delocalized

The delocalized electrons are free to move throughout the plane.

If a material contains many delocalized bonds it is likely to be soft.

These form delocalized π-electrons that can be excited by radiation.

But, chemists are slow to switch from the delocalized electrons view.

The actual structure with delocalized electrons is called a resonance hybrid.

Due to the delocalized electrons between the layers, it can conduct electricity very well.

Electrical conductivity: Poor, as there are no delocalized electrons.

Delocalized electrons are contained within an orbital that extends over several adjacent atoms.

Delocalized electrons are important for several reasons.

In a metal, semimetal or degenerate semiconductor, lies within a delocalized band.

The left side (from ionic to metallic) is for delocalized bonds with varying electronegativity difference.

Both feature amino groups linked to electron-withdrawing centers that can participate in delocalized bonding.

Metals make relatively good conductors of heat, primarily because the delocalized electrons are free to transport thermal energy between atoms.

These fluorophores fluoresce thanks to delocalized electrons which can jump a band and stabilize the energy absorbed.

This property can be found in quantum dots, certain lanthanides and certain organic molecules with delocalized electrons.

The formulation should not be interpreted as containing radical anion, but rather that there is a delocalized valence "hole".

Carbon nanotubes are metallic or semiconducting, based upon delocalized electrons occupying a 1-D density of states.

Molecules which have a conjugaated system have special properties created by the greater sharing of the delocalized electrons among many atoms.

However in some cases a bandstructure can result in which there are two delocalized sub-bands with states of opposite spins that have different energies.

The delocalized electrons allow metal atoms to slide past one another without being subjected to strong repulsive forces that would cause other materials to shatter.

Delocalized electrons also exist in the structure of solid metals, where the d-subshell interferes with the above s-subshell.

Each carbon atom contributes one electron to a delocalized system of electrons that is also a part of the chemical bonding.

Due to the delocalized nature of dithiolenes, metal dithiolenes often exist in multiple oxidation states.

The conventional understanding of pi stacking involves quadropole interactions between delocalized electrons in p-orbitals.

Metallic structure consists of aligned positive ions (cations) in a "sea" of delocalized electrons.