Difference between revisions of "Quantum light: states and dynamics"
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* [[Chapter2-quantum-light-part-4| Entangled photons]] | * [[Chapter2-quantum-light-part-4| Entangled photons]] | ||
* [[Chapter2-quantum-light-part-5-interferometry| Interferometry and metrology]] | * [[Chapter2-quantum-light-part-5-interferometry| Interferometry and metrology]] | ||
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| + | == Handouts == | ||
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| + | * [http://cua.mit.edu/8.422/HANDOUTS/chapter2-quantum-light-part-1.pdf Photons and statistics] | ||
| + | * [http://cua.mit.edu/8.422/HANDOUTS/chapter2-quantum-light-part-2.pdf Non-classical light] | ||
| + | * [http://cua.mit.edu/8.422/HANDOUTS/chapter2-quantum-light-part-3.pdf Single photons] | ||
| + | * [http://cua.mit.edu/8.422/HANDOUTS/chapter2-quantum-light-part-4.pdf Entangled photons] | ||
| + | * [http://cua.mit.edu/8.422/HANDOUTS/chapter2-quantum-light-part-5-interferometry.pdf Interferometry and Metrology] | ||
Revision as of 16:55, 3 February 2009
This chapter is a study of the quantum properties of light, specifically, single-mode monochromatic light. We begin by considering the states in which quanta of the electromatic field, photons, may exist. We describe how these states are mathematically represented, and how they transform under simple physical operations, such as propagation through free space, and through optical beamsplitters. We also consider how two modes of light may relate to each other, in particular through entanglement, a purely quantum-mechanical property which can be a useful resource. Throughout this study of the quantum nature light, we develop an intuition and a language for quantum states and behaviors which may be applied not just to light, but also, to analogous states of matter.
- Photons and statistics
- Non-classical light; squeezed states
- Single photons
- Entangled photons
- Interferometry and metrology
