Quantum biology: Difference between revisions
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File:Macrophage ferritin.jpg|Macrophage ferritin | |||
File:Ferritin tunneling (cropped).tif|Ferritin tunneling | |||
File:Iron outside of neuroemlanin.png|Iron outside of neuroemlanin | |||
File:Glial cell.png|Glial cell | |||
File:Generic Photosystem Complex.png|Generic Photosystem Complex | |||
File:Antennae Complex.png|Antennae Complex | |||
File:FMO Complex Simple Diagram.jpg|FMO Complex Simple Diagram | |||
File:Quantum Magnetoreception in Birds.svg|Quantum Magnetoreception in Birds | |||
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Latest revision as of 05:57, 3 March 2025
Quantum biology is an emerging field of science that combines principles of quantum mechanics and biology. It aims to understand the role of quantum phenomena in biological processes.
History[edit]
The concept of quantum biology was first introduced in the 1930s by Niels Bohr, Max Delbrück, and other physicists who were exploring the principles of quantum mechanics. However, it was not until the late 20th century that the field began to gain traction, with the discovery of quantum effects in photosynthesis and bird navigation.
Quantum phenomena in biology[edit]
Quantum biology investigates several phenomena where quantum effects play a crucial role:
- Photosynthesis: Quantum coherence has been observed in the process of photosynthesis. This allows plants to use sunlight more efficiently for energy production.
- Bird navigation: Some birds have been found to use quantum entanglement in their magnetic compass to navigate during migration.
- Enzyme kinetics: Quantum tunneling has been proposed to play a role in enzyme reactions, speeding up the process significantly.
- DNA and Genetics: Quantum mechanics may play a role in DNA mutation and genetic variation.
Challenges and future directions[edit]
Despite the promising findings, quantum biology is still a young field with many challenges. The main challenge is the difficulty of observing quantum effects in biological systems due to the warm and wet conditions in which life exists. However, with the advancement of technology and the development of new experimental techniques, it is expected that the field will continue to grow and contribute to our understanding of life at the quantum level.
See also[edit]
References[edit]
<references />
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Quantum biology gallery[edit]
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Macrophage ferritin -
Ferritin tunneling -
Iron outside of neuroemlanin -
Glial cell -
Generic Photosystem Complex -
Antennae Complex -
FMO Complex Simple Diagram -
Quantum Magnetoreception in Birds
