C
C. Charmousis
Researcher at Université Paris-Saclay
Publications - 29
Citations - 2838
C. Charmousis is an academic researcher from Université Paris-Saclay. The author has contributed to research in topics: Cosmological constant & General relativity. The author has an hindex of 19, co-authored 29 publications receiving 2597 citations. Previous affiliations of C. Charmousis include François Rabelais University & University of Paris-Sud.
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Journal ArticleDOI
Effective Holographic Theories for low-temperature condensed matter systems
TL;DR: In this article, the authors analyzed the IR dynamics of effective holographic theories capturing the interplay between charge density and the leading relevant scalar operator at strong coupling, and showed that when the scalar operators is not the dilaton, the DC resistivity scales as the heat capacity (and entropy) for planar 3D systems.
Journal ArticleDOI
General second-order scalar-tensor theory and self-tuning.
TL;DR: This work establishes the unique action that will allow for the existence of a consistent self-tuning mechanism on Friedmann-Lemaître-Robertson-Walker backgrounds, and shows how it can be understood as a combination of just four base Lagrangians with an intriguing geometric structure dependent on the Ricci scalar.
Journal ArticleDOI
Black holes, gravitational waves and fundamental physics: a roadmap
Leor Barack,Vitor Cardoso,Vitor Cardoso,Samaya Nissanke,Samaya Nissanke,Samaya Nissanke,Thomas P. Sotiriou,Abbas Askar,Abbas Askar,C. Belczynski,Gianfranco Bertone,Edi Bon,Diego Blas,Richard Brito,Tomasz Bulik,Clare Burrage,Christian T. Byrnes,Chiara Caprini,Masha Chernyakova,Piotr T. Chruściel,Piotr T. Chruściel,Monica Colpi,Monica Colpi,Valeria Ferrari,Daniele Gaggero,Jonathan R. Gair,Juan Garcia-Bellido,S. F. Hassan,Lavinia Heisenberg,Martin Hendry,Ik Siong Heng,Carlos A. R. Herdeiro,Tanja Hinderer,Tanja Hinderer,Assaf Horesh,Bradley J. Kavanagh,Bence Kocsis,Michael Kramer,Michael Kramer,Alexandre Le Tiec,Chiara M. F. Mingarelli,Germano Nardini,Gijs Nelemans,Gijs Nelemans,Carlos Palenzuela,Paolo Pani,Albino Perego,Albino Perego,Edward K. Porter,Elena M. Rossi,Patricia Schmidt,Alberto Sesana,Ulrich Sperhake,Ulrich Sperhake,Antonio Stamerra,Leo C. Stein,Nicola Tamanini,Thomas M. Tauris,Thomas M. Tauris,L. Arturo Ureña-López,Frederic H. Vincent,Marta Volonteri,Barry Wardell,Norbert Wex,Kent Yagi,Tiziano Abdelsalhin,Miguel A. Aloy,Pau Amaro-Seoane,Lorenzo Annulli,Manuel Arca-Sedda,Ibrahima Bah,Enrico Barausse,Elvis Barakovic,Robert Benkel,Charles L. Bennett,Laura Bernard,Sebastiano Bernuzzi,Christopher P. L. Berry,Emanuele Berti,Emanuele Berti,Miguel Bezares,Jose J. Blanco-Pillado,Jose Luis Blázquez-Salcedo,Matteo Bonetti,Mateja Bošković,Zeljka Bosnjak,Katja Bricman,Bernd Brügmann,Pedro R. Capelo,Sante Carloni,Pablo Cerdá-Durán,C. Charmousis,Sylvain Chaty,Aurora Clerici,Andrew J. Coates,Marta Colleoni,Lucas G. Collodel,Geoffrey Compère,William G. Cook,Isabel Cordero-Carrión,Miguel Correia,Álvaro de la Cruz-Dombriz,Viktor G. Czinner,Kyriakos Destounis,Kostas Dialektopoulos,Kostas Dialektopoulos,Daniela D. Doneva,Daniela D. Doneva,Massimo Dotti,Massimo Dotti,Amelia Drew,Christopher Eckner,James Edholm,Roberto Emparan,Roberto Emparan,Recai Erdem,Miguel Ferreira,Pedro G. Ferreira,Andrew Finch,José A. Font,Nicola Franchini,Kwinten Fransen,Dmitry V. Gal'tsov,Dmitry V. Gal'tsov,A. Ganguly,Davide Gerosa,Kostas Glampedakis,A. Gomboc,Ariel Goobar,Leonardo Gualtieri,Eduardo Guendelman,Francesco Haardt,Troels Harmark,Filip Hejda,Thomas Hertog,Seth Hopper,Sascha Husa,Nada Ihanec,Taishi Ikeda,Amruta Jaodand,Amruta Jaodand,Philippe Jetzer,Xisco Jiménez-Forteza,Xisco Jiménez-Forteza,Marc Kamionkowski,David E. Kaplan,Stelios Kazantzidis,Masashi Kimura,Shiho Kobayashi,Kostas D. Kokkotas,Julian H. Krolik,Jutta Kunz,Claus Lämmerzahl,Claus Lämmerzahl,Paul D. Lasky,José P. S. Lemos,Jackson Levi Said,Stefano Liberati,Jorge C. Lopes,Raimon Luna,Yin-Zhe Ma,Yin-Zhe Ma,Elisa Maggio,Alberto Mangiagli,Alberto Mangiagli,Marina Martinez Montero,Andrea Maselli,Lucio Mayer,Anupam Mazumdar,C. Messenger,Brice Ménard,Masato Minamitsuji,Christopher J. Moore,David F. Mota,Sourabh Nampalliwar,Andrea Nerozzi,David A. Nichols,Emil Nissimov,Martin Obergaulinger,Niels A. Obers,Roberto Oliveri,George Pappas,Vedad Pasic,H. V. Peiris,Tanja Petrushevska,Denis Pollney,Geraint Pratten,Nemanja Rakic,Nemanja Rakic,István Rácz,Miren Radia,Fethi M. Ramazanoğlu,Antoni Ramos-Buades,Guilherme Raposo,Marek Rogatko,Roxana Rosca-Mead,D. Rosińska,Stephan Rosswog,Ester Ruiz-Morales,Mairi Sakellariadou,Nicolas Sanchis-Gual,Om Sharan Salafia,Anuradha Samajdar,Alicia M. Sintes,Majda Smole,Carlos F. Sopuerta,Rafael Souza-Lima,Marko Stalevski,Nikolaos Stergioulas,Chris Stevens,Tomas Tamfal,Alejandro Torres-Forné,Sergey S. Tsygankov,Kivanç I. Ünlütürk,Rosa Valiante,Maarten van de Meent,José M. Velhinho,Yosef Verbin,Bert Vercnocke,Daniele Vernieri,Rodrigo Vicente,Vincenzo Vitagliano,Amanda Weltman,Bernard F. Whiting,A. R. Williamson,Helvi Witek,Aneta Wojnar,Kadri Yakut,Haopeng Yan,S. S. Yazadjiev,G. Zaharijas,Miguel Zilhão +231 more
TL;DR: A comprehensive overview of the state of the art in the relevant fields of research, summarize important open problems, and lay out a roadmap for future progress can be found in this article, which is an initiative taken within the framework of the European Action on 'Black holes, Gravitational waves and Fundamental Physics'.
Journal ArticleDOI
Strong coupling in Hořava gravity
TL;DR: In this paper, it was shown that Horava gravity suffers from two different strong coupling problems, extending all the way into the deep infra-red, and that the original Horava model and its "phenomenologically viable" extensions do not have a perturbative General Relativity limit at any scale.
Journal ArticleDOI
Effective Holographic Theories for low-temperature condensed matter systems
TL;DR: In this paper, the authors analyzed the IR dynamics of effective holographic theories capturing the interplay between charge density and the leading relevant scalar operator at strong coupling, and showed that when the scalar operators is not the dilaton, the DC resistivity scales as the heat capacity (and entropy) for planar (3d) systems.