Quantum Biology Design Concepts May Pave The Way For New Solar Technology

Researchers have developed a synthetic substance that resembles the intricate quantum dynamics seen in photosynthesis. The substance might open up whole new pathways for innovative solar light gathering systems.

In big, hot, disordered systems, quantum effects are typically insignificant. The near-perfect quantum efficiency of photosynthetic light harvesting, even at physiological temperatures, may be due to quantum superpositions, according to recent ultrafast spectroscopy tests conducted by researchers.

Superpositions are supported by photosynthetic antennae, the proteins that organise chlorophyll and other light-absorbing molecules in plants and microbes. According to researchers : animals that utilise photosynthesis have evolved a defence mechanism to prevent these superpositions. As a result, the components of the cell that transform solar energy into chemical energy are more effectively transferred energy from absorbed sunlight. The latest findings show that this quantum mechanical property can be included into synthetic molecules.

These artificial substances might serve as the foundation for solar energy technology that imitates the energy-transfer mechanisms used by plants during photosynthesis.

The fluorescein molecule, which was originally used to colour the Chicago River green for St. Patrick's Day, was altered by the researchers, who then employed a rigid bridge structure to bind various pairings of these dyes together. The resultant molecules successfully mimicked the crucial characteristics of chlorophyll molecules in photosynthetic systems, which allow coherences to last for tens of femtoseconds at ambient temperature.

A femtosecond is a millionth of a billionth of a second. However, because the excitations in these systems flow through them on this extremely short timescale, these quantum superpositions can be crucial in the transfer of energy.

The researchers used highly designed laboratories and cutting-edge femtosecond laser systems to construct a movie of energy flow in the molecules in order to look for signs of long-lived superpositions. The sample was exposed to three carefully timed laser pulses, which caused it to release an optical signal that was collected and directed into a camera.

The researchers produced a two-dimensional video of the system's energy flow by scanning the gaps in time between the incoming laser pulses. Each two-dimensional spectrum represents a single frame in the movie and contains details about the locations of energy inside the system and the routes it took to get there.

These movies display oscillating signals in very narrow portions of the signal, or quantum beats, as well as relaxation from high-energy states toward lower-energy states over time. According to researchers, "Quantum beats are the signature of quantum coherence, coming from the interference between the various energy levels in the superposition, akin to the beating heard when two instruments that are just slightly out of tune with one another try to play the same note."

Quantum coherences in photosynthetic antennas prevent excitations from becoming trapped as they travel to the reaction centre, where the process of converting electrical energy into chemical energy starts, according to computer models. According to one explanation, it is unavoidable that the excitation choose the right path as it travels through the antenna since it is constantly superposing all other potential courses.

It is yet to be known whether such a complicated occurrence could be replicated outside of nature until similar coherences were seen in synthetic systems.