What Makes a Classical Concept Classical? Toward a
... My aim in the present paper is to develop a new interpretation, or better, a reconstruction of the doctrine of classical concepts that seeks to be faithful to Bohr’s words, and, at the same time, to make both physical and philosophical sense. At the heart of this reconstruction are proposals regardi ...
... My aim in the present paper is to develop a new interpretation, or better, a reconstruction of the doctrine of classical concepts that seeks to be faithful to Bohr’s words, and, at the same time, to make both physical and philosophical sense. At the heart of this reconstruction are proposals regardi ...
QUANTUM COMPUTING
... reported at the end of this preface, the reader can find the list of references I considered to prepare the lectures on quantum computing I have been holding at the Department of Physics of the University of Milan: each book has particular aspects that I appreciated and, therefore, I wanted to commu ...
... reported at the end of this preface, the reader can find the list of references I considered to prepare the lectures on quantum computing I have been holding at the Department of Physics of the University of Milan: each book has particular aspects that I appreciated and, therefore, I wanted to commu ...
Quantum fluctuation relations: Foundations and applications
... Eq. (2). Bochkov and Kuzovlev (1977, 1979, 1981a, 1981b) proved Eq. (14) for classical systems. Their derivation will be reviewed in the next section. The quantum version, Eq. (55), was not reported until recently (Andrieux and Gaspard, 2008). In Sec. III.C we discuss the fundamental obstacles that ...
... Eq. (2). Bochkov and Kuzovlev (1977, 1979, 1981a, 1981b) proved Eq. (14) for classical systems. Their derivation will be reviewed in the next section. The quantum version, Eq. (55), was not reported until recently (Andrieux and Gaspard, 2008). In Sec. III.C we discuss the fundamental obstacles that ...
entanglement properties of quantum many
... used to describe strongly correlated quantum many-body systems in condensedmatter physics, hadronic physics, and quantum chemistry. The information gained in such a program should improve our understanding of quantum phase transitions occurring in these systems as well as their behavior in regions a ...
... used to describe strongly correlated quantum many-body systems in condensedmatter physics, hadronic physics, and quantum chemistry. The information gained in such a program should improve our understanding of quantum phase transitions occurring in these systems as well as their behavior in regions a ...
Kazakov - From Sigma Models to Four-dimensional QFT
... Baxter’s TQ and QQ operatorial relations and nested Bethe ansatz equations from new Master identity. Wronskian solutions of Hirota eq. ...
... Baxter’s TQ and QQ operatorial relations and nested Bethe ansatz equations from new Master identity. Wronskian solutions of Hirota eq. ...
A Mathematical Characterization of the Physical Structure of Observers
... will be observed by any observer will be close to the textbook probability for the typical manifestation of that observer, where “typical” is defined using the fundamental probability. The philosophical objection to the idea of mind as a “ghost in a machine”, is that if the mind has no physical powe ...
... will be observed by any observer will be close to the textbook probability for the typical manifestation of that observer, where “typical” is defined using the fundamental probability. The philosophical objection to the idea of mind as a “ghost in a machine”, is that if the mind has no physical powe ...
arXiv:1407.5822v1 [physics.bio
... The brain is the center of the nervous system in all vertebrates and most invertebrates. Only a few invertebrates, such as sponges, jellyfish, sea squirts, and starfish do not have one, though they have diffuse neural tissue. The brain of a vertebrate is the most complex organ of its body. In a typi ...
... The brain is the center of the nervous system in all vertebrates and most invertebrates. Only a few invertebrates, such as sponges, jellyfish, sea squirts, and starfish do not have one, though they have diffuse neural tissue. The brain of a vertebrate is the most complex organ of its body. In a typi ...
How brains make decisions
... The brain is the center of the nervous system in all vertebrates and most invertebrates. Only a few invertebrates, such as sponges, jellyfish, sea squirts, and starfish do not have one, though they have diffuse neural tissue. The brain of a vertebrate is the most complex organ of its body. In a typi ...
... The brain is the center of the nervous system in all vertebrates and most invertebrates. Only a few invertebrates, such as sponges, jellyfish, sea squirts, and starfish do not have one, though they have diffuse neural tissue. The brain of a vertebrate is the most complex organ of its body. In a typi ...
Chapter 1
... instance, Richard Feynman observed that quantum mechanics problems are very difficult to solve on a classical computer. This observation caused him to conclude – “we need a quantum computer to model quantum mechanical phenomena efficiently”. While working on the problem of testing quantum circuits, ...
... instance, Richard Feynman observed that quantum mechanics problems are very difficult to solve on a classical computer. This observation caused him to conclude – “we need a quantum computer to model quantum mechanical phenomena efficiently”. While working on the problem of testing quantum circuits, ...
