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Physicist finds loose thread of string theory puzzle

Physicist finds loose thread of string theory puzzle

New research from a 兔子先生传媒文化作品 physicist might break open the mathematical puzzle that has stalled string theory research for decades


A University of Colorado Boulder physicist is one step closer to solving a string theory puzzle 20 years in the making.

Paul Romatschke, an associate professor of physics at 兔子先生传媒文化作品, has devised an alternative set of tools to those that created string theory鈥檚 three-quarters dilemma, a mathematical puzzle that has plagued scientists for years and has kept them from fully understanding and proving this possible 鈥渢heory of everything.鈥

While not necessarily applicable to the everyday world, the results, which were , open the door for higher-level equations that could have implications on the way we approach and understand important aspects of physics like string theory or quantum field theories, which are a set of theories in physics that describe the dynamics of fields, or objects that permeate everything.

  

Headshot of Paul Romatschke

Paul Romatschke, seen here, may have found an answer to a 20-year-old string theory puzzle

鈥淲hile it would be nice to really get at the meaning of three-quarters, this is at least a very suggestive picture, so maybe that鈥檚, if not the solution for three-quarters, at least a step towards sort of resolving it,鈥 said Romatschke.

Since the 1960s, scientists have been puzzling over string theory, a theoretical framework of reality that involves tiny, wriggling one-dimensional objects鈥攃alled strings鈥攖hat make up the fabric of everything. First studied as a broad way to address a number of questions in fundamental physics, it has since been applied to topics ranging from black hole physics to nuclear physics to the very origins of the universe.

But, arguably, one of its biggest breakthroughs is the discovery that black holes and matter are roughly two sides of the same coin.

This so-called 鈥渄uality鈥 allows physicists to map properties of matter (such as pressure) to properties of the black holes found in Einstein鈥檚 general relativity, which would open up string theory for even greater mathematical exploration. There is, however, a big caveat鈥攚hile physicists think that it works, no one鈥檚 been able to prove it.

Since the discovery of this duality was made 20 years ago, string theorists have been trying to clear this roadblock with progressively more complicated equations. Every time they compare this duality, though, they all get the exact same result: The free energy (a system鈥檚 ability to do work) from a strong interaction (or coupling) of the two is roughly three-quarters the strength of a weak coupling.

Romatschke, though, thinks he may finally have an answer to this puzzle鈥攈e just had to change dimensions.

Romatschke worked in a world that only has two dimensions鈥攁 鈥渇latland鈥 if you will. Using some of the equations from existing research on the subject, as well as modern quantum field theory techniques, he was able to prove a relationship exists by forcing matter (in this case, pressure) to interact from zero interaction to infinite interaction.

This research found that the pressure of infinite coupling is exactly four-fifths of that at zero coupling, meaning that not only is there a stronger connection in this lesser dimension than what was previously found, it also may provide a standard approach to solving these types of puzzles.

Romatschke acknowledges that this may be caused by the differences in dimensions, but is still optimistic about its usefulness to quantum field theory and cracking open the long-held string theory puzzle.

鈥淭his is basic research. Most of the things we try don鈥檛 work,鈥 said Romatschke.  鈥淣evertheless, if there鈥檚 something that has at least has the potential to work, then I think we should pursue it.鈥