Recent work using room‑temperature, single‑molecule spectroscopy shows that even higher plants retain coherent dynamics under natural light conditions. Engineers are now mimicking this “coherent hopping” in synthetic light‑harvesting polymers, hoping to surpass the performance of conventional photovoltaic cells.
Plants, algae, and some bacteria convert sunlight into chemical energy with a staggering ~95 % quantum efficiency in the initial light‑harvesting stage. Classical models, based on incoherent hopping of excitons (electron‑hole pairs) between pigment molecules, could not fully account for this speed and robustness. JUQ-373
Cryptochrome, a flavoprotein found in the retinas of many animals, undergoes photo‑induced electron transfer, creating a radical pair. The singlet‑triplet interconversion of this pair is magnetic‑field dependent, ultimately affecting the downstream neural signal that the bird interprets as directional information. Plants, algae, and some bacteria convert sunlight into
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JUQ‑373 – An Overview of the Next‑Generation Quantum‑Enhanced Processor
