“The improved understanding of the equations of hydrodynamics is general in nature; it applies to all quantum field theories, including those like quantum chromodynamics that are of interest to real world experiments.”
Interview in The Hindu (2013)
Context: The improved understanding of the equations of hydrodynamics is general in nature; it applies to all quantum field theories, including those like quantum chromodynamics that are of interest to real world experiments. I think this is a good (though minor) example of the impact of string theory on experiments. At our current stage of understanding of string theory, we can effectively do calculations only in particularly simple — particularly symmetric — theories. But we are able to analyse these theories very completely; do the calculations completely correctly. We can then use these calculations to test various general predictions about the behaviour of all quantum field theories. These expectations sometimes turn out to be incorrect. With the string calculations to guide you can then correct these predictions. The corrected general expectations then apply to all quantum field theories, not just those very symmetric ones that string theory is able to analyse in detail.
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Shiraz Minwalla3
Indian physicist 1972Related quotes
Shiraz Minwalla (1972) Indian physicist
Interview in The Hindu (2013)
Context: The improved understanding of the equations of hydrodynamics is general in nature; it applies to all quantum field theories, including those like quantum chromodynamics that are of interest to real world experiments. I think this is a good (though minor) example of the impact of string theory on experiments. At our current stage of understanding of string theory, we can effectively do calculations only in particularly simple — particularly symmetric — theories. But we are able to analyse these theories very completely; do the calculations completely correctly. We can then use these calculations to test various general predictions about the behaviour of all quantum field theories. These expectations sometimes turn out to be incorrect. With the string calculations to guide you can then correct these predictions. The corrected general expectations then apply to all quantum field theories, not just those very symmetric ones that string theory is able to analyse in detail.
Lee Smolin (1955) American cosmologist
The Trouble With Physics: The Rise of String Theory, The Fall of a Science, and What Comes Next (2007)
Willis Lamb (1913–2008) American Physicist
W. E. Lamb, Super classical quantum mechanics: the best interpretation of non relativistic quantum mechanics, Am. J. Phys. 69, 413-422 (2001).
Steven Weinberg (1933) American theoretical physicist
"Testing Quantum Mechanics" http://www.sciencedirect.com/science/article/pii/0003491689902765, Annals of Physics (1989)
Diederik Aerts (1953) Belgian theoretical physicist
Aerts, D. (1998). " The entity and modern physics: the creation-discovery view of reality. http://www.vub.ac.be/CLEA/aerts/publications/1998EntModPhys.pdf" In E. Castellani (Ed.), Interpreting Bodies: Classical and Quantum Objects in Modern Physics (pp. 223-257). Princeton: Princeton University Press.
Yoichiro Nambu (1921–2015) American physicist
[Quasi-particles and gauge invariance in the theory of superconductivity, Physical Review, 117, 3, February 1960, 648–663, 10.1103/PhysRev.117.648]
Sean Carroll (1966) American theoretical cosmologist
No causes, whether material, formal, efficient, or final. But there are levels on top of that, where the vocabulary changes.
Chap. 3 : The World Moves by Itself
The Big Picture (2016)
"Quantum Locality", Found Phys (2011) 41: 705–733
“When you look at a vacuum in a quantum theory of fields, it isn't exactly nothing.”
Peter Higgs (1929) British physicist
in video Meet Peter Higgs http://cdsweb.cern.ch/record/1019670 by CERN (July 2004).