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Photonic time crystals, materials with consistent spatial composition but periodically varying properties over time, offer innovative pathways for optical information processing. These materials can modulate and amplify light's spectral composition, enabling advanced functionality. "This gives us new degrees of freedom but also poses a lot of challenges," said Professor Carsten Rockstuhl from Ka 
by Robert Schreiber
Berlin, Germany (SPX) Dec 10, 2024
Photonic time crystals, materials with consistent spatial composition but periodically varying properties over time, offer innovative pathways for optical information processing. These materials can modulate and amplify light's spectral composition, enabling advanced functionality. "This gives us new degrees of freedom but also poses a lot of challenges," said Professor Carsten Rockstuhl from Karlsruhe Institute of Technology (KIT). "This study paves the way for using these materials in information processing systems capable of using and amplifying light of any frequency."
Toward Four-dimensional Photonic Crystals
A critical feature of photonic time crystals is the momentum space bandgap, which dictates the amplification of light propagation based on direction. A wider bandgap results in greater amplification. "Previously we've had to intensify the periodic variation of material properties such as the refractive index to achieve a wide bandgap. Only then can light be amplified at all," said Puneet Garg, one of the study's lead authors. However, material limitations made this approach challenging.The researchers addressed this by merging photonic time crystals with spatial structures to create "photonic space-time crystals." These integrated systems used silicon spheres to trap light longer, allowing better interaction with periodic material property changes. "We're talking about resonances that intensify the interactions between light and matter," explained Xuchen Wang, the co-lead author. The innovation expanded the bandgap across nearly the entire momentum space, enabling light amplification in all directions. "This could be the crucial missing step on the way toward practical use of such novel optical materials," Wang added.
Professor Rockstuhl expressed optimism about the findings, stating, "We're very excited about this breakthrough in photonic materials, and we look forward to seeing the long-term impact of our research. Now the enormous potential of modern optical materials research can be realized." The research's implications extend beyond optics and photonics, with potential applications in various physical systems.
The project was supported by the German Research Foundation's Collaborative Research Center "Wave phenomena: analysis and numerics" and is part of the Helmholtz Association's Information research field.
Research Report:Expanding momentum bandgaps in photonic time crystals through resonances
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