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Hyperbolic metamaterials exhibit 2T physics by Staff Writers Washington DC (SPX) Sep 22, 2020
Metamaterials - nanoengineered structures designed for precise control and manipulation of electromagnetic waves - have enabled such innovations as invisibility cloaks and super-resolution microscopes. Using transformation optics, these novel devices operate by manipulating light propagation in "optical spacetime," which may be different from the actual physical spacetime. According to Igor Smolyaninov of the University of Maryland, "One of the more unusual applications of metamaterials was a theoretical proposal to construct a physical system that would exhibit two-time physics behavior on small scales." That proposal was recently realized experimentally by demonstration of two-time (2T) behavior in ferro-fluid-based hyperbolic metamaterials by Smolyaninov and a team of researchers from Towson University, led by Vera Smolyaninova. The observed 2T behavior has potential for use in ultrafast all-optical hypercomputing.
2T physics
Nonlinear hyperbolic metamaterials for precision light control Smolyaninov explains that the gravity analogues are a coincidental mathematical parallel: the mathematical equations that describe propagation of light in hyperbolic metamaterials also describe particle propagation in the physical, or Minkowski, spacetime in which one of the spatial coordinates behaves as a "time-like variable." Smolyaninov explains further that nonlinear optical effects "bend" this flat Minkowski spacetime, resulting in "effective gravitational force between extraordinary photons." According to Smolyaninov, experimental observation of the effective gravity in such a system should enable observation of the emergence of the gravitational arrow of time along a spatial direction. Together with conventional physical time, the two time-like variables guide evolution of the light field in a hyperbolic metamaterial. Experimental progress in this exciting field has been relatively slow until recently, due to difficulties associated with the 3D nanofabrication techniques necessary to produce large-volume 3D nonlinear hyperbolic metamaterials. The research team developed an alternative way to fabricate large-volume 3D nonlinear hyperbolic metamaterials using self-assembly of magnetic metallic nanoparticles in a ferrofluid subjected to external magnetic field. Smolyaninov explains, "Due to nonlinear optical Kerr effect in the strong optical field of a CO2 laser, light propagating inside the ferrofluid indeed exhibits pronounced gravity-like effects, leading to emergence of the gravitational arrow of time." As predicted by the earlier theoretical work, the experimentally observed dynamics of self-focused light filaments may indeed be described mathematically using the 2T physics model.
Ultrafast all-optical hypercomputing
Research Report: "Experimental observation of effective gravity and two-time physics in ferrofluid-based hyperbolic metamaterials"
Making waves in space Paris (ESA) Sep 16, 2020 The International Space Station is an exciting place for experiments. This one in particular was making waves in space. Called Fluidics, the experiment studies fluid dynamics in microgravity and recently performed another successful round of science on board the Space Station. Developed by French space agency CNES and co-funded by Airbus Defense and Space, the Fluidics or Fluid Dynamics in Space experiment is probing how fluids behave in weightlessness. Have you ever tried walking while carr ... read more
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