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20 results on '"Kastikainen, Jani"'

1. Towards complexity of primary-deformed Virasoro circuits

Author

Erdmenger, Johanna, Kastikainen, Jani, and Schuhmann, Tim

Subjects
High Energy Physics - Theory, Quantum Physics
Abstract

The Fubini-Study metric is a central element of information geometry. We explore the role played by information geometry for determining the circuit complexity of Virasoro circuits and their deformations. To this effect, we study unitary quantum circuits generated by the Virasoro algebra and Fourier modes of a primary operator. Such primary-deformed Virasoro circuits can be realized in two-dimensional conformal field theories, where they provide models of inhomogeneous global quenches. We consider a cost function induced by the Fubini-Study metric and provide a universal expression for its time-evolution to quadratic order in the primary deformation for general source profiles. For circuits generated by the Virasoro zero mode and a primary, we obtain a non-zero cost only if spatial inhomogeneities are sufficiently large. In this case, we find that the cost saturates when the source becomes time independent. The exact saturation value is determined by the history of the source profile. As a byproduct, returning to undeformed circuits, we relate the Fubini-Study metric to the K\"ahler metric on a coadjoint orbit of the Virasoro group., Comment: 60 pages, 7 figures, 4 appendices

Published
2024

2. Flavors of entanglement

Author

Jokela, Niko, Kastikainen, Jani, Penín, José Manuel, and Ruotsalainen, Helime

Subjects
High Energy Physics - Theory, Condensed Matter - Strongly Correlated Electrons, General Relativity and Quantum Cosmology
Abstract

We employ holography to investigate Liu-Mezei renormalization group monotones in conformal field theories influenced by massive flavor degrees of freedom. We examine the entanglement entropy of a spherical subregion in three holographic field theories - $\mathcal{N}=1$ Klebanov-Witten theory, $\mathcal{N}=4$ SYM theory, and ABJM theory - with fundamental flavor. The gravity dual of massive unquenched flavor is described by dynamical D-branes, and we solve their backreaction in the smeared approximation. We compute entanglement entropy using the Ryu-Takayanagi formula in these backreacted geometries. Our findings indicate that the Liu-Mezei A- and F-functions decrease monotonically to leading order in the number of flavors across all examples. Additionally, we calculate the leading flavor contribution to entanglement entropy using an alternative probe brane method that does not require knowledge of backreaction in the bulk geometries. These results consistently match with backreacted calculations in all cases, assuming omission of a specific IR boundary term stemming from a total derivative., Comment: 71 pages, 3 figures, 5 appendices, matches the published version

Published
2024
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3. Cornering gravitational entropy

Author

Kastikainen, Jani and Svesko, Andrew

Subjects
High Energy Physics - Theory, General Relativity and Quantum Cosmology
Abstract

We present a new derivation of gravitational entropy functionals in higher-curvature theories of gravity using corner terms that are needed to ensure well-posedness of the variational principle in the presence of corners. This is accomplished by cutting open a manifold with a conical singularity into a wedge with boundaries intersecting at a corner. Notably, our observation provides a rigorous definition of the action of a conical singularity that does not require regularization. For Einstein gravity, we compute the R\'enyi entropy of gravitational states with either fixed-periodicity or fixed-area boundary conditions. The entropy functional for fixed-area states is equal to the corner term, whose extremization follows from the variation of the Einstein action of the wedge under transverse diffeomorphisms. For general Lovelock gravity the entropy functional of fixed-periodicity states is equal to the Jacobson--Myers (JM) functional, while fixed-area states generalize to fixed-JM-functional states, having a flat spectrum. Extremization of the JM functional is shown to coincide with the variation of the Lovelock action of the wedge. For arbitrary $F$(Riemann) gravity, under special periodic boundary conditions, we recover the Dong--Lewkowycz entropy for fixed-periodicity states. Since the variational problem in the presence of corners is not well-posed, we conjecture the generalization of fixed-area states does not exist for such theories without additional boundary conditions. Thus, our work suggests the existence of entropy functionals is tied to the existence of corner terms which make the Dirichlet variational problem well-posed., Comment: 46 pages + appendices, 3 figures; v2: minor edits, references added, JHEP version

Published
2023

4. Gravitational R\'enyi entropy from corner terms

Author

Kastikainen, Jani and Svesko, Andrew

Subjects
High Energy Physics - Theory, General Relativity and Quantum Cosmology
Abstract

We provide a consistent first principles prescription to compute gravitational R\'enyi entropy using Hayward corner terms. For Euclidean solutions to Einstein gravity, we compute R\'enyi entropy of Hartle--Hawking and fixed--area states by cutting open a manifold containing a conical singularity into a wedge with a corner. The entropy functional for fixed--area states is equal to the corner term itself, having a flat-entanglement spectrum, while extremization of the functional follows from the variation of the corner term under diffeomorphisms. Notably, our method does not require regularization of the conical singularity, and naturally extends to higher-curvature theories of gravity., Comment: 5 pages, 2 figures; v2: References added; v3: minor edits, PRD version

Published
2023

5. Quantum information geometry of driven CFTs

Author

de Boer, Jan, Godet, Victor, Kastikainen, Jani, and Keski-Vakkuri, Esko

Subjects
High Energy Physics - Theory, Condensed Matter - Statistical Mechanics, Quantum Physics
Abstract

Driven quantum systems exhibit a large variety of interesting and sometimes exotic phenomena. Of particular interest are driven conformal field theories (CFTs) which describe quantum many-body systems at criticality. In this paper, we develop both a spacetime and a quantum information geometry perspective on driven 2d CFTs. We show that for a large class of driving protocols the theories admit an alternative but equivalent formulation in terms of a CFT defined on a spacetime with a time-dependent metric. We prove this equivalence both in the operator formulation as well as in the path integral description of the theory. A complementary quantum information geometric perspective for driven 2d CFTs employs the so-called Bogoliubov-Kubo-Mori (BKM) metric, which is the counterpart of the Fisher metric of classical information theory, and which is obtained from a perturbative expansion of relative entropy. We compute the BKM metric for the universal sector of Virasoro excitations of a thermal state, which captures a large class of driving protocols, and find it to be a useful tool to classify and characterize different types of driving. For M\"obius driving by the SL(2,R) subgroup, the BKM metric becomes the hyperbolic metric on the unit disk. We show how the non-trivial dynamics of Floquet driven CFTs is encoded in the BKM geometry via M\"obius transformations. This allows us to identify ergodic and non-ergodic regimes in the driving. We also explain how holographic driven CFTs are dual to driven BTZ black holes with evolving horizons. The deformation of the black hole horizon towards and away from the asymptotic boundary provides a holographic understanding of heating and cooling in Floquet CFTs., Comment: 89 pages including references, 14 figures. Changes in V2: layout improvements and additional references. Matches published version

Published
2023
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7. Holographic BCFT Spectra from Brane Mergers

Author

Biswas, Shovon, Kastikainen, Jani, Shashi, Sanjit, and Sully, James

Subjects
High Energy Physics - Theory, Condensed Matter - Statistical Mechanics, General Relativity and Quantum Cosmology
Abstract

We use holography to study the spectra of boundary conformal field theories (BCFTs). To do so, we consider a 2-dimensional Euclidean BCFT with two circular boundaries that correspond to dynamical end-of-the-world branes in 3-dimensional gravity. Interactions between these branes inform the operator content and the energy spectrum of the dual BCFT. As a proof of concept, we first consider two highly separated branes whose only interaction is taken to be mediated by a scalar field. The holographic computation of the scalar-mediated exchange reproduces a light scalar primary and its global descendants in the closed-string channel of the dual BCFT. We then consider a gravity model with point particles. Here, the interaction of two separated branes corresponds to a heavy operator which lies below the black hole threshold. However, we may also consider branes at finite separation that "merge" non-smoothly. Such brane mergers can be used to describe unitary sub-threshold boundary-condition-changing operators in the open-string spectrum of the BCFT. We also find a new class of sub-threshold Euclidean bra-ket wormhole saddles with a factorization puzzle for closed-string amplitudes., Comment: 56 pages (including appendices) + references, 23 figures; v3: added construction of excited states in open-string channel, version to appear in JHEP

Published
2022
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8. Flavored ABJM theory on the sphere and holographic F-functions

Author

Jokela, Niko, Kastikainen, Jani, Kiritsis, Elias, and Nitti, Francesco

Subjects
High Energy Physics - Theory
Abstract

We study strongly coupled ABJM theory on the 3-sphere with massive quenched flavor using the AdS/CFT correspondence. The holographic dual consists of type IIA supergravity with probe D6-branes. The flavor mass is a relevant deformation driving an RG flow whose IR endpoint is pure ABJM theory. At non-zero mass, we find that the theory on the 3-sphere exhibits a quantum phase transition at a critical value of the sphere radius. The transition corresponds to a topology change in the D6-brane embeddings whose dual interpretation is the meson-melting transition. We perform the holographic computation of the free energy on 3-sphere and we use it to construct various candidate F-functions. These were recently proposed in the context of Einstein-scalar gravity to interpolate monotonically between the values of the sphere free energies of the UV and IR CFTs. We find that while the F-functions of the flavored ABJM theory have the correct UV and IR limits, they are not monotonic. We surmise that the non-monotonicity is related to the presence of the phase transition., Comment: 52 pages, 9 figures, v3 includes three new references and small corrections, matches the published version

Published
2021
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9. Structure of Holographic BCFT Correlators from Geodesics

Author

Kastikainen, Jani and Shashi, Sanjit

Subjects
High Energy Physics - Theory
Abstract

We compute correlation functions, specifically 1-point and 2-point functions, in holographic boundary conformal field theory (BCFT) using geodesic approximation. The holographic model consists of a massive scalar field coupled to a Karch-Randall brane -- a rigid boundary in the bulk AdS space. Geodesic approximation requires the inclusion of paths reflecting off of this brane, which we show in detail. For the 1-point function, we find agreement between geodesic approximation and the harder $\Delta$-exact calculation, and we give a novel derivation of boundary entropy using the result. For the 2-point function, we find a factorization phase transition and a mysterious set of anomalous boundary-localized BCFT operators. We also discuss some puzzles concerning these operators., Comment: 17 pages (including appendices) + references, 11 figures; v3: fixed additional typos, matches version to appear in PRD

Published
2021
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10. Quantum hypothesis testing in many-body systems

Author

de Boer, Jan, Godet, Victor, Kastikainen, Jani, and Keski-Vakkuri, Esko

Subjects
Quantum Physics, Condensed Matter - Statistical Mechanics, High Energy Physics - Theory
Abstract

One of the key tasks in physics is to perform measurements in order to determine the state of a system. Often, measurements are aimed at determining the values of physical parameters, but one can also ask simpler questions, such as "is the system in state A or state B?". In quantum mechanics, the latter type of measurements can be studied and optimized using the framework of quantum hypothesis testing. In many cases one can explicitly find the optimal measurement in the limit where one has simultaneous access to a large number $n$ of identical copies of the system, and estimate the expected error as $n$ becomes large. Interestingly, error estimates turn out to involve various quantum information theoretic quantities such as relative entropy, thereby giving these quantities operational meaning. In this paper we consider the application of quantum hypothesis testing to quantum many-body systems and quantum field theory. We review some of the necessary background material, and study in some detail the situation where the two states one wants to distinguish are parametrically close. The relevant error estimates involve quantities such as the variance of relative entropy, for which we prove a new inequality. We explore the optimal measurement strategy for spin chains and two-dimensional conformal field theory, focusing on the task of distinguishing reduced density matrices of subsystems. The optimal strategy turns out to be somewhat cumbersome to implement in practice, and we discuss a possible alternative strategy and the corresponding errors., Comment: 76 pages, v2: references added, v3: minor changes, published version

Published
2020
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11. Conical defects and holography in topological AdS gravity

Author

Kastikainen, Jani

Subjects
High Energy Physics - Theory, General Relativity and Quantum Cosmology, Mathematical Physics
Abstract

We study codimension-even conical defects that contain a deficit solid angle around each point along the defect. We show that they lead to a delta function contribution to the Lovelock scalar and we compute the contribution by two methods. We then show that these codimension-even defects appear as Euclidean brane solutions in higher dimensional topological AdS gravity which is Lovelock-Chern-Simons gravity without torsion. The theory possesses a holographic Weyl anomaly that is purely of type-A and proportional to the Lovelock scalar. Using the formula for the defect contribution, we prove a holographic duality between codimension-even defect partition functions and codimension-even brane on-shell actions in Euclidean signature. More specifically, we find that the logarithmic divergences match, because the Lovelock-Chern-Simons action localizes on the brane exactly. We demonstrate the duality explicitly for a spherical defect on the boundary which extends as a codimension-even hyperbolic brane into the bulk. For vanishing brane tension, the geometry is a foliation of Euclidean AdS space that provides a one-parameter generalization of AdS-Rindler space., Comment: 29 pages with three appendices

Published
2020
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12. Quasi-local energy and ADM mass in pure Lovelock gravity

Author

Kastikainen, Jani

Subjects
General Relativity and Quantum Cosmology, High Energy Physics - Theory
Abstract

We study how the standard definitions of ADM mass and Brown-York quasi-local energy generalize to pure Lovelock gravity. The quasi-local energy is renormalized using the background subtraction prescription and we consider its limit for large surfaces. We find that the large surface limit vanishes for asymptotically flat fall-off conditions except in Einstein gravity. This problem is avoided by focusing on the variation of the quasi-local energy which correctly approaches the variation of the ADM mass for large surfaces. As a result, we obtain a new simple formula for the ADM mass in pure Lovelock gravity. We apply the formula to spherically symmetric geometries verifying previous calculations in the literature. We also revisit asymptotically AdS geometries., Comment: 24 pages with two appendices; references added, minor changes to abstract and text, updated to JHEP style

Published
2019
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15. Investigations of Boundaries and Branes in the Holographic Duality

Author

Kastikainen, Jani, University of Helsinki, Faculty of Science, Department of Physics, Doctoral Programme in Particle Physics and Universe Sciences, Université Paris Cité, Astroparticule et Cosmologie, Helsingin yliopisto, matemaattis-luonnontieteellinen tiedekunta, Alkeishiukkasfysiikan ja maailmankaikkeuden tutkimuksen tohtoriohjelma, Helsingfors universitet, matematisk-naturvetenskapliga fakulteten, Doktorandprogrammet i elementarpartikelfysik och kosmologi, Hofman, Diego, Keski-Vakkuri, Esko, and Nitti, Francesco

Subjects
teoreettinen fysiikka
Abstract

Quantum conformal field theory (CFT) is a special type of quantum field theory which is symmetric under conformal transformations of spacetime. Because of their relative simplicity, CFTs appear in many different areas of theoretical physics such as condensed matter physics and quantum gravity. For example in the study of statistical mechanical systems, CFTs appear as continuum effective descriptions of collective phenomena near a critical point where a phase transition occurs. In this context, the existence of different types of CFTs is connected to the classification of different universality classes of phase transitions. As theories by themselves, CFTs do not describe the gravitational force which is transmitted by the graviton particle. However, CFTs are deeply connected to gravity in string theory where they determine the dynamics of quantum mechanical strings. The spectrum of vibrational modes of a string include the graviton making string theory a theory of quantum gravity which is self-consistent based on vast theoretical knowledge. Hence CFTs have played a central role in the development of string theory and in our quest to unify Einstein's theory of gravity with quantum mechanics. The main milestone in the modern understanding of quantum gravity was the discovery of the holographic duality in string theory. Simply put, the duality says that there exist special CFTs which contain rules to describe gravity hidden in them. However, these rules are holographic, because they describe gravity in a spacetime with one extra dimension: the duality is like a hologram where a three-dimensional image (gravity) is encoded on a two-dimensional surface (CFT). Not only is the holographic duality useful in understanding the structure of quantum gravity, it is also extremely powerful in predicting dynamics of strongly interacting quantum fields that occur inside neutron stars for example. This thesis is devoted to the study of the holographic duality and it is based on four research articles on the topic. The focus is on how extended objects, namely boundaries and branes, behave on both sides of the duality. In string theory, boundaries of open strings describe dynamics of D-branes whose understanding was crucial for the discovery of the holographic duality in the first place. Similarly on the CFT side, boundaries give raise to observable effects such as the Casimir effect when the system is confined between two parallel plates. The goal of the thesis is to give an introduction to these concepts in the context of the holographic duality. Faasimuutos on luonnonilmiö, jossa aineen olomuoto muuttuu äkillisesti ulkoisen tekijän vaikutuksesta. Perinteinen esimerkki faasimuutoksesta on veden kiehuminen, jossa vesi muuttuu nesteestä kaasuksi lämpötilaa nostettaessa. Luonnossa esiintyy myös niin sanottuja kvanttifaasimuutoksia, jotka tapahtuvat absoluuttisessa nolla lämpötilassa ja, joiden aiheuttaja on aineen rakennuspalikoiden ominainen kvanttivärähtely. Fyysikot ovat pitkään tutkineet faasimuutoksien ominaisuuksia ja on käynyt ilmi, että faasimuutoksen läheisyydessä aineen ominaisuudet yksinkertaistuvat. Tästä syystä erilaiselta näyttäviä faasimuutoksia voidaan kuvata yhdellä mallilla, joka tunnetaan nimellä konformikenttäteoria. Kyseessä on matemaattinen teoria, jossa aineen kollektiivisia ominaisuuksia mallinnetaan värähtelevien kvanttikenttien avulla. Konformikenttäteoria on tavanomaista yksinkertaisempi, koska sen yhtälöt ovat konformisymmetrisia eli ne ovat riippumattomia kaikista pituusskaaloista fraktaalin tavoin. Konformikenttäteoria on modernin teoreettisen fysikaan kulmakivi ja sillä on sovelluksia myös faasimuutoksien mallintamisen ulkopuolella. Aivan 1900-luvun lopussa tehtiin havainto, että tietynlaiset konformikenttäteoriat sisältävät itsessään säännöt kuvaamaan myös painovoiman lakeja eli Einsteinin yleistä suhteellisuusteoriaa. Tätä löytöä kutsutaan nimellä holografinen dualiteetti, koska konformikenttäteoria mallintaa painovoimaa hologrammin tavoin maailmankaikkeudessa, jolla on yksi ulottuvuus enemmän. Mikä tekee holografisesta dualiteetista niin erityisen on sen kyky kuvata painovoiman kvanttimekaanisia ominaisuuksia. Teoreettisen fysiikan yksi suurimmista ongelmista on ollut yhdistää kvanttimekaniikan ja painovoiman yhtälöt toisiinsa, mikä on johtanut matemaattisiin ristiriitoihin kuten mustien aukkojen informaatioparadoksiin. Dualiteetin tutkimus on johtanut läpimurtoihin tämänkaltaisten ristiriitojen ratkaisuissa. Tässä väitöskirjassa tutkitaan konformikenttäteorian ja kvanttipainovoiman välistä yhteyttä holografisen dualiteetin avulla. Tutkimuksen painotus on erilaisten levittäytyneiden kappaleiden, esimerkiksi reunojen ja braanien, aiheuttamien vaikutuksien selvittäminen. Väitöskirja toimii johdantona kaksiulotteisiin konformikenttäteorioihin, modifioituihin gravitaatioteorioihin sekä säieteoriaan tässä kontekstissa.

Published
2023

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