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Infinite Analysis Seminar Tokyo
Seminar information archive ~05/01|Next seminar|Future seminars 05/02~
| Date, time & place | Saturday 13:30 - 16:00 117Room #117 (Graduate School of Math. Sci. Bldg.) |
|---|
Seminar information archive
2025/04/25
17:00-19:00 Room #056 (Graduate School of Math. Sci. Bldg.)
Naoto Okubo (Aoyama Gakuin University, College of Science and Engineering) 17:00-18:00
Cluster algebra and birational representations of affine Weyl groups (JAPANESE)
A generalization of the q-Garnier system with the aid of a birational representation of an affine Weyl group (JAPANESE)
Naoto Okubo (Aoyama Gakuin University, College of Science and Engineering) 17:00-18:00
Cluster algebra and birational representations of affine Weyl groups (JAPANESE)
[ Abstract ]
The cluster algebra (with the coefficients) was introduced by Fomin and Zelevinsky. It is a variety of commutative ring generated by the cluster variables. A set of all cluster variables is given by an operation called the mutation which acts on a triple of the quiver, the cluster variables and the coefficients. Then new cluster variables (resp. coefficients) are rational in original cluster variables and coefficients (resp. coefficients). In this talk, we discuss a systematic formulation of birational representations of affine Weyl groups with the aid of the mutation. These birational representations become sources of the q-Painleve equations as will be seen in the next talk. This talk is based on a collaboration with T. Suzuki (Kindai Univ.) and that with T. Masuda (Aoyama Gakuin Univ.) and T. Tsuda (Aoyama Gakuin Univ).
Takao Suzuki (Kindai University, Faculty of Science and Engineering) 18:00-19:00The cluster algebra (with the coefficients) was introduced by Fomin and Zelevinsky. It is a variety of commutative ring generated by the cluster variables. A set of all cluster variables is given by an operation called the mutation which acts on a triple of the quiver, the cluster variables and the coefficients. Then new cluster variables (resp. coefficients) are rational in original cluster variables and coefficients (resp. coefficients). In this talk, we discuss a systematic formulation of birational representations of affine Weyl groups with the aid of the mutation. These birational representations become sources of the q-Painleve equations as will be seen in the next talk. This talk is based on a collaboration with T. Suzuki (Kindai Univ.) and that with T. Masuda (Aoyama Gakuin Univ.) and T. Tsuda (Aoyama Gakuin Univ).
A generalization of the q-Garnier system with the aid of a birational representation of an affine Weyl group (JAPANESE)
[ Abstract ]
The q-Garnier system was introduced by Sakai as the connection preserving deformation of a linear q-difference equation. Afterward, Nagao and Yamada investigated the q-Garnier system by using the Pade method in detail and gave its variations (regarded as q-analogues of the Schlesinger transformations). In this talk, we formulate the q-Garnier system and its variations systematically by using the birational representation given in the previous talk. If time permits, we discuss a Lax form and a particular solution in terms of the basic hypergeometric series. This talk is based on a collaboration with N. Okubo (Aoyama Gakuin Univ).
The q-Garnier system was introduced by Sakai as the connection preserving deformation of a linear q-difference equation. Afterward, Nagao and Yamada investigated the q-Garnier system by using the Pade method in detail and gave its variations (regarded as q-analogues of the Schlesinger transformations). In this talk, we formulate the q-Garnier system and its variations systematically by using the birational representation given in the previous talk. If time permits, we discuss a Lax form and a particular solution in terms of the basic hypergeometric series. This talk is based on a collaboration with N. Okubo (Aoyama Gakuin Univ).
2025/02/13
13:30-17:00 Room #118, hybrid seminar (Graduate School of Math. Sci. Bldg.)
Genki Shibukawa (Kobe University) 13:30-15:00
Basics and developments of the $\mu$-function (First part) (日本語)
Basics and developments of the $\mu$-function (Second part) (日本語)
Genki Shibukawa (Kobe University) 13:30-15:00
Basics and developments of the $\mu$-function (First part) (日本語)
[ Abstract ]
First part (speaker: Genki Shibukawa) Starting from a short introduction to the original Zwegers' $\mu$ function, we explain some basic tools of $q$-special functions ( $q$-hypergeometric functions) and $q$-analysis ($q$-difference equations, $q$-Borel and $q$-Laplace transformations) which are necessary to give a special function theoretic interpretation of the $\mu $-function. In these settings, we introduce the generalized $\mu $-function which is a one-parameter deformation of the Zwegers' $\mu $-function, and derive its basic properties such as symmetry, explicit formulas, difference relations, and connection formulas. In particular, we explain the relationship between the generalized $\mu $-function and $q$-Hermite polynomial (function).
Satoshi Tsuchimi (Kobe University) 15:30-17:00First part (speaker: Genki Shibukawa) Starting from a short introduction to the original Zwegers' $\mu$ function, we explain some basic tools of $q$-special functions ( $q$-hypergeometric functions) and $q$-analysis ($q$-difference equations, $q$-Borel and $q$-Laplace transformations) which are necessary to give a special function theoretic interpretation of the $\mu $-function. In these settings, we introduce the generalized $\mu $-function which is a one-parameter deformation of the Zwegers' $\mu $-function, and derive its basic properties such as symmetry, explicit formulas, difference relations, and connection formulas. In particular, we explain the relationship between the generalized $\mu $-function and $q$-Hermite polynomial (function).
Basics and developments of the $\mu$-function (Second part) (日本語)
[ Abstract ]
Second part (speaker: Satoshi Tsuchimi)
In this part, we present some advanced topics of the $\mu$ function. First, we show that the $\mu$-functions naturally appear in special solutions of factorized higher-order $q$-difference equations. Next, by applying the above $q$-analytic methods, we introduce a multivariate analogue of the generalized $\mu$-function and give some formulas. Finally, by similar methods, we construct another generalization of the $\mu$-function from the Kontsevich function which is an important function in knot invariants. This generalization of the $\mu$-function is related to the big $q$-Hermite polynomial (function) which is a 1 parameter deform of the $q$-Hermite polynomial.
Second part (speaker: Satoshi Tsuchimi)
In this part, we present some advanced topics of the $\mu$ function. First, we show that the $\mu$-functions naturally appear in special solutions of factorized higher-order $q$-difference equations. Next, by applying the above $q$-analytic methods, we introduce a multivariate analogue of the generalized $\mu$-function and give some formulas. Finally, by similar methods, we construct another generalization of the $\mu$-function from the Kontsevich function which is an important function in knot invariants. This generalization of the $\mu$-function is related to the big $q$-Hermite polynomial (function) which is a 1 parameter deform of the $q$-Hermite polynomial.
2025/01/16
15:30-16:30 Room #オンライン開催 (Graduate School of Math. Sci. Bldg.)
Please make contact to the following address if you want to attend the seminar.
Jean-Emile Bourgine (SIMIS (Shanghai Institute for Mathematics and Interdisciplinary Sciences))
Free field representations of quantum groups and q-deformed W-algebras through cluster algebras (ENGLISH)
Please make contact to the following address if you want to attend the seminar.
Jean-Emile Bourgine (SIMIS (Shanghai Institute for Mathematics and Interdisciplinary Sciences))
Free field representations of quantum groups and q-deformed W-algebras through cluster algebras (ENGLISH)
[ Abstract ]
Following the development of the AGT correspondence, new relations between free field representations of quantum groups and W-algebras were obtained. The simplest one is the homomorphism between the level $(N,0)$ horizontal representation of the quantum toroidal gl(1) algebra and (dressed) q-deformed $W_N$ algebras. In this talk, I will explain how to extend this type of relations to the Wakimoto representations of quantum affine sl(N) algebras using the 'surface defect' deformation of the quantum toroidal sl(N) algebra.
Following the development of the AGT correspondence, new relations between free field representations of quantum groups and W-algebras were obtained. The simplest one is the homomorphism between the level $(N,0)$ horizontal representation of the quantum toroidal gl(1) algebra and (dressed) q-deformed $W_N$ algebras. In this talk, I will explain how to extend this type of relations to the Wakimoto representations of quantum affine sl(N) algebras using the 'surface defect' deformation of the quantum toroidal sl(N) algebra.
2024/12/19
14:00-15:30 Room #002 (Graduate School of Math. Sci. Bldg.)
Omar Kidwai (The Chinese University of Hong Kong)
Quadratic differentials and Donaldson-Thomas invariants (English)
Omar Kidwai (The Chinese University of Hong Kong)
Quadratic differentials and Donaldson-Thomas invariants (English)
[ Abstract ]
We recall the relation between quadratic differentials and spaces of stability conditions due to Bridgeland-Smith. We describe the calculation of (refined) Donaldson-Thomas invariants for stability conditions on a certain class of 3-Calabi-Yau triangulated categories studied by Christ-Haiden-Qiu. This category is slightly different from the usual one discussed by Bridgeland and Smith, which in particular allows us to recover a nonzero invariant in the case where the quadratic differential has a second-order pole, in agreement with predictions from the physics literature. Based on joint work with N. Williams.
We recall the relation between quadratic differentials and spaces of stability conditions due to Bridgeland-Smith. We describe the calculation of (refined) Donaldson-Thomas invariants for stability conditions on a certain class of 3-Calabi-Yau triangulated categories studied by Christ-Haiden-Qiu. This category is slightly different from the usual one discussed by Bridgeland and Smith, which in particular allows us to recover a nonzero invariant in the case where the quadratic differential has a second-order pole, in agreement with predictions from the physics literature. Based on joint work with N. Williams.
2024/10/30
15:30-16:30 Room # (Graduate School of Math. Sci. Bldg.)
Shin'ichi Arita (The University of Tokyo)
Dirac作用素に対するRellich型の定理について (日本語)
Shin'ichi Arita (The University of Tokyo)
Dirac作用素に対するRellich型の定理について (日本語)
2024/10/16
15:30-16:30 Room #056 (Graduate School of Math. Sci. Bldg.)
Davide Dal Martello (Rikkyo University)
Convolutions, factorizations, and clusters from Painlevé VI (English)
Davide Dal Martello (Rikkyo University)
Convolutions, factorizations, and clusters from Painlevé VI (English)
[ Abstract ]
The Painlevé VI equation governs the isomonodromic deformation problem of both 2-dimensional Fuchsian and 3-dimensional Birkhoff systems. Through duality, this feature identifies the two systems. We prove this bijection admits a more transparent middle convolution formulation, which unlocks a monodromic translation involving the Killing factorization. Moreover, exploiting a higher Teichmüller parametrization of the monodromy group, Okamoto's birational map of PVI is given a new realization as a cluster transformation. Time permitting, we conclude with a taste of the quantum version of these constructions.
The Painlevé VI equation governs the isomonodromic deformation problem of both 2-dimensional Fuchsian and 3-dimensional Birkhoff systems. Through duality, this feature identifies the two systems. We prove this bijection admits a more transparent middle convolution formulation, which unlocks a monodromic translation involving the Killing factorization. Moreover, exploiting a higher Teichmüller parametrization of the monodromy group, Okamoto's birational map of PVI is given a new realization as a cluster transformation. Time permitting, we conclude with a taste of the quantum version of these constructions.
2024/10/10
10:00-11:30 Room #122 (Graduate School of Math. Sci. Bldg.)
Chiara Franceschini (University of Modena and Reggio Emilia)
Harmonic models out of equilibrium: duality relations and invariant measure (ENGLISH)
Chiara Franceschini (University of Modena and Reggio Emilia)
Harmonic models out of equilibrium: duality relations and invariant measure (ENGLISH)
[ Abstract ]
Zero-range interacting systems of Harmonic type have been recently introduced by Frassek, Giardinà and Kurchan [JSP 2020] from the integrable XXX Hamiltonian with non compact spins. In this talk I will introduce this one parameter family of models on a one dimensional lattice with open boundary whose dynamics describes redistribution of energy or jump of particles between nearest neighbor sites. These models belong to the same macroscopic class of the KMP model, introduced in 1982 by Kipnis Marchioro and Presutti. First, I will show their similar algebraic structure as well as their duality relations. Second, I will present how to explicitly characterize the invariant measure out of equilibrium, a task that is, in general, quite difficult in this context and it has been achieved in very few cases, e.g. the well known exclusion process. As an application, thanks to this characterization, it is possible to compute formulas predicted by macroscopic fluctuation theory.
This is from joint works with: Gioia Carinci, Rouven Frassek, Davide Gabrielli, Cirstian Giarinà, Frank Redig and Dimitrios Tsagkarogiannis.
Zero-range interacting systems of Harmonic type have been recently introduced by Frassek, Giardinà and Kurchan [JSP 2020] from the integrable XXX Hamiltonian with non compact spins. In this talk I will introduce this one parameter family of models on a one dimensional lattice with open boundary whose dynamics describes redistribution of energy or jump of particles between nearest neighbor sites. These models belong to the same macroscopic class of the KMP model, introduced in 1982 by Kipnis Marchioro and Presutti. First, I will show their similar algebraic structure as well as their duality relations. Second, I will present how to explicitly characterize the invariant measure out of equilibrium, a task that is, in general, quite difficult in this context and it has been achieved in very few cases, e.g. the well known exclusion process. As an application, thanks to this characterization, it is possible to compute formulas predicted by macroscopic fluctuation theory.
This is from joint works with: Gioia Carinci, Rouven Frassek, Davide Gabrielli, Cirstian Giarinà, Frank Redig and Dimitrios Tsagkarogiannis.
2024/07/29
10:30-12:00 Room #056 (Graduate School of Math. Sci. Bldg.)
John Alex Cruz Morales (National University of Colombia)
What would be equivariant mirror symmetry for Hitchin systems? (ENGLISH)
John Alex Cruz Morales (National University of Colombia)
What would be equivariant mirror symmetry for Hitchin systems? (ENGLISH)
[ Abstract ]
In some recent works Aganagic has introduced the idea of equivariant mirror symmetry for certain kind of hyperkahler manifolds. In this talk, after reviewing Aganagic's proposal, we will discuss how some parts of this framework could be used to study mirror symmetry of Hitchin systems. This is based on work in progress with O. Dumitrescu and M. Mulase.
In some recent works Aganagic has introduced the idea of equivariant mirror symmetry for certain kind of hyperkahler manifolds. In this talk, after reviewing Aganagic's proposal, we will discuss how some parts of this framework could be used to study mirror symmetry of Hitchin systems. This is based on work in progress with O. Dumitrescu and M. Mulase.
2023/12/15
13:00-14:30 Room #056 (Graduate School of Math. Sci. Bldg.)
Laszlo Feher (University of Szeged, Hungary)
Bi-Hamiltonian structures of integrable many-body models from Poisson reduction (ENGLISH)
Laszlo Feher (University of Szeged, Hungary)
Bi-Hamiltonian structures of integrable many-body models from Poisson reduction (ENGLISH)
[ Abstract ]
We review our results on bi-Hamiltonian structures of trigonometric spin Sutherland models
built on collective spin variables.
Our basic observation was that the cotangent bundle $T^*\mathrm{U}(n)$ and its holomorphic analogue $T^* \mathrm{GL}(n,{\mathbb C})$,
as well as $T^*\mathrm{GL}(n,{\mathbb C})_{\mathbb R}$, carry a natural quadratic Poisson bracket,
which is compatible with the canonical linear one. The quadratic bracket arises by change of variables and analytic continuation
from an associated Heisenberg double.
Then, the reductions of $T^*{\mathrm{U}}(n)$ and $T^*{\mathrm{GL}}(n,{\mathbb C})$ by the conjugation actions of the
corresponding groups lead to the real and holomorphic spin Sutherland models, respectively, equipped
with a bi-Hamiltonian structure. The reduction of $T^*{\mathrm{GL}}(n,{\mathbb C})_{\mathbb R}$ by the group $\mathrm{U}(n) \times \mathrm{U}(n)$ gives
a generalized Sutherland model coupled to two ${\mathfrak u}(n)^*$-valued spins.
We also show that
a bi-Hamiltonian structure on the associative algebra ${\mathfrak{gl}}(n,{\mathbb R})$ that appeared in the context
of Toda models can be interpreted as the quotient of compatible Poisson brackets on $T^*{\mathrm{GL}}(n,{\mathbb R})$.
Before our work, all these reductions were studied using the canonical Poisson structures of the cotangent bundles,
without realizing the bi-Hamiltonian aspect.
Finally, if time permits, the degenerate integrability of some of the reduced systems
will be explained as well.
[1] L. Feher, Reduction of a bi-Hamiltonian hierarchy on $T^*\mathrm{U}(n)$
to spin Ruijsenaars--Sutherland models, Lett. Math. Phys. 110, 1057-1079 (2020).
[2] L. Feher, Bi-Hamiltonian structure of spin Sutherland models: the holomorphic case, Ann. Henri Poincar\'e 22, 4063-4085 (2021).
[3] L. Feher, Bi-Hamiltonian structure of Sutherland models coupled to two $\mathfrak{u}(n)^*$-valued spins from Poisson reduction,
Nonlinearity 35, 2971-3003 (2022).
[4] L. Feher and B. Juhasz,
A note on quadratic Poisson brackets on $\mathfrak{gl}(n,\mathbb{R})$ related to Toda lattices,
Lett. Math. Phys. 112:45 (2022).
[5] L. Feher,
Notes on the degenerate integrability of reduced systems obtained from the master systems of free motion on cotangent bundles of
compact Lie groups, arXiv:2309.16245
We review our results on bi-Hamiltonian structures of trigonometric spin Sutherland models
built on collective spin variables.
Our basic observation was that the cotangent bundle $T^*\mathrm{U}(n)$ and its holomorphic analogue $T^* \mathrm{GL}(n,{\mathbb C})$,
as well as $T^*\mathrm{GL}(n,{\mathbb C})_{\mathbb R}$, carry a natural quadratic Poisson bracket,
which is compatible with the canonical linear one. The quadratic bracket arises by change of variables and analytic continuation
from an associated Heisenberg double.
Then, the reductions of $T^*{\mathrm{U}}(n)$ and $T^*{\mathrm{GL}}(n,{\mathbb C})$ by the conjugation actions of the
corresponding groups lead to the real and holomorphic spin Sutherland models, respectively, equipped
with a bi-Hamiltonian structure. The reduction of $T^*{\mathrm{GL}}(n,{\mathbb C})_{\mathbb R}$ by the group $\mathrm{U}(n) \times \mathrm{U}(n)$ gives
a generalized Sutherland model coupled to two ${\mathfrak u}(n)^*$-valued spins.
We also show that
a bi-Hamiltonian structure on the associative algebra ${\mathfrak{gl}}(n,{\mathbb R})$ that appeared in the context
of Toda models can be interpreted as the quotient of compatible Poisson brackets on $T^*{\mathrm{GL}}(n,{\mathbb R})$.
Before our work, all these reductions were studied using the canonical Poisson structures of the cotangent bundles,
without realizing the bi-Hamiltonian aspect.
Finally, if time permits, the degenerate integrability of some of the reduced systems
will be explained as well.
[1] L. Feher, Reduction of a bi-Hamiltonian hierarchy on $T^*\mathrm{U}(n)$
to spin Ruijsenaars--Sutherland models, Lett. Math. Phys. 110, 1057-1079 (2020).
[2] L. Feher, Bi-Hamiltonian structure of spin Sutherland models: the holomorphic case, Ann. Henri Poincar\'e 22, 4063-4085 (2021).
[3] L. Feher, Bi-Hamiltonian structure of Sutherland models coupled to two $\mathfrak{u}(n)^*$-valued spins from Poisson reduction,
Nonlinearity 35, 2971-3003 (2022).
[4] L. Feher and B. Juhasz,
A note on quadratic Poisson brackets on $\mathfrak{gl}(n,\mathbb{R})$ related to Toda lattices,
Lett. Math. Phys. 112:45 (2022).
[5] L. Feher,
Notes on the degenerate integrability of reduced systems obtained from the master systems of free motion on cotangent bundles of
compact Lie groups, arXiv:2309.16245
2023/12/06
13:00-14:30 Room #056 (Graduate School of Math. Sci. Bldg.)
Misha Feigin (University of Glasgow)
This seminar has been cancelled.
Flat coordinates of algebraic Frobenius manifolds (ENGLISH)
Misha Feigin (University of Glasgow)
This seminar has been cancelled.
Flat coordinates of algebraic Frobenius manifolds (ENGLISH)
[ Abstract ]
This seminar has been cancelled.
Orbit spaces of the reflection representation of finite irreducible Coxeter groups provide Frobenius manifolds with polynomial prepotentials. Flat coordinates of the corresponding flat metric, known as Saito metric, are distinguished basic invariants of the Coxeter group. They have applications in representations of Cherednik algebras. Frobenius manifolds with algebraic prepotentials remain not classified and they are typically related to quasi-Coxeter conjugacy classes in finite Coxeter groups. We obtain flat coordinates for the majority of known examples of algebraic Frobenius manifolds in dimensions up to 4. In all the cases, flat coordinates appear to be some algebraic functions on the orbit space of the Coxeter group. This is a joint work with Daniele Valeri and Johan Wright.
This seminar has been cancelled.
Orbit spaces of the reflection representation of finite irreducible Coxeter groups provide Frobenius manifolds with polynomial prepotentials. Flat coordinates of the corresponding flat metric, known as Saito metric, are distinguished basic invariants of the Coxeter group. They have applications in representations of Cherednik algebras. Frobenius manifolds with algebraic prepotentials remain not classified and they are typically related to quasi-Coxeter conjugacy classes in finite Coxeter groups. We obtain flat coordinates for the majority of known examples of algebraic Frobenius manifolds in dimensions up to 4. In all the cases, flat coordinates appear to be some algebraic functions on the orbit space of the Coxeter group. This is a joint work with Daniele Valeri and Johan Wright.
2023/04/24
16:00-17:30 Room #123 (Graduate School of Math. Sci. Bldg.)
Takahiko Nobukawa (Kobe University )
Euler type integral formulas and hypergeometric solutions for
variants of the $q$ hypergeometric equations.
(Japanese)
Takahiko Nobukawa (Kobe University )
Euler type integral formulas and hypergeometric solutions for
variants of the $q$ hypergeometric equations.
(Japanese)
[ Abstract ]
We know that Papperitz's differential equation is essentially obtained from
Gauss' hypergeometric equation by applying a Moebius transformation,
implying that we have Euler type integral formulas or hypergeometric solutions.
The variants of the $q$ hypergeometric equations, introduced by
Hatano-Matsunawa-Sato-Takemura (Funkcial. Ekvac.,2022), are second order
$q$-difference systems which can be regarded as $q$ analoges of Papperitz's equation.
This motivates us for deriving Euler type integral formulas and hypergeometric solutions
for the pertinent $q$-difference systems. If time admits, I explain
the relation with $q$-analogues of Kummer's 24 solutions,
or the variants of multivariate $q$-hypergeometric functions.
This talk is based on the collaboration with Taikei Fujii.
We know that Papperitz's differential equation is essentially obtained from
Gauss' hypergeometric equation by applying a Moebius transformation,
implying that we have Euler type integral formulas or hypergeometric solutions.
The variants of the $q$ hypergeometric equations, introduced by
Hatano-Matsunawa-Sato-Takemura (Funkcial. Ekvac.,2022), are second order
$q$-difference systems which can be regarded as $q$ analoges of Papperitz's equation.
This motivates us for deriving Euler type integral formulas and hypergeometric solutions
for the pertinent $q$-difference systems. If time admits, I explain
the relation with $q$-analogues of Kummer's 24 solutions,
or the variants of multivariate $q$-hypergeometric functions.
This talk is based on the collaboration with Taikei Fujii.
2020/02/18
15:00-16:00 Room #002 (Graduate School of Math. Sci. Bldg.)
Vincent Pasquier (IPhT Saclay)
Hydrodynamics of a one dimensional lattice gas.
(ENGLISH)
Vincent Pasquier (IPhT Saclay)
Hydrodynamics of a one dimensional lattice gas.
(ENGLISH)
[ Abstract ]
The simplest boxball model is a one dimensional lattice gas obtained as
a certain (cristal) limit of the six vertex model where the evolution
determined by the transfer matrix becomes deterministic. One can
study its thermodynamics in and out of equilibrium and we shall present
preliminary results in this direction.
Collaboration with Atsuo Kuniba and Grégoire Misguich.
The simplest boxball model is a one dimensional lattice gas obtained as
a certain (cristal) limit of the six vertex model where the evolution
determined by the transfer matrix becomes deterministic. One can
study its thermodynamics in and out of equilibrium and we shall present
preliminary results in this direction.
Collaboration with Atsuo Kuniba and Grégoire Misguich.
2019/12/17
15:00-16:00 Room #駒場国際教育研究棟(旧6号館)108 (Graduate School of Math. Sci. Bldg.)
Ryo Ohkawa (Waseda University)
(-2) blow-up formula (JAPANESE)
Ryo Ohkawa (Waseda University)
(-2) blow-up formula (JAPANESE)
[ Abstract ]
In this talk, we will consider the moduli of ADHM data
corresponding to the affine A_1 Dynkin diagram.
It is a moduli of framed sheaves on the (-2) curve or the projective
plane with a group action.
Each of these two types of moduli integrals has a combinatorial
description. In particular, the Hirota derivative of the Nekrasov
function can be obtained on the (-2) curve.
We introduce equalities among these two integrals and the
corresponding functional equations in some cases.
This is similar to the blow-up formula by Nakajima-Yoshioka.
I would also like to talk about relationships with the study of the
Painleve tau function by Bershtein-Shchechkin.
In this talk, we will consider the moduli of ADHM data
corresponding to the affine A_1 Dynkin diagram.
It is a moduli of framed sheaves on the (-2) curve or the projective
plane with a group action.
Each of these two types of moduli integrals has a combinatorial
description. In particular, the Hirota derivative of the Nekrasov
function can be obtained on the (-2) curve.
We introduce equalities among these two integrals and the
corresponding functional equations in some cases.
This is similar to the blow-up formula by Nakajima-Yoshioka.
I would also like to talk about relationships with the study of the
Painleve tau function by Bershtein-Shchechkin.
2018/12/25
16:00-17:00 Room #002 (Graduate School of Math. Sci. Bldg.)
Takashi Takebe (National Research University Higher School of Economics (Moscow))
Q-operators for generalised eight vertex models associated
to the higher spin representations of the Sklyanin algebra. (ENGLISH)
Takashi Takebe (National Research University Higher School of Economics (Moscow))
Q-operators for generalised eight vertex models associated
to the higher spin representations of the Sklyanin algebra. (ENGLISH)
[ Abstract ]
The Q-operator was first introduced by Baxter in 1972 as a
tool to solve the eight vertex model and recently attracts
attention from the representation theoretical viewpoint. In
this talk, we show that Baxter's apparently quite ad hoc and
technical construction can be generalised to the model
associated to the higher spin representations of the
Sklyanin algebra. If everybody in the audience understands Japanese, the talk
will be in Japanese.
The Q-operator was first introduced by Baxter in 1972 as a
tool to solve the eight vertex model and recently attracts
attention from the representation theoretical viewpoint. In
this talk, we show that Baxter's apparently quite ad hoc and
technical construction can be generalised to the model
associated to the higher spin representations of the
Sklyanin algebra. If everybody in the audience understands Japanese, the talk
will be in Japanese.
2018/12/06
16:00-17:00 Room #002 (Graduate School of Math. Sci. Bldg.)
Francesco Ravanini (University of Bologna)
Integrability and TBA in non-equilibrium emergent hydrodynamics (ENGLISH)
Francesco Ravanini (University of Bologna)
Integrability and TBA in non-equilibrium emergent hydrodynamics (ENGLISH)
[ Abstract ]
The paradigm of investigating non-equilibrium phenomena by considering stationary states of emergent hydrodynamics has attracted a lot of attention in the last years. Recent proposals of an exact approach in integrable cases, making use of TBA techniques, are presented and discussed.
The paradigm of investigating non-equilibrium phenomena by considering stationary states of emergent hydrodynamics has attracted a lot of attention in the last years. Recent proposals of an exact approach in integrable cases, making use of TBA techniques, are presented and discussed.
2018/10/04
16:00-17:00 Room #002 (Graduate School of Math. Sci. Bldg.)
Andrew Kels (Graduate School of Arts and Sciences, University of Tokyo)
Integrable quad equations derived from the quantum Yang-Baxter
equation. (ENGLISH)
Andrew Kels (Graduate School of Arts and Sciences, University of Tokyo)
Integrable quad equations derived from the quantum Yang-Baxter
equation. (ENGLISH)
[ Abstract ]
I will give an overview of an explicit correspondence that exists between
two different types of integrable equations; 1) the quantum Yang-Baxter
equation in its star-triangle relation (STR) form, and 2) the classical
3D-consistent quad equations in the Adler-Bobenko-Suris (ABS)
classification. The fundamental aspect of this correspondence is that the
equation of the critical point of a STR is equivalent to an ABS quad
equation. The STR's considered here are in fact equivalent to
hypergeometric integral transformation formulas. For example, a STR for
$H1_{(\varepsilon=0)}$ corresponds to the Euler Beta function, a STR for
$Q1_{(\delta=0)}$ corresponds to the $n=1$ Selberg integral, and STR's for
$H2_{\varepsilon=0,1}$, $H1_{(\varepsilon=1)}$, correspond to different
hypergeometric integral formulas of Barnes. I will discuss some of these
examples and some directions for future research.
I will give an overview of an explicit correspondence that exists between
two different types of integrable equations; 1) the quantum Yang-Baxter
equation in its star-triangle relation (STR) form, and 2) the classical
3D-consistent quad equations in the Adler-Bobenko-Suris (ABS)
classification. The fundamental aspect of this correspondence is that the
equation of the critical point of a STR is equivalent to an ABS quad
equation. The STR's considered here are in fact equivalent to
hypergeometric integral transformation formulas. For example, a STR for
$H1_{(\varepsilon=0)}$ corresponds to the Euler Beta function, a STR for
$Q1_{(\delta=0)}$ corresponds to the $n=1$ Selberg integral, and STR's for
$H2_{\varepsilon=0,1}$, $H1_{(\varepsilon=1)}$, correspond to different
hypergeometric integral formulas of Barnes. I will discuss some of these
examples and some directions for future research.
2018/09/25
16:00-17:00 Room #002 (Graduate School of Math. Sci. Bldg.)
Nobutaka Nakazono (Aoyama Gakuin University Department of Physics and Mathematics)
Classification of quad-equations on a cuboctahedron (JAPANESE)
Nobutaka Nakazono (Aoyama Gakuin University Department of Physics and Mathematics)
Classification of quad-equations on a cuboctahedron (JAPANESE)
[ Abstract ]
Adelr-Bobenko-Suris (2003, 2009) and Boll (2011) classified quad-equations on a cube using a consistency around a cube. By use of this consistency, we can define integrable two-dimensional partial difference equations called ABS equations. A major example of ABS equation is the lattice modified KdV equation, which is a discrete analogue of the modified KdV equation. It is known that Lax representations and Backlund transformations of ABS equations can be constructed by using the consistency around a cube, and ABS equations can be reduced to differential and difference Painlevé equations via periodically reductions.
In this talk, we show a classification of quad-equations on a cuboctahedron using a consistency around a cuboctahedron and the relation between a resulting partial difference equation and a discrete Painlevé equation.
This work has been done in collaboration with Prof Nalini Joshi (The University of Sydney).
Adelr-Bobenko-Suris (2003, 2009) and Boll (2011) classified quad-equations on a cube using a consistency around a cube. By use of this consistency, we can define integrable two-dimensional partial difference equations called ABS equations. A major example of ABS equation is the lattice modified KdV equation, which is a discrete analogue of the modified KdV equation. It is known that Lax representations and Backlund transformations of ABS equations can be constructed by using the consistency around a cube, and ABS equations can be reduced to differential and difference Painlevé equations via periodically reductions.
In this talk, we show a classification of quad-equations on a cuboctahedron using a consistency around a cuboctahedron and the relation between a resulting partial difference equation and a discrete Painlevé equation.
This work has been done in collaboration with Prof Nalini Joshi (The University of Sydney).
2018/07/17
16:00-17:00 Room #002 (Graduate School of Math. Sci. Bldg.)
Valerii Sopin: (Higher School of Economics (Moscow))
Operator algebra for statistical model of square ladder (ENGLISH)
Valerii Sopin: (Higher School of Economics (Moscow))
Operator algebra for statistical model of square ladder (ENGLISH)
[ Abstract ]
In this talk we will define operator algebra for square ladder on the basis
of semi-infinite forms.
Keywords: hard-square model, square ladder, operator algebra, semi-infinite
forms, fermions, quadratic algebra, cohomology, Demazure modules,
Heisenberg algebra.
In this talk we will define operator algebra for square ladder on the basis
of semi-infinite forms.
Keywords: hard-square model, square ladder, operator algebra, semi-infinite
forms, fermions, quadratic algebra, cohomology, Demazure modules,
Heisenberg algebra.
2018/04/03
15:00-16:00 Room #002 (Graduate School of Math. Sci. Bldg.)
Naoki Genra (RIMS, Kyoto U.)
Screening Operators and Parabolic inductions for W-algebras
(ENGLISH)
Naoki Genra (RIMS, Kyoto U.)
Screening Operators and Parabolic inductions for W-algebras
(ENGLISH)
[ Abstract ]
(Affine) W-algebras are the family of vertex algebras defined by
Drinfeld-Sokolov reductions. We introduce the free field realizations of
W-algebras by the Wakimoto representations of affine Lie algebras, which
we call the Wakimoto representations of W-algebras. Then W-algebras may be
described as the intersections of the kernels of the screening operators.
As applications, the parabolic inductions for W-algebras are obtained.
This is motivated by results of Premet and Losev on finite W-algebras. In
A-types, this becomes a chiralization of coproducts by Brundan-Kleshchev.
In BCD-types, we also have analogue results in special cases.
(Affine) W-algebras are the family of vertex algebras defined by
Drinfeld-Sokolov reductions. We introduce the free field realizations of
W-algebras by the Wakimoto representations of affine Lie algebras, which
we call the Wakimoto representations of W-algebras. Then W-algebras may be
described as the intersections of the kernels of the screening operators.
As applications, the parabolic inductions for W-algebras are obtained.
This is motivated by results of Premet and Losev on finite W-algebras. In
A-types, this becomes a chiralization of coproducts by Brundan-Kleshchev.
In BCD-types, we also have analogue results in special cases.
2018/03/27
15:00-16:00 Room #002 (Graduate School of Math. Sci. Bldg.)
Yoshiki Fukusumi (The University of Tokyo, The Institute for Solid State Physics)
Schramm-Loewner evolutions and Liouville field theory (JAPANESE)
Yoshiki Fukusumi (The University of Tokyo, The Institute for Solid State Physics)
Schramm-Loewner evolutions and Liouville field theory (JAPANESE)
[ Abstract ]
Schramm-Loewner evolutions (SLEs) are stochastic processes driven by Brownian motions which preserves conformal invariance. They describe the cluster boundaries associated with the minimal models of the conformal field theory, including the Ising model and the percolation as typical examples. The correlation functions of such models remarkably satisfy the martingale condition. We briefly review some known results. Then we analyse the time reversing procedure of Schramm Loewner evolutions and its relation to Liouville field theory or 2d pure gravity. We can get martingale observables by the calculation of the correlation functions of Liouville field theory without matter.
Schramm-Loewner evolutions (SLEs) are stochastic processes driven by Brownian motions which preserves conformal invariance. They describe the cluster boundaries associated with the minimal models of the conformal field theory, including the Ising model and the percolation as typical examples. The correlation functions of such models remarkably satisfy the martingale condition. We briefly review some known results. Then we analyse the time reversing procedure of Schramm Loewner evolutions and its relation to Liouville field theory or 2d pure gravity. We can get martingale observables by the calculation of the correlation functions of Liouville field theory without matter.
2018/02/06
15:00-17:30 Room #002 (Graduate School of Math. Sci. Bldg.)
Hosho Katsura (Department of Physics, Graduate School of Science, The Univeristy of Tokyo ) 15:00-16:00
Sine-square deformation of one-dimensional critical systems (ENGLISH)
Modular invariant representations of the $N=2$ vertex operator superalgebra (ENGLISH)
Hosho Katsura (Department of Physics, Graduate School of Science, The Univeristy of Tokyo ) 15:00-16:00
Sine-square deformation of one-dimensional critical systems (ENGLISH)
[ Abstract ]
Sine-square deformation (SSD) is one example of smooth boundary conditions that have significantly smaller finite-size effects than open boundary conditions. In a one-dimensional system with SSD, the interaction strength varies smoothly from the center to the edges according to the sine-square function. This means that the Hamiltonian of the system is inhomogeneous, as it lacks translational symmetry. Nevertheless, previous studies have revealed that the SSD leaves the ground state of the uniform chain with periodic boundary conditions (PBC) almost unchanged for critical systems. In particular, I showed in [1,2,3] that the correspondence is exact for critical XY and quantum Ising chains. The same correspondence between SSD and PBC holds for Dirac fermions in 1+1 dimension and a family of more general conformal field theories. If time permits, I will also introduce more recent results [4,5] and discuss the excited states of the SSD systems.
[1] H. Katsura, J. Phys. A: Math. Theor. 44, 252001 (2011).
[2] H. Katsura, J. Phys. A: Math. Theor. 45, 115003 (2012).
[3] I. Maruyama, H. Katsura, T. Hikihara, Phys. Rev. B 84, 165132 (2011).
[4] K. Okunishi and H. Katsura, J. Phys. A: Math. Theor. 48, 445208 (2015).
[5] S. Tamura and H. Katsura, Prog. Theor. Exp. Phys 2017, 113A01 (2017).
Ryo Sato (Graduate School of Mathematical Sciences, The University of Tokyo) 16:30-17:30Sine-square deformation (SSD) is one example of smooth boundary conditions that have significantly smaller finite-size effects than open boundary conditions. In a one-dimensional system with SSD, the interaction strength varies smoothly from the center to the edges according to the sine-square function. This means that the Hamiltonian of the system is inhomogeneous, as it lacks translational symmetry. Nevertheless, previous studies have revealed that the SSD leaves the ground state of the uniform chain with periodic boundary conditions (PBC) almost unchanged for critical systems. In particular, I showed in [1,2,3] that the correspondence is exact for critical XY and quantum Ising chains. The same correspondence between SSD and PBC holds for Dirac fermions in 1+1 dimension and a family of more general conformal field theories. If time permits, I will also introduce more recent results [4,5] and discuss the excited states of the SSD systems.
[1] H. Katsura, J. Phys. A: Math. Theor. 44, 252001 (2011).
[2] H. Katsura, J. Phys. A: Math. Theor. 45, 115003 (2012).
[3] I. Maruyama, H. Katsura, T. Hikihara, Phys. Rev. B 84, 165132 (2011).
[4] K. Okunishi and H. Katsura, J. Phys. A: Math. Theor. 48, 445208 (2015).
[5] S. Tamura and H. Katsura, Prog. Theor. Exp. Phys 2017, 113A01 (2017).
Modular invariant representations of the $N=2$ vertex operator superalgebra (ENGLISH)
[ Abstract ]
One of the most remarkable features in representation theory of a (``good'') vertex operator superalgebra (VOSA) is the modular invariance property of the characters. As an application of the property, M. Wakimoto and D. Adamovic proved that all the fusion rules for the simple $N=2$ VOSA of central charge $c_{p,1}=3(1-2/p)$ are computed from the modular $S$-matrix by the so-called Verlinde formula. In this talk, we present a new ``modular invariant'' family of irreducible highest weight modules over the simple $N=2$ VOSA of central charge $c_{p,p'}:=3(1-2p'/p)$. Here $(p,p')$ is a pair of coprime integers such that $p,p'>1$. In addition, we will discuss some generalization of the Verlinde formula in the spirit of Creutzig--Ridout.
One of the most remarkable features in representation theory of a (``good'') vertex operator superalgebra (VOSA) is the modular invariance property of the characters. As an application of the property, M. Wakimoto and D. Adamovic proved that all the fusion rules for the simple $N=2$ VOSA of central charge $c_{p,1}=3(1-2/p)$ are computed from the modular $S$-matrix by the so-called Verlinde formula. In this talk, we present a new ``modular invariant'' family of irreducible highest weight modules over the simple $N=2$ VOSA of central charge $c_{p,p'}:=3(1-2p'/p)$. Here $(p,p')$ is a pair of coprime integers such that $p,p'>1$. In addition, we will discuss some generalization of the Verlinde formula in the spirit of Creutzig--Ridout.
2017/11/10
17:00-18:30 Room #122 (Graduate School of Math. Sci. Bldg.)
Fabio Novaes (International Institute of Physics (UFRN))
Chern-Simons, gravity and integrable systems. (ENGLISH)
http://www.iip.ufrn.br/eventslecturer?inf==0EVRpXTR1TP
Fabio Novaes (International Institute of Physics (UFRN))
Chern-Simons, gravity and integrable systems. (ENGLISH)
[ Abstract ]
It is known since the 80's that pure three-dimensional gravity is classically equivalent to a Chern-Simons theory with gauge group SL(2,R) x SL(2,R). For a given set of boundary conditions, the asymptotic classical phase space has a central extension in terms of two copies of Virasoro algebra. In particular, this gives a conformal field theory representation of black hole solutions in 3d gravity, also known as BTZ black holes. The BTZ black hole entropy can then be recovered using CFT. In this talk, we review this story and discuss recent results on how to relax the BTZ boundary conditions to obtain the KdV hierarchy at the boundary. More generally, this shows that Chern-Simons theory can represent virtually any integrable system at the boundary, given some consistency conditions. We also briefly discuss how this formulation can be useful to describe non-relativistic systems.
[ Reference URL ]It is known since the 80's that pure three-dimensional gravity is classically equivalent to a Chern-Simons theory with gauge group SL(2,R) x SL(2,R). For a given set of boundary conditions, the asymptotic classical phase space has a central extension in terms of two copies of Virasoro algebra. In particular, this gives a conformal field theory representation of black hole solutions in 3d gravity, also known as BTZ black holes. The BTZ black hole entropy can then be recovered using CFT. In this talk, we review this story and discuss recent results on how to relax the BTZ boundary conditions to obtain the KdV hierarchy at the boundary. More generally, this shows that Chern-Simons theory can represent virtually any integrable system at the boundary, given some consistency conditions. We also briefly discuss how this formulation can be useful to describe non-relativistic systems.
http://www.iip.ufrn.br/eventslecturer?inf==0EVRpXTR1TP
2017/05/30
17:30-18:30 Room #002 (Graduate School of Math. Sci. Bldg.)
Soichi Okada (Graduate School of Mathematics, Nagoya University)
$Q$-functions associated to the root system of type $C$ (JAPANESE)
Soichi Okada (Graduate School of Mathematics, Nagoya University)
$Q$-functions associated to the root system of type $C$ (JAPANESE)
[ Abstract ]
Schur $Q$-functions are a family of symmetric functions introduced
by Schur in his study of projective representations of symmetric
groups. They are obtained by putting $t=-1$ in the Hall-Littlewood
functions associated to the root system of type $A$. (Schur
functions are the $t=0$ specialization.) This talk concerns
symplectic $Q$-functions, which are obtained by putting $t=-1$
in the Hall-Littlewood functions associated to the root system
of type $C$. We discuss several Pfaffian identities as well
as a combinatorial description for them. Also we present some
positivity conjectures.
Schur $Q$-functions are a family of symmetric functions introduced
by Schur in his study of projective representations of symmetric
groups. They are obtained by putting $t=-1$ in the Hall-Littlewood
functions associated to the root system of type $A$. (Schur
functions are the $t=0$ specialization.) This talk concerns
symplectic $Q$-functions, which are obtained by putting $t=-1$
in the Hall-Littlewood functions associated to the root system
of type $C$. We discuss several Pfaffian identities as well
as a combinatorial description for them. Also we present some
positivity conjectures.
2016/12/22
14:00-17:30 Room #002 (Graduate School of Math. Sci. Bldg.)
Yuta Nozaki (Graduate School of Mathematical Sciences, the University of Tokyo) 14:00-15:30
Homology cobordisms over a surface of genus one (JAPANESE)
Generalization of Schur partition theorem (JAPANESE)
Yuta Nozaki (Graduate School of Mathematical Sciences, the University of Tokyo) 14:00-15:30
Homology cobordisms over a surface of genus one (JAPANESE)
[ Abstract ]
Morimoto showed that some lens spaces have no genus one fibered knot,
and Baker completely determined such lens spaces.
In this talk, we introduce our results for the corresponding problem
formulated in terms of homology cobordisms.
The Chebotarev density theorem and binary quadratic forms play a key
role in the proof.
Shunsuke Tsuchioka (Graduate School of Mathematical Sciences, the University of Tokyo) 16:00-17:30Morimoto showed that some lens spaces have no genus one fibered knot,
and Baker completely determined such lens spaces.
In this talk, we introduce our results for the corresponding problem
formulated in terms of homology cobordisms.
The Chebotarev density theorem and binary quadratic forms play a key
role in the proof.
Generalization of Schur partition theorem (JAPANESE)
[ Abstract ]
The celebrated Rogers-Ramanujan partition theorem (RRPT) claims that
the number of partitions of n whose parts are ¥pm1 modulo 5
is equinumerous to the number of partitions of n whose successive
differences are
at least 2. Schur found a mod 6 analog of RRPT in 1926.
We will report a generalization for odd $p¥geq 3$ via representation
theory of quantum groups.
At p=3, it is Schur's theorem. The statement for p=5 was conjectured by
Andrews in 1970s
in a course of his 3 parameter generalization of RRPT and proved in 1994
by Andrews-Bessenrodt-Olsson with an aid of computer.
This is a joint work with Masaki Watanabe (arXiv:1609.01905).
The celebrated Rogers-Ramanujan partition theorem (RRPT) claims that
the number of partitions of n whose parts are ¥pm1 modulo 5
is equinumerous to the number of partitions of n whose successive
differences are
at least 2. Schur found a mod 6 analog of RRPT in 1926.
We will report a generalization for odd $p¥geq 3$ via representation
theory of quantum groups.
At p=3, it is Schur's theorem. The statement for p=5 was conjectured by
Andrews in 1970s
in a course of his 3 parameter generalization of RRPT and proved in 1994
by Andrews-Bessenrodt-Olsson with an aid of computer.
This is a joint work with Masaki Watanabe (arXiv:1609.01905).
2016/11/10
15:00-17:00 Room #002 (Graduate School of Math. Sci. Bldg.)
Yohei Kashima (Graduate School of Mathematical Scineces, The University of Tokyo)
Superconducting phase in the BCS model with imaginary
magnetic field (JAPANESE)
Yohei Kashima (Graduate School of Mathematical Scineces, The University of Tokyo)
Superconducting phase in the BCS model with imaginary
magnetic field (JAPANESE)
[ Abstract ]
We prove that in the BCS model with an imaginary magnetic field
at positive temperature a spontaneous symmetry breaking (SSB) and
an off-diagonal long range order (ODLRO) occur. Here the BCS model
is meant to be a self-adjoint operator on the Fermionic Fock space,
consisting of a free part describing the electrons' nearest neighbor
hopping and a quartic interacting part describing a long range
interaction between Cooper pairs. The interaction with the imaginary
magnetic field is given by the z-component of the spin operator
multiplied by a pure imaginary parameter. The SSB and the ODLRO are
shown in the infinite-volume limit of the thermal average over the
full Fermionic Fock space. The insertion of the imaginary magnetic
field changes the gap equation. Consequently the SSB and the ODLRO
are shown in high temperature, weak coupling regimes where these
phenomena do not take place in the conventional BCS model. The proof
is based on the method of Grassmann integration.
We prove that in the BCS model with an imaginary magnetic field
at positive temperature a spontaneous symmetry breaking (SSB) and
an off-diagonal long range order (ODLRO) occur. Here the BCS model
is meant to be a self-adjoint operator on the Fermionic Fock space,
consisting of a free part describing the electrons' nearest neighbor
hopping and a quartic interacting part describing a long range
interaction between Cooper pairs. The interaction with the imaginary
magnetic field is given by the z-component of the spin operator
multiplied by a pure imaginary parameter. The SSB and the ODLRO are
shown in the infinite-volume limit of the thermal average over the
full Fermionic Fock space. The insertion of the imaginary magnetic
field changes the gap equation. Consequently the SSB and the ODLRO
are shown in high temperature, weak coupling regimes where these
phenomena do not take place in the conventional BCS model. The proof
is based on the method of Grassmann integration.
