Los Alamos scientists unravel the nature of knot

Contact: Todd Hanson, tahanson@lanl.gov, (505) 665-2085 ( 01-022.shtml )

Recent News Los Alamos scientist named Asian American Engineer of the Year Los Alamos scientist featured in NASA science update Los Alamos muon detector could thwart nuclear smugglers Wojciech H. Zurek named Phi Beta Kappa visiting scholar Four Los Alamos physicists honored by American Physical Society Los Alamos National Laboratory organizations earn seven out of 13 NNSA Pollution Prevention awards Carter Hydrick returns to the Bradbury Science Museum Feb. 15 Laboratory supports summer science program New NASA IBEX mission to carry Los Alamos instrument Beason takes top threat reduction post at Los Alamos

LOS ALAMOS, N.M., Feb. 16, 2001 -- Scientists at the Department of Energy's Los Alamos National Laboratory are watching simple knots untie themselves in order to gain a better understanding of how granular materials flow and how filamentary objects like DNA molecules tangle. The research is published in the February 19 issue of the American Physical Society's Physical Review Letters.

To understand how simple knots untie themselves, Los Alamos scientists studied chains made from tiny, nickel-plated steel balls interconnected by thin rods. These chains, consisting of up to 300 beads, were tied in tight trefoil knots with three crossover points and then laid on a vibrating steel plate. The constant and uniform shaking of the plate allowed the chain to stretch, wiggle and bend while scientists watched the many configurations the chain went through on its way toward untying itself.

"Understanding the physical mechanisms governing the relaxation of knots is actually quite crucial to characterizing the flow and deformation properties of materials like polymers, gels and rubber," said Los Alamos researcher Eli Ben-Naim. "Typically this kind of research is modeled mathematically or by using computer simulations, but this shaking experiment allowed us to actually compare a real-world physical system to theory."

Ben-Naim and his collaborators discovered that although the chain's motion was complicated, the knot motion resembled what mathematicians call a "random walk," a sequence of motions where the direction of each successive movement is random. They also found that the statistical properties of unknotting time depended almost completely on the locations of the three crossing points of the knots in the chain.

They also discovered that the unknotting time in seconds was proportional to the square of the chain's length in beads. For example, a chain of 150 beads in length took, on average, approximately 60 seconds to untie. In the end, each chain untied itself completely.

Despite the experiment's rather simple construction, the model shows a simple correlation to real physical systems with the beads in the chains representing molecules or macromolecules, and the vibrating steel plate representing the application of energy to the system. According to Ben-Naim this type of shaking experiment represents a new way to study the structures of polymers and certain granular materials as well as the dynamics of entanglements in DNA. These entanglements significantly slow down the flow of macromolecules such as polymers and DNA, making them more sluggish, and knots affect the strength of macromolecules.

Ben-Naim's collaborators on this project were Zahir Daya and Robert Ecke, also at Los Alamos. The Laboratory Directed Research and Development program funded the work.

More news releases about Mathematics

More news releases about Physics

More news releases from the Theoretical (T) Division