adjective relating to a molecule that is not superimposable on its mirror image, thus having a non-superimposable mirror image relationship
In chemistry, chiral refers to molecules that are non-superimposable mirror images of each other. Chirality is important in the study of organic chemistry and drug development.
Chirality is also relevant in biology, particularly in the study of molecular biology and genetics where the chirality of molecules can affect their biological function.
Chirality is crucial in the pharmaceutical industry as enantiomers of drugs can have different pharmacological effects on the body. Drug development often involves separating and studying chiral compounds.
In materials science, chiral materials exhibit interesting optical, electrical, and mechanical properties that make them useful in various applications such as sensors and photonics.
Chiral nanoparticles have unique properties that can be exploited in nanotechnology for various applications such as drug delivery and catalysis.
In chemistry, the term 'chiral' is used to describe molecules that are non-superimposable mirror images of each other.
Pharmacists need to be aware of chiral molecules when dispensing medications, as the different forms can have different effects on the body.
Biologists may study chiral molecules in living organisms to understand their functions and interactions.
Physicists may encounter chiral materials in the study of condensed matter physics, where chirality can affect the properties of materials.
Engineers working in fields such as materials science or nanotechnology may need to consider the chirality of molecules when designing new materials or devices.