

Early life and education

Vergniory was born in Getxo. [4] She was a doctoral researcher at the University of the Basque Country. Her research considered many-body effects on the interactions between excited electronic states and the mobile ions on surfaces. [5] She started working on topological materials in 2012. [6]

Research and career

Vergniory worked as a research fellow at the Ikerbasque and the Donostia International Physics Center. [7] She studied novel materials and computational strategies to realise new condensed matter systems. [8]

Verginory became interested in the design of new topological materials with optimised functional properties. [9] [10] Topological materials are insulators in the bulk but conductive on their surfaces. [11] The conducting channels that facilitate current flow are robust and independent of size.

Vergniory studied the Inorganic Crystal Structure Database to identify topologically nontrivial materials. [12] She designed a computational effort to simulate real materials and determine whether or not they showed topological properties. [13] This included complex theoretical analysis that could classify topological phases, and information from materials scientists on whether materials were suitable or not. [14] Vergniory uses her supercomputers to perform her calculations ab initio. [6] In an interview with Physics World , Verginory said that she had been surprised by how many materials she identified with topological properties. [14] As an output of this work, the high-order topological insulator Bi4Br4 was synthesised and studied experimentally. She showed that if it was possible to identify the symmetry of the crystalline symmetry of a material, she could easily anticipate the behaviour of the charge. [14] She has since started investigating organic materials. [14] She believes that topological crystals with a chiral structure will display several exotic physical phenomena. [15]

Awards and honours

Selected publications

Related Research Articles

<span class="mw-page-title-main">Kondo effect</span> Physical phenomenon due to impurities

In physics, the Kondo effect describes the scattering of conduction electrons in a metal due to magnetic impurities, resulting in a characteristic change i.e. a minimum in electrical resistivity with temperature. The cause of the effect was first explained by Jun Kondo, who applied third-order perturbation theory to the problem to account for scattering of s-orbital conduction electrons off d-orbital electrons localized at impurities. Kondo's calculation predicted that the scattering rate and the resulting part of the resistivity should increase logarithmically as the temperature approaches 0 K. Extended to a lattice of magnetic impurities, the Kondo effect likely explains the formation of heavy fermions and Kondo insulators in intermetallic compounds, especially those involving rare earth elements such as cerium, praseodymium, and ytterbium, and actinide elements such as uranium. The Kondo effect has also been observed in quantum dot systems.

<span class="mw-page-title-main">Majorana fermion</span> Fermion that is its own antiparticle

A Majorana fermion, also referred to as a Majorana particle, is a fermion that is its own antiparticle. They were hypothesised by Ettore Majorana in 1937. The term is sometimes used in opposition to a Dirac fermion, which describes fermions that are not their own antiparticles.

<span class="mw-page-title-main">Tungsten ditelluride</span> Chemical compound

Tungsten ditelluride (WTe2) is an inorganic semimetallic chemical compound. In October 2014, tungsten ditelluride was discovered to exhibit an extremely large magnetoresistance: 13 million percent resistance increase in a magnetic field of 60 tesla at 0.5 kelvin. The resistance is proportional to the square of the magnetic field and shows no saturation. This may be due to the material being the first example of a compensated semimetal, in which the number of mobile holes is the same as the number of electrons. Tungsten ditelluride has layered structure, similar to many other transition metal dichalcogenides, but its layers are so distorted that the honeycomb lattice many of them have in common is in WTe2 hard to recognize. The tungsten atoms instead form zigzag chains, which are thought to behave as one-dimensional conductors. Unlike electrons in other two-dimensional semiconductors, the electrons in WTe2 can easily move between the layers.

The quantum spin Hall state is a state of matter proposed to exist in special, two-dimensional semiconductors that have a quantized spin-Hall conductance and a vanishing charge-Hall conductance. The quantum spin Hall state of matter is the cousin of the integer quantum Hall state, and that does not require the application of a large magnetic field. The quantum spin Hall state does not break charge conservation symmetry and spin- conservation symmetry.

<span class="mw-page-title-main">Topological insulator</span> State of matter with insulating bulk but conductive boundary

A topological insulator is a material whose interior behaves as an electrical insulator while its surface behaves as an electrical conductor, meaning that electrons can only move along the surface of the material.

In condensed matter physics, a quantum spin liquid is a phase of matter that can be formed by interacting quantum spins in certain magnetic materials. Quantum spin liquids (QSL) are generally characterized by their long-range quantum entanglement, fractionalized excitations, and absence of ordinary magnetic order.

<span class="mw-page-title-main">Shoucheng Zhang</span> Chinese-American physicist

Shoucheng Zhang was a Chinese-American physicist who was the JG Jackson and CJ Wood professor of physics at Stanford University. He was a condensed matter theorist known for his work on topological insulators, the quantum Hall effect, the quantum spin Hall effect, spintronics, and high-temperature superconductivity. According to the National Academy of Sciences:

He discovered a new state of matter called topological insulator in which electrons can conduct along the edge without dissipation, enabling a new generation of electronic devices with much lower power consumption. For this ground breaking work he received numerous international awards, including the Buckley Prize, the Dirac Medal and Prize, the Europhysics Prize, the Physics Frontiers Prize and the Benjamin Franklin Medal.

<span class="mw-page-title-main">Samarium hexaboride</span> Chemical compound

Samarium hexaboride (SmB6) is an intermediate-valence compound where samarium is present both as Sm2+ and Sm3+ ions at the ratio 3:7. It is a Kondo insulator having a metallic surface state.

<span class="mw-page-title-main">Charles L. Kane</span> American physicist

Charles L. Kane is a theoretical condensed matter physicist and is the Christopher H. Browne Distinguished Professor of Physics at the University of Pennsylvania. He completed a B.S. in physics at the University of Chicago in 1985 and his Ph.D. at Massachusetts Institute of Technology in 1989. Prior to joining the faculty at the University of Pennsylvania he was a postdoctoral associate at IBM's T. J. Watson Research Center working with his mentor Matthew P. A. Fisher, among others.

<span class="mw-page-title-main">Quantum simulator</span> Simulators of quantum mechanical systems

Quantum simulators permit the study of a quantum system in a programmable fashion. In this instance, simulators are special purpose devices designed to provide insight about specific physics problems. Quantum simulators may be contrasted with generally programmable "digital" quantum computers, which would be capable of solving a wider class of quantum problems.

Claudia Felser is a German solid state chemist and materials scientist. She is currently a director of the Max Planck Institute for Chemical Physics of Solids. Felser was elected as a member into the National Academy of Engineering in 2020 for the prediction and discovery of engineered quantum materials ranging from Heusler compounds to topological insulators.

<span class="mw-page-title-main">Pedro Miguel Etxenike</span> Basque physicist and former Minister of Education of the Basque Autonomous Community

Pedro Miguel Etxenike Landiribar, also known as Pedro Miguel Echenique, is a theoretical solid-state physicist, Professor of Condensed Matter Physics at the University of the Basque Country (UPV/EHU), and former minister of the Basque Autonomous Community.

Weyl semimetals are semimetals or metals whose quasiparticle excitation is the Weyl fermion, a particle that played a crucial role in quantum field theory but has not been observed as a fundamental particle in vacuum. In these materials, electrons have a linear dispersion relation, making them a solid-state analogue of relativistic massless particles.

<span class="mw-page-title-main">Xue Qikun</span> Chinese physicist

Xue Qikun is a Chinese physicist. He is a professor of Tsinghua University, Beijing. He has done much work in Condensed Matter Physics, especially on superconductors and topological insulators. In 2013, Xue was the first to achieve the quantum anomalous Hall effect (QAHE), an unusual orderly motion of electrons in a conductor, in his laboratory at Tsinghua University. Xue is a member of the Chinese Academy of Sciences, vice president for research of Tsinghua University, and director of State Key Lab of Quantum Physics. In 2016, he was one of the first recipients of the new Chinese Future Science Prize for experimental discovery of high-temperature superconductivity at material interfaces and the QAHE. This award has been described as "China's Nobel Prize".

<span class="mw-page-title-main">Dirac cone</span> Quantum effect in some non-metals

In physics, Dirac cones are features that occur in some electronic band structures that describe unusual electron transport properties of materials like graphene and topological insulators. In these materials, at energies near the Fermi level, the valence band and conduction band take the shape of the upper and lower halves of a conical surface, meeting at what are called Dirac points.

The term Dirac matter refers to a class of condensed matter systems which can be effectively described by the Dirac equation. Even though the Dirac equation itself was formulated for fermions, the quasi-particles present within Dirac matter can be of any statistics. As a consequence, Dirac matter can be distinguished in fermionic, bosonic or anyonic Dirac matter. Prominent examples of Dirac matter are graphene and other Dirac semimetals, topological insulators, Weyl semimetals, various high-temperature superconductors with -wave pairing and liquid helium-3. The effective theory of such systems is classified by a specific choice of the Dirac mass, the Dirac velocity, the gamma matrices and the space-time curvature. The universal treatment of the class of Dirac matter in terms of an effective theory leads to a common features with respect to the density of states, the heat capacity and impurity scattering.

Photonic topological insulators are artificial electromagnetic materials that support topologically non-trivial, unidirectional states of light. Photonic topological phases are classical electromagnetic wave analogues of electronic topological phases studied in condensed matter physics. Similar to their electronic counterparts, they, can provide robust unidirectional channels for light propagation. The field that studies these phases of light is referred to as topological photonics.

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References

  1. 1 2 Maia Vergniory publications indexed by Google Scholar OOjs UI icon edit-ltr-progressive.svg
  2. Maia Vergniory publications from Europe PubMed Central
  3. 1 2 "APS fellowship awarded to Maia G. Vergniory". EurekAlert!. Retrieved 2022-11-09.
  4. ""Nuestro logro ha sido desarrollar la teoría que ganó el Premio Nobel"". El Diario Vasco (in Spanish). 2017-07-20. Retrieved 2022-11-09.
  5. "Gorputz anitzen eta banda-egituraren efektuak egoera elektroniko kitzikatuen zein oio higikorren eta gainazal solidoen arteko elkerrekintzaren gainean | WorldCat.org". www.worldcat.org. Retrieved 2022-11-09.
  6. 1 2 "Maia G. Vergniory: "Se han encontrado 200 materiales topológicos, pero aún no tenemos el candidato ideal"". Quo (in Spanish). 2018-12-07. Retrieved 2022-11-09.
  7. "Department of Applied Physics Research Seminar: Maia G. Vergniory | Aalto University". www.aalto.fi. 29 March 2021. Retrieved 2022-11-09.
  8. "Research". This is the website of Maia G. Vergniory. 2020-04-22. Retrieved 2022-11-09.
  9. Goikoetxea, Jakes (10 June 2022). "Ezezaguna bai, exotikoa ez". Berria (in Basque). Retrieved 2022-11-09.
  10. ""Para el ordenador cuántico queda como mínimo una década"". Agencia SINC (in Spanish). Retrieved 2022-11-09.
  11. "Donostia International Physics Center –2018/09/05 Maia Garcia Vergniory in the cover of Nature Physics". dipc.ehu.eus. Retrieved 2022-11-09.
  12. Vergniory, Maia G.; Wieder, Benjamin J.; Elcoro, Luis; Parkin, Stuart S. P.; Felser, Claudia; Bernevig, B. Andrei; Regnault, Nicolas (2022-05-20). "All topological bands of all nonmagnetic stoichiometric materials". Science. 376 (6595): eabg9094. arXiv: 2105.09954 . doi:10.1126/science.abg9094. ISSN   0036-8075. PMID   35587971. S2CID   235125620.
  13. "Topological Materials Database". topologicalquantumchemistry.com. Retrieved 2022-11-09.
  14. 1 2 3 4 "A periodic table for topological materials". Physics World. 2022-11-01. Retrieved 2022-11-09.
  15. Schröter, Niels B. M.; Pei, Ding; Vergniory, Maia G.; Sun, Yan; Manna, Kaustuv; de Juan, Fernando; Krieger, Jonas A.; Süss, Vicky; Schmidt, Marcus; Dudin, Pavel; Bradlyn, Barry; Kim, Timur K.; Schmitt, Thorsten; Cacho, Cephise; Felser, Claudia (August 2019). "Chiral topological semimetal with multifold band crossings and long Fermi arcs". Nature Physics. 15 (8): 759–765. arXiv: 1812.03310 . Bibcode:2019NatPh..15..759S. doi:10.1038/s41567-019-0511-y. ISSN   1745-2481. S2CID   118941556.
  16. "Donostia International Physics Center –2017/11/22 - Maia García-Vergniory, researcher from DIPC and UPV/EHU, winner of the Prize L'Oréal-UNESCO For Women in Science". dipc.ehu.es. Retrieved 2022-11-09.
  17. Taibo, Por Marieta (2017-11-23). "Estas científicas pueden cambiar tu vida". Cosmopolitan (in European Spanish). Retrieved 2022-11-09.
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