Nobel Prize in Physics: Seeing the Light

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Nobel Prize in Physics: Seeing the Light

Posted by CmdrTaco on Tuesday October 4, 2005 @04:20AM from the for-people-smarter-than-me dept.

lidden writes "The Nobel Prize in Physics 2005 has been awarded Roy J. Glauber "for his contribution to the quantum theory of optical coherence". And John L. Hall and Theodor W. Hänsch "for their contributions to the development of laser-based precision spectroscopy, including the optical frequency comb technique"."

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Corresponding wikipedia articles by Anonymous Coward · 2005-10-04 04:27 · Score: 3, Informative

There are already three articles about those outstanding scientists in the english wikipedia at [[Roy J. Glauber]], [[John L. Hall]] and [[Theodor W. Hänsch]].

The German wikipedia and the Indonesian one has also three articles. Some of them are still to be considered stubs.

I would like you to invite to translate them into other languages (oops, I forgot Esperanto, there are already articles about them) and to contribute to those articles. We need freely licensed pictures of them and more details about their CV and their work.

Thanks you very much in advance.
Re:Physics behind the awards by Cyclotron_Boy · 2005-10-04 04:28 · Score: 4, Informative

Ooops- wrong link...
Try this one instead.
My bad. Need more coffee.
Re:He got a nobel prize for WHAT?!? by feranick · 2005-10-04 04:42 · Score: 5, Informative

Glauber didn't discover the laser, if this is what you mean. He provided the theory for quantum optics, which deals with quantum electrodynamical interactions of light and matter. Hall and Hänsch instead developed laser-based precision spectroscopy: in other words they used laser for high precision frequency measurements. Coherent optics is not just about laser, but what you can do with them.
Re:Bandwidth enhancement? by marcus · 2005-10-04 04:43 · Score: 5, Informative

A fairly large part of physics and cosmology is mind blowing. That is why it is so interesting, at least to me. Forget quantum oddness, just consider some of the numbers. Try to get a real grip on things like 10^19 eV. The universe is truly, literally, awe inspiring.

With radio we already have much more sophisticated modulation methods. Most "light band" modulation today is basically an automated, binary version of Morse Code, still effectively in the Stone Age. We are currently just barely able to "tune" a light transmitter and receiver. DWDM is nowhere near the spectral density of current radio technology. We cannot do anything with light approaching phase shift modulation, spread spectrum techniques, code division muxing, hell even plain old FM in the "light band" is currently out of reach. While lasers could be compared to classic PLLs, currently they are not even close to being as useful in frequency modulation and demodulation applications.

--
Good judgement comes from experience, and experience comes from bad judgement.
- W. Wriston, former Citibank CEO
From a Student by ThinkComp · 2005-10-04 05:23 · Score: 5, Informative

I was an undergraduate student in one of Professor Glauber's courses at Harvard two years ago, and though I'm certainly no specialist on light or physics, I really enjoyed his course (The Nature of Light and Matter). It's one of the many Core Curriculum courses at Harvard, but it's taught by one of the few professors there worthy of calling himself a teacher. He has a great sense of humor. I'm glad someone who deserves some credit was able to earn it.