Light energy transfer: molecular vibrations instead of resonance
Photosynthesis involves the transfer of light energy between molecular structures. | © Christoph Olesinski
When light meets matter – say, sunlight striking the surface of the Earth – it is mostly absorbed and quickly converted into heat. In some cases, however, the light energy is also passed between molecular structures, when a pigment excited by the light transfers the energy to another pigment. An example of this process is photosynthesis. Numerous technological developments use this energy transfer, for which the physical chemist Theodor Förster developed a theory some 70 years ago. According to Förster resonance energy transfer (FRET), the light energy is transferred without radiation through resonance via small molecular dipole antennas – that is to say, electromagnetic interactions.
LMU chemist Prof. Heinz Langhals has now experimentally refuted this theory using the synthesis of test molecules. His results show that the energy is actually transferred via molecular vibrations – akin to how a stage floor can carry the vibrations of a grand piano to a cello standing on the platform. This process can reach all the way down into nano dimensions, and the chemist thinks it will be particularly interesting for the further development of optical technologies.
Heinz Langhals, Christian Dietl: Vibronic Intramolecular Resonant Energy Transfer along More than 5 nm: Synthesis of Dyads for a Re-Examination of the Distance Function of FRET. The Journal of Organic Chemistry 2022