molecular symmetry

A central construct in inorganic chemistry is the theory of molecular symmetry.

Molecular symmetry can be studied several different ways.

Spectroscopic notation is based on facts taken from molecular symmetry.

While various frameworks for the study of molecular symmetry exist, group theory is the predominant one.

Molecular symmetry is a basic idea in chemistry.

Reactions normally result in the inversion of molecular symmetry.

X-ray analysis shows D molecular symmetry with the aromatic planes separated by 262 pm.

He discovered the molecular symmetry group G.

Scientists can find molecular symmetry by using X-ray crystallography and other forms of spectroscopy.

Molecular symmetry can predict or explain chemical properties.

This is in contrast to the commonly encountered D molecular symmetry exhibited by most trioxides.

Durene has a unusually high melting point, reflecting its high molecular symmetry.

In chemistry, molecular symmetry is the symmetry of molecules.

Selenium monochloride exhibits C molecular symmetry, similar to hydrogen peroxide.

The triphenylmethyl cation effectively has D3h molecular symmetry.

The molecular symmetry is D.

This planar compound has idealized C molecular symmetry.

PH is a trigonal pyramidal molecule with C molecular symmetry.

Biological and biochemical systems, like amino acids and enzymes often belong to low molecular symmetry point groups.

The molecular symmetry of the reactants help predict how the product of the reaction is made up and the energy needed for the reaction.

BH is a trigonal planar molecule (D molecular symmetry).

NI is pyramidal (C molecular symmetry), as are the other nitrogen trihalides and ammonia.

The spectra of solid samples often contain more bands than expected on the basis of the molecular symmetry of single, isolated molecules.

It consists of one carbon atom surrounded by three oxygen atoms, in a trigonal planar arrangement, with D molecular symmetry.

Many transition metal complexes with electronic configuration d-d are capable of spin crossover (and d when molecular symmetry is lower than O).