Counterexamples in scale calculus

We construct counterexamples to classical calculus facts such as the inverse and implicit function theorems in scale calculus—a generalization of multivariable calculus to infinite-dimensional vector spaces, in which the reparameterization maps relevant to symplectic geometry are smooth. Scale calculus is a corner stone of polyfold theory, which was introduced by Hofer, Wysocki, and Zehnder as a broadly applicable tool for regularizing moduli spaces of pseudoholomorphic curves. We show how the novel nonlinear scale-Fredholm notion in polyfold theory overcomes the lack of implicit function theorems, by formally establishing an often implicitly used fact: The differentials of basic germs—the local models for scale-Fredholm maps—vary continuously in the space of bounded operators when the base point changes. We moreover demonstrate that this continuity holds only in specific coordinates, by constructing an example of a scale-diffeomorphism and scale-Fredholm map with discontinuous differentials. This justifies the high technical complexity in the foundations of polyfold theory.

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Normal form of equivariant maps in infinite dimensions

Annals of Global Analysis and Geometry ◽

10.1007/s10455-021-09777-2 ◽

2021 ◽

Author(s):

Tobias Diez ◽

Gerd Rudolph

Keyword(s):

Normal Form ◽

Moduli Space ◽

Moduli Spaces ◽

Infinite Dimensions ◽

Pseudoholomorphic Curves ◽

Infinite Dimensional ◽

Equivariant Maps ◽

Slice Theorem ◽

Smooth Map ◽

Main Technical Tool

AbstractLocal normal form theorems for smooth equivariant maps between infinite-dimensional manifolds are established. These normal form results are new even in finite dimensions. The proof is inspired by the Lyapunov–Schmidt reduction for dynamical systems and by the Kuranishi method for moduli spaces. It uses a slice theorem for Fréchet manifolds as the main technical tool. As a consequence, the abstract moduli space obtained by factorizing a level set of the equivariant map with respect to the group action carries the structure of a Kuranishi space, i.e., such moduli spaces are locally modeled on the quotient by a compact group of the zero set of a smooth map. The general results are applied to the moduli space of anti-self-dual instantons, the Seiberg–Witten moduli space and the moduli space of pseudoholomorphic curves.

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Infinitely entangled states

Quantum Information and Computation ◽

10.26421/qic3.4-1 ◽

2003 ◽

Vol 3 (4) ◽

pp. 281-306

Author(s):

M. Keyl ◽

D. Schlingemann ◽

R.F. Werner

Keyword(s):

Hilbert Spaces ◽

Degrees Of Freedom ◽

Entangled States ◽

Entangled State ◽

Bounded Operators ◽

Infinite Dimensional ◽

Infinite Dimensional Hilbert Space ◽

Density Operators ◽

Fundamental Paper ◽

Extended Notion

For states in infinite dimensional Hilbert spaces entanglement quantities like the entanglement of distillation can become infinite. This leads naturally to the question, whether one system in such an infinitely entangled state can serve as a resource for tasks like the teleportation of arbitrarily many qubits. We show that appropriate states cannot be obtained by density operators in an infinite dimensional Hilbert space. However, using techniques for the description of infinitely many degrees of freedom from field theory and statistical mechanics, such states can nevertheless be constructed rigorously. We explore two related possibilities, namely an extended notion of algebras of observables, and the use of singular states on the algebra of bounded operators. As applications we construct the essentially unique infinite analogue of maximally entangled states, and the singular state used heuristically in the fundamental paper of Einstein, Rosen and Podolsky.

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