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On the quantum no-signalling assisted zero-error
On the quantum no-signalling assisted zero-error

Many Body Quantum Mechanics
Many Body Quantum Mechanics

Unitarity as Preservation of Entropy and Entanglement in Quantum
Unitarity as Preservation of Entropy and Entanglement in Quantum

Born approximation - BYU Physics and Astronomy
Born approximation - BYU Physics and Astronomy

Glassy Chimeras Could Be Blind to Quantum Speedup:
Glassy Chimeras Could Be Blind to Quantum Speedup:

... Recently, a programmable quantum annealing machine has been built that minimizes the cost function of hard optimization problems by, in principle, adiabatically quenching quantum fluctuations. Tests performed by different research teams have shown that, indeed, the machine seems to exploit quantum e ...
5.3 Atomic Emission Spectra and the Quantum Mechanical Model
5.3 Atomic Emission Spectra and the Quantum Mechanical Model

... Atomic Emission Spectra A prism separates light into the colors it contains. White light produces a rainbow of colors. ...
2015_0042_Quantum Robot = CSP = Quantum Emotional
2015_0042_Quantum Robot = CSP = Quantum Emotional

Modeling and Control of Quantum Systems: An Introduction
Modeling and Control of Quantum Systems: An Introduction

... the reader with a set of theoretical tools that are as “portable” ...
Daniel Dennett`s Compatibilism
Daniel Dennett`s Compatibilism

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From Quantum Gates to Quantum Learning

... – superposition allows quantum computer to make calculations on all 128 possible numbers (27) in ONE iteration i.e. finishes in 1 second. – Tremendous possibilities… imagine doing computations on even larger sample spaces all at the same time!!! ...
Matchgate and space-bounded quantum computations are equivalent
Matchgate and space-bounded quantum computations are equivalent

Quantum Mechanical Modelling and Optical Spectroscopy of
Quantum Mechanical Modelling and Optical Spectroscopy of

... it comes without any emission of greenhouse gases; ZnO structures poses as candidates for highly efficient and affordable solar cells. Furthermore will transitioning to a more efficient light source, such as readily available light emitting diodes, noticeably lower the global energy demand. In fact ...
Minimally Entangled Typical Quantum States at Finite Temperature
Minimally Entangled Typical Quantum States at Finite Temperature

... starting from a random configuration. This suggests that the thermal-step autocorrelation time (similar to a Monte Carlo autocorrelation time) is very short, the key to efficient sampling. In practical calculations (inset), one does one long run with many thermal steps, discarding the first results ...
Construction X for quantum error-correcting codes
Construction X for quantum error-correcting codes

Quantum technology: the second quantum revolution
Quantum technology: the second quantum revolution

Quantum Mechanics as Quantum Information
Quantum Mechanics as Quantum Information

... “But what nonsense is this,” you must be asking. “Where else could they start?” The main issue is this, and no one has said it more clearly than Carlo Rovelli [11]. Where present-day quantumfoundation studies have stagnated in the stream of history is not so unlike where the physics of length contra ...
Quantum Mechanics as Quantum Information (and only a little more)
Quantum Mechanics as Quantum Information (and only a little more)

Slides - Agenda
Slides - Agenda

Geometry and Dynamics of a Quantum Search
Geometry and Dynamics of a Quantum Search

III. Contact-ing Schrödinger
III. Contact-ing Schrödinger

Hypergroups and Quantum Bessel Processes of Non
Hypergroups and Quantum Bessel Processes of Non

Sc h o o l o f Ph ysic s ...
Sc h o o l o f Ph ysic s ...

Doubly infinite separation of quantum information and communication Please share
Doubly infinite separation of quantum information and communication Please share

... compared with its classical counterpart. For constant nonzero probability of error, the gap between classical information and communication complexities is at most exponential for any communication task [9,10]. For zero and asymptotically vanishing probability of error, the largest known gap is cons ...
Quantum heat engine with multilevel quantum systems
Quantum heat engine with multilevel quantum systems

"Rovelli's World"
"Rovelli's World"

... of itself.” When asked “information about what?” he replies “The answer is ‘the potential consequences of our experimental interventions into nature’.” (ibid, p. 7) But Fuchs also has a precise proposal about how to describe the information-updating process in response to measurement. (See further [ ...
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Max Born



Max Born (German: [bɔɐ̯n]; 11 December 1882 – 5 January 1970) was a German physicist and mathematician who was instrumental in the development of quantum mechanics. He also made contributions to solid-state physics and optics and supervised the work of a number of notable physicists in the 1920s and 30s. Born won the 1954 Nobel Prize in Physics for his ""fundamental research in Quantum Mechanics, especially in the statistical interpretation of the wave function"".Born was born in 1882 in Breslau, then in Germany, now in Poland and known as Wrocław. He entered the University of Göttingen in 1904, where he found the three renowned mathematicians, Felix Klein, David Hilbert and Hermann Minkowski. He wrote his Ph.D. thesis on the subject of ""Stability of Elastica in a Plane and Space"", winning the University's Philosophy Faculty Prize. In 1905, he began researching special relativity with Minkowski, and subsequently wrote his habilitation thesis on the Thomson model of the atom. A chance meeting with Fritz Haber in Berlin in 1918 led to discussion of the manner in which an ionic compound is formed when a metal reacts with a halogen, which is today known as the Born–Haber cycle.In the First World War after originally being placed as a radio operator, due to his specialist knowledge he was moved to research duties regarding sound ranging. In 1921, Born returned to Göttingen, arranging another chair for his long-time friend and colleague James Franck. Under Born, Göttingen became one of the world's foremost centres for physics. In 1925, Born and Werner Heisenberg formulated the matrix mechanics representation of quantum mechanics. The following year, he formulated the now-standard interpretation of the probability density function for ψ*ψ in the Schrödinger equation, for which he was awarded the Nobel Prize in 1954. His influence extended far beyond his own research. Max Delbrück, Siegfried Flügge, Friedrich Hund, Pascual Jordan, Maria Goeppert-Mayer, Lothar Wolfgang Nordheim, Robert Oppenheimer, and Victor Weisskopf all received their Ph.D. degrees under Born at Göttingen, and his assistants included Enrico Fermi, Werner Heisenberg, Gerhard Herzberg, Friedrich Hund, Pascual Jordan, Wolfgang Pauli, Léon Rosenfeld, Edward Teller, and Eugene Wigner.In January 1933, the Nazi Party came to power in Germany, and Born, who was Jewish, was suspended. He emigrated to Britain, where he took a job at St John's College, Cambridge, and wrote a popular science book, The Restless Universe, as well as Atomic Physics, which soon became a standard text book. In October 1936, he became the Tait Professor of Natural Philosophy at the University of Edinburgh, where, working with German-born assistants E. Walter Kellermann and Klaus Fuchs, he continued his research into physics. Max Born became a naturalised British subject on 31 August 1939, one day before World War II broke out in Europe. He remained at Edinburgh until 1952. He retired to Bad Pyrmont, in West Germany. He died in hospital in Göttingen on 5 January 1970.
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