Can anyone suggest me some good quantum optics books? Suggestions from personal experiences appreciated?

Suggestions from personal experiences appreciated. Please also discuss the level of the book. For example if it is a graduate or an undergraduate level book.

Let me know also any prerequisits that might be helpful to have to follow the book Asked by milton_bose 61 months ago Similar questions: suggest quantum optics books Suggestions personal experiences appreciated Science > Physics.

Similar questions: suggest quantum optics books Suggestions personal experiences appreciated.

See below for suggestions Your preference will depend on your knowledge level, So I will suggest a few/ All these suggestions and prices are from Amazon. Introductory Quantum Optics (Paperback) by Christopher Gerry, Peter Knight Price: $46.80 Paperback: 332 pages Publisher: Cambridge University Press (November 22, 2004) Language: English ISBN: 052152735X Product Dimensions: 9.6 x 7.3 x 0.7 inches Book DescriptionThis elementary introduction to the subject of quantum optics, the study of the quantum mechanical nature of light and its interaction with matter, is almost entirely concerned with the quantized electromagnetic field. The text is designed for upper-level undergraduates taking courses in quantum optics who have already taken a course in quantum mechanics, and for first- and second- year graduate students.

___Modern Foundations Of Quantum Optics (Paperback) by Vlatko Vedral Price: $32.00 Karen Kirkby, Times gher Education SupplementIt is beautifully laid out and written in a manner that makes one just want to go on reading. Product DetailsPaperback: 222 pages Publisher: Imperial College Press (June 2005) Language: English ISBN: 1860945538 Product Dimensions: 9.2 x 6.3 x 0.6 inches ___Methods in Theoretical Quantum Optics (Oxford Series on Optical and Imaging Sciences, 15) (Paperback) by Stephen M. Barnett, Paul M.

Radmore List Price: $69.50 Paperback: 292 pages Publisher: Oxford University Press, USA; New Ed edition (January 23, 2003) Language: English ISBN: 0198563612 Product Dimensions: 9.2 x 6.1 x 0.6 inches Review`'The reader will find here a very clear presentation of material not readily found elsewhere. Postgraduate students of quantum optics will find this work to be of the greatest utility. It sets out to be genuinely helpful to students, with sufficient material provided at each step of a calculation to enable an inexperienced reader to fully understand the derivation...Experienced researchers will find that this text is a most convenient handbook of techniques, and will want it close to their elbow.'' S.

Swain, Contemporary Physics`'...an authoritative account of the key material, something which will not date easily and will be welcomed for many years by new students of this field. I strongly recommend it to novices and experts alike.'' P. Knight, Journal of Modern Optics`'...a model of clarity and completeness.

'' J.M.Raimond, Ecole Normale Superieure, Paris`'...a very good text...'' V. Vedral, Imperial College, London`'...exceptionally clearly written. '' K.

Burnett, University of Oxford`'The reader will find here a very clear presentation of material not readily found elsewhere. Postgraduate students of quantum optics will find this work to be of the greatest utility. It sets out to be genuinely helpful to students, with sufficient material provided at each step of a calculation to enable an inexperienced reader to fully understand the derivation...Experienced researchers will find that this text is a most convenient handbook of techniques, and will want it close to their elbow.

'' S. Swain, Contemporary Physics`'...an authoritative account of the key material, something which will not date easily and will be welcomed for many years by new students of this field. I strongly recommend it to novices and experts alike.

' ' P. Knight, Journal of Modern Optics Book DescriptionMethods in theoretical quantum optics is aimed at those readers who already have some knowledge of mathematical methods and have also been introduced to the basic ideas of quantum optics. This book is ideal for students who have already explored the basics of the quantum theory of light and are seeking to acquire the mathematical skills used in real problems.

This book is not primarily about the physics of quantum optics, but rather presents the mathematical methods widely used by workers in this field. There is no comparable book which covers either the range or the depth of mathematical techniques. Or, more specialized:Statistical Methods in Quantum Optics 1: Master Equations and Fokker-Planck Equations (Theoretical and Mathematical Physics) (Hardcover) (one of a series)Price: $72.95 Book DescriptionThe book provides an introduction to the methods of quantum statistical mechanics used in quantum optics and their application to the quantum theories of the single-mode laser and optical bistability.

The generalized representations of Drummond and Gardiner are discussed together with the more standard methods for deriving Fokker--Planck equations. Particular attention is given to the theory of optical bistability formulated in terms of the positive P-representation, and the theory of small bistable systems. This is a textbook at an advanced graduate level.

It is intended as a bridge between an introductory discussion of the master equation method and problems of current research. Book InfoDevelops the formalism of open systems in quantum optics, from foundations to applications. The operator master equation & quantum regression theorem are introduced as fundamental tools for describing the statistical properties of radiation from driven atoms & electromagnetic cavities.

DLC: Quantum optics - Statistical methods. Hardcover: 361 pages Publisher: Springer; 1 edition (April 25, 2003) Language: English ISBN: 3540548823 Product Dimensions: 9.4 x 6.3 x 1 inches Sources: www.amazon.com .

No experience here,but ratings follow the books Quantum optics From Wikipedia, the free encyclopedia Jump to: navigation, search Quantum optics is a field of research in physics, dealing with the application of quantum mechanics to phenomena involving light and its interactions with matter. Contents hide 1 story of quantum optics 2 Concepts of quantum optics 3 See also 4 External links edit story of quantum optics Light is made up of particles called photons and hence inherently is "grainy" (quantized); quantum optics is the study of the nature and effects of this. The first indication that light might be quantized came from Max Planck in 1899 when he correctly modelled blackbody radiation by assuming that the exchange of energy between light and matter only occurred in discrete amounts he called quanta.It was unknown whether the source of this discreteness was the matter or the light.

In 1905, Albert Einstein published the theory of the photoelectric effect. It appeared that the only possible explanation for the effect was the existence of particles of light called photons. Later, Bohr showed that the atoms were also quantized, in the sense that they could only emit discrete amounts of energy.

The understanding of the interaction between light and matter following from these developments not only formed the basis of quantum optics but also were crucial for the development of quantum mechanics as a whole. However, the subfields of quantum mechanics dealing with matter-light interaction were principally regarded as research into matter rather than into light and hence, one rather spoke of atom physics and quantum electronics. This changed with the invention of the maser in 1953 and the laser in 1960.

Laser science—i.e. , research into principles, design and application of these devices—became an important field, and the quantum mechanics underlying the laser's principles was studied now with more emphasis on the properties of light, and the name quantum optics became customary.As laser science needed good theoretical foundations, and also because research into these soon proved very fruitful, interest in quantum optics rose. Following the work of Dirac in quantum field theory, George Sudarshan, Roy J.

Glauber, and Leonard Mandel applied quantum theory to the electromagnetic field in the 1950s and 1960s to gain a more detailed understanding of photodetection and the statistics of light (see degree of coherence). This led to the introduction of the coherent state as a quantum description of laser light and the realization that some states of light could not be described with classical waves. In 1977, Kimble et al.

Demonstrated the first source of light which required a quantum description: a single atom that emitted one photon at a time. This was the first conclusive evidence that light was made up of photons. Another quantum state of light with certain advantages over any classical state, squeezed light, was soon proposed.

At the same time, development of short and ultrashort laser pulses—created by Q switching and modelocking techniques—opened the way to the study of unimaginably fast ("ultrafast") processes. Applications for solid state research (e.g. Raman spectroscopy) were found, and mechanical forces of light on matter were studied. The latter led to levitating and positioning clouds of atoms or even small biological samples in an optical trap or optical tweezers by laser beam.

This, along with Doppler cooling was the crucial technology needed to achieve the celebrated Bose-Einstein condensation. Other remarkable results are the demonstration of quantum entanglement, quantum teleportation, and (recently, in 1995) quantum logic gates. The latter are of much interest in quantum information theory, a subject which partly emerged from quantum optics, partly from theoretical computer science.

Today's fields of interest among quantum optics researchers include parametric down-conversion, parametric oscillation, even shorter (attosecond) light pulses, use of quantum optics for quantum information, manipulation of single atoms, Bose-Einstein condensates, their application, and how to manipulate them (a sub-field often called atom optics), and much more. Research into quantum optics that aims to bring photons into use for information transfer and computation is now often called photonics to emphasize the claim that photons and photonics will take the role that electrons and electronics now have. Edit Concepts of quantum optics Quantum optics operators Ladder operators Creation and annihilation operators Displacement operator Rotation operator Squeeze operator edit this template According to quantum mechanics, light may be considered not only as an electro-magnetic wave but also as a "stream" of particles called photons which travel with c, the vacuum speed of light.

These particles should not be considered to be classical billiard balls, but as quantum mechanical particles described by a wavefunction spread over a finite region. Each particle carries one quantum of energy equal to hf, where h is Planck's constant and f is the frequency of the light. The postulation of the quantization of light by Max Planck in 1899 and the discovery of the general validity of this idea in Albert Einstein's 1905 explanation of the photoelectric effect soon led physicists to realize the possibility of population inversion and the possibility of the laser.

This kind of use of statistical mechanics is the fundament of most concepts of quantum optics: Light is described in terms of field operators for creation and annihilation of photons—i.e. In the language of quantum electrodynamics. A frequently encountered state of the light field is the coherent state as introduced by Roy J.

Glauber in 1963. This state, which can be used to approximately describe the output of a single-frequency laser well above the laser threshold, exhibits Poissonian photon number statistics. Via certain nonlinear interactions, a coherent state can be transformed into a squeezed coherent state, which can exhibit super- or sub- Poissonean photon statistics.

Such light is called squeezed light. Other important quantum aspects are related to correlations of photon statistics between different beams. For example, parametric nonlinear processes can generate so-called twin beams, where ideally each photon of one beam is associated with a photon in the other beam.

Atoms are considered as quantum mechanical oscillators with a discrete energy spectrum with the transitions between the energy eigenstates being driven by the absorption or emission of light according to Einstein's theory with the oscillator strength depending on the quantum numbers of the states. For solid state matter one uses the energy band models of solid state physics. This is important as understanding how light is detected (typically by a solid-state device that absorbs it) is crucial for understanding experiments.

Edit See also Physics Portal Optics Optical physics Nonclassical light edit External links An introduction to quantum optics of the light field Encyclopedia of laser physics and technology, with content on quantum optics (particularly quantum noise in lasers), by Rüdiger Paschotta. Qwiki - A quantum physics wiki devoted to providing technical resources for practicing quantum physicists. An introduction to quantum optics, with a description of optical cavities, quantum dots, vacuum-field Rabi oscillations, the semi-classical Rabi model and the Jaynes-Cummings model.

Various Quantum Optics Reports Retrieved from "http://en.wikipedia.org/wiki/Quantum_optics" Categories: Quantum electronics | Quantum optics Views Article Discussion Edit this page story Personal tools .

I'm looking for personal experiences, please, not web pages or books. " "I need help learning physics. Could someone suggest how I should go learning about physics?

" "what the bleep do we know? & Quantum Physics, Is this stuff for real?

I'm looking for personal experiences, please, not web pages or books.

I need help learning physics. Could someone suggest how I should go learning about physics?

I cant really gove you an answer,but what I can give you is a way to a solution, that is you have to find the anglde that you relate to or peaks your interest. A good paper is one that people get drawn into because it reaches them ln some way.As for me WW11 to me, I think of the holocaust and the effect it had on the survivors, their families and those who stood by and did nothing until it was too late.