A quantum leap forward?
November 23, 2009
Jeff Barrett, with an original Hugh Everett III paper in hand, is embarking on an adventure to better understand quantum mechanics theory involving concepts such as parallel universes. Photo by Daniel A. Anderson
The dusty boxes that line the walls of Jeff Barrett's UC Irvine office mark a high point in his academic career. Their contents: pages and pages of notes, most more than 50 years old, penned by late quantum theorist Hugh Everett III.
With $160,000 from the National Science Foundation, Barrett and colleagues are combing through, scanning and preserving documents they hope will shed light on how to understand measurement as a consistent physical process in quantum mechanics - one of physics' most debated puzzles that Everett believed he had solved as a graduate student.
"Everett liked to debunk commonly held beliefs," said Barrett, logic & philosophy of science professor and author of The Quantum Mechanics of Minds and Worlds, a book about Everett's work. "He often was the first to say, 'It can't work like that,' and then he'd try to provide evidence showing he was right."
Everett developed a new way of thinking about quantum mechanics, which explains the behavior of physical objects - the stability of matter, the nature of fundamental particles like electrons and photons, and the function of devices such as personal computers and laser pointers.
Standard quantum mechanics has two rules about how physical objects change over time: one for when an object is observed or measured and a second for all other times. Everett believed the second rule applied to all physical processes, including observation and measurement.
Eschewing the first rule would mean the physical universe is constantly evolving into many parallel, also-splitting universes, each containing copies of every observer and object. Everett's "many-worlds" theory attracted some attention when first published, in 1957, but didn't gain wide popularity until the mid-1970s.
Everett died in 1982, and his son, Mark - lead singer and songwriter of the indie-rock band Eels - inherited documents related to his scientific work.
In 2007, to honor the 50th anniversary of Everett's theory, Scientific American commissioned journalist Peter Byrne to write Everett's biography. Byrne contacted Mark Everett and found a treasure trove - everything from notes on the theorist's days as a college student to personal commentaries on other physicists' interpretations of his work.
Byrne asked UCI's Barrett to help make sense of the more technical documents.
"Most physicists today would agree with Everett's basic proposal, but exactly how it works has never been clear," Barrett said. "Significant disagreement remains about how Everett's interpretation of quantum mechanics should itself be interpreted."
Sifting through the physicist's notes, he says, is "a once-in-a-lifetime chance to read something I care very much about but never knew existed." Adds Barrett: "Everett's reflections on quantum mechanics almost certainly will help us better understand his theory and develop options for addressing the quantum measurement problem."
UCI plans to make the documents available online. They will become part of the American Institute of Physics' archive on Everett. Typescripts of the most important work, together with introductory essays and interpretative notes by Byrne and Barrett, are scheduled to be published by Princeton University Press in the 2010-11 academic year.
Source: University of California - Irvine
Popularity is a nice thing. It doesn't, however, replace falsifiability.
"Standard quantum mechanics has two rules about how physical objects change over time: one for when an object is observed or measured and a second for all other times. Everett believed the second rule applied to all physical processes, including observation and measurement. Eschewing [aka avoiding] the first rule would mean the physical universe is constantly evolving into many parallel [...] universes"
One can't "eschew" the first rule (state reduction), as observation is Everything with regard to empirical knowledge. What qualifies as an inductive scientific theory is that it provide a model for relating Observable Events. That is it. No more meaning or range can be expected of it.
I know there is more to it than that- but given the laws of physics we know, in no way do I find it possible that there are an infinite number of copies of me out there much less everything in an infinite number of universes stacked on top of each other.
I think we have a lot to learn about dark matter and dark energy and how they might be effecting or influencing particles like photons and electrons before we go on to say that there may be "infinite universes" out there.
Sure, its sparks some interest, but to scientist REALLY believe that is true?
It wasn't that long ago that people believed mice "spontaneously generated" in bags of wheat left in a barn.
You are free to speculate this way. As I'm free to tell you the tale of the lilac dragon in my garage which is invisible to everyone but me.
As there is no method to disprove my tale or your speculation just in case it should be nonsense, it is not science anymore. Falsifiability is the minimal kriterion of scientific thinking.
These two points explain to utter perfection the specific quanta of what time is in our dimensional viewpoint.
One must understand that Maxwell's original works contained equations to explain this but the math was cut down for engineering purposes. Then we lost the point of the original works.