For example, investigations of dynamic molecular structure and energy transfer at the quantum level have credibility if they explain macroscopic biological observables that otherwise are inexplicable.
In particular the step-wise, quantum release of protons upon photon absorption linked to water `splitting' in photosynthesis requires a quantum theoretical explanation involving complex photosystem II.
Fundamental biological processes that involve the conversion of energy into forms that are usable for chemical transformations are quantum mechanical in nature.
Quantum biology uses mathematical computation to model biological interactions in light of QM effects.
An unresolved and still controversial issue in this field is that of non-trivial (i.e. not limited to properties of molecules) role of quantum effects in biological systems. However recent studies of transcription are consistent with quantum information processing of coherent duplex DNA states by the transcriptase.
Some of the biological phenomena that have been studied in terms of quantum processes are the absorbance of frequency-specific radiation (i.e., photosynthesis and vision)...
For example, investigations of dynamic molecular structure and energy transfer at the quantum level have credibility if they explain macroscopic biological observables that otherwise are inexplicable.
An unresolved and still controversial issue in this field is that of non-trivial (i.e. not limited to properties of molecules) role of quantum effects in biological systems. However recent studies of transcription are consistent with quantum information processing of coherent duplex DNA states by the transcriptase.
Some of the biological phenomena that have been studied in terms of quantum processes are the absorbance of frequency-specific radiation (i.e., photosynthesis and vision); the conversion of chemical energy into motion; magnetoreception in animals and brownian motors in many cellular processes.