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In this archival footage from BBC TV, celebrated physicist Richard Feynman explains what fire, magnets, rubber bands (and more) are like at the scale of the jiggling atoms they're made of. This accessible, enchanting conversation in physics reveals a teeming nano-world that's just plain fun to imagine.
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Richard Phillips Feynman (d. 11 Mayıs 1918 - ö. 15 Şubat 1988), kuantum mekaniğinin ayrılmaz formülasyonu, kuantum elektrodinamiği teorisi, aşırı soğutulmuş sıvı helyumun süper-akışkan fiziği ve partonu önerdiği parçacık fiziğindeki çalışmaları ile 1965'te, Julian Schwinger ve Sin-Itiro Tomonaga ile birlikte Nobel Fizik Ödülü'ne layık görülmüş Amerikalı ...
Richard Phillips Feynman (* 11. máj 1918, Queens, New York, USA – † 15. február 1988, Los Angeles, Kalifornia) bol americký fyzik, ktorý značne rozšíril teóriu kvantovej elektrodynamiky, fyziky supratekutosti tekutého hélia a časticovej fyziky. Za svoju prácu o kvantovej elektrodynamike získal Feynman v roku 1965 Nobelovu cenu ...
1–1 Atomic mechanics. “Quantum mechanics” is the description of the behavior of matter and light in all its details and, in particular, of the happenings on an atomic scale. Things on a very small scale behave like nothing that you have any direct experience about. They do not behave like waves, they do not behave like particles, they do ...
Richard Feynman: Physics is fun to imagine In this archival footage from BBC TV, celebrated physicist Richard Feynman explains what fire, magnets, rubber bands (and more) are like at the scale of the jiggling atoms they’re made of. This accessible, enchanting conversation in physics reveals a teeming nano-world that’s just plain fun to imagine.
Helium merely decreases the atomic motions as much as it can, but even at absolute zero there is still enough motion to keep it from freezing. Helium, even at absolute zero, does not freeze, unless the pressure is made so great as to make the atoms squash together. If we increase the pressure, we can make it solidify.
