Bohr`s atomic model: the evolution of a theory
Bohr`s atomic model: the evolution of a theory

... introduced the quantum in his model. He used Planck’s quantum hypothese, imposing a condition on a saturnian system that further abided the classical mechanic rules. He created a quantized one electron atom model. Such a system only emitted energy while passing from one state to another. The energie ...
Bose-Einstein condensates
Bose-Einstein condensates

Integer and fractional quantum Hall effects
Integer and fractional quantum Hall effects

Anomaly of non-locality and entanglement in teaching quantum
Anomaly of non-locality and entanglement in teaching quantum

Quantum Distinction: Quantum Distinctiones!
Quantum Distinction: Quantum Distinctiones!

... we see we see from reference system of life [2]. We suggest notions functionality of life and distinction as base notions what should give the key access to deal with aspects of reference system of life. First, distinction we consider as main notion for what may be called referential physical scienc ...
Wave-mechanical Model for Chemistry (Reprint: To be published in
Wave-mechanical Model for Chemistry (Reprint: To be published in

... linear combination of atomic orbitals. Recent developments, inspired by taking cognisance of space-time topology and leading to a proper understanding of electron structure and spin, matter waves, and nonlinear effects, are briefly outlined. ...
Quantum information processing with superconducting qubits in a
Quantum information processing with superconducting qubits in a

... Quantum computing deals with the processing of information according to the laws of quantum mechanics. Within the last few years, it has attracted considerable attention because quantum computers are expected to be capable of performing certain tasks which no classical computers can do in practical ...
Thermal Physics PH2001
Thermal Physics PH2001

... • A negative temperature state must therefore be hotter than T= as its is a more energetic state of the system. ...
Why 3+1 = 11 for small values of 7
Why 3+1 = 11 for small values of 7

... With so many different options, it's no wonder so many different string theories have developed! However if we wish to find a universally applicable theory we must resolve these differences. It is no coincidence that many string theories share similar aspects, and often can be described in terms of ...
Metric fluctuations and decoherence
Metric fluctuations and decoherence

Charge and Mass of the Electron
Charge and Mass of the Electron

Quantum circuits for strongly correlated quantum systems
Quantum circuits for strongly correlated quantum systems

... novel ways of looking at strongly correlated quantum manybody systems. On the one hand, a great deal of theoretical work has been done identifying the basic structure of entanglement in low-energy states of many-body Hamiltonians. This has led, for example, to new interpretations of renormalization- ...
a presentation of Michel from 2009
a presentation of Michel from 2009

... a very large many-body system (on a microscopic level) in the presence of noise and using noisy devices. The idea, that quantum mechanics helps us to do it, looks strange, since all our experience in physics suggests that quantum effects are more fragile than classical ones. ...
Document
Document

6 GU 2007 Quantum Illusions and Time
6 GU 2007 Quantum Illusions and Time

Signal Analysis
Signal Analysis

... Networks Lab and the Stem Cells Research Institute • The Stem Cells Research Institute is directed by Prof. Angelo Vescovi, who has pioneered the field of ...
ELECTROGRAVITATION AS A UNIFIED FIELD
ELECTROGRAVITATION AS A UNIFIED FIELD

- EPJ Web of Conferences
- EPJ Web of Conferences

Vaxjo, 16 - Homepages of UvA/FNWI staff
Vaxjo, 16 - Homepages of UvA/FNWI staff

The Standard Model of Particle Physics
The Standard Model of Particle Physics

Phys. Rev. Lett. 99, 200404 - Harvard Condensed Matter Theory group
Phys. Rev. Lett. 99, 200404 - Harvard Condensed Matter Theory group

Spectral Analysis of Nonrelativistic Quantum Electrodynamics
Spectral Analysis of Nonrelativistic Quantum Electrodynamics

Chapter 9 Quantum Mechanics
Chapter 9 Quantum Mechanics

Failed theories of superconductivity
Failed theories of superconductivity

What you always wanted to know about Bohmian mechanics but
What you always wanted to know about Bohmian mechanics but

... Bohmians appreciate the GRW model which includes a stochastic term into the Schrödinger equation to describe the wavefunction collapse. Short but to the point: not the indeterminism of quantum mechanics but rather its vague account of the measurement process created discomfort with the ordinary fo ...

History of quantum field theory

In particle physics, the history of quantum field theory starts with its creation by Paul Dirac, when he attempted to quantize the electromagnetic field in the late 1920s. Major advances in the theory were made in the 1950s, and led to the introduction of quantum electrodynamics (QED). QED was so successful and ""natural"" that efforts were made to use the same basic concepts for the other forces of nature. These efforts were successful in the application of gauge theory to the strong nuclear force and weak nuclear force, producing the modern standard model of particle physics. Efforts to describe gravity using the same techniques have, to date, failed. The study of quantum field theory is alive and flourishing, as are applications of this method to many physical problems. It remains one of the most vital areas of theoretical physics today, providing a common language to many branches of physics.