Not exact matches
Carbon
atoms are shown in grey, hydrogen in white,
nitrogen in red, fluorine in
light blue and chlorine in green.
Also, the supernova's
light spectrum shows the presence of forms of carbon,
nitrogen, and oxygen
atoms that are considered unprecedented.
They are particularly good at identifying the position of
light atoms such as hydrogen, oxygen, carbon and
nitrogen in samples.
When a
nitrogen atom replaces a carbon in the crystal structure of diamond, it creates a
nitrogen - vacancy center, which can store information that is written and read out using
light.
Some of these
light - element nuclei also might be produced by cosmic rays shattering
atoms of carbon,
nitrogen, oxygen, and other elements in the interstellar medium.
The ensuing ability to achieve a controlled trade - off between emissive and photocatalytic behavior of CDs depending on
nitrogen atom positioning inside the aromatic domain is expected to bring substantial improvements on their efficiency for on - demand
light emission or energy conversion applications.
Reddish and bluish
light that often appears in the lower fringes of auroras is produced by ions striking
atoms of
nitrogen.
Light from oxygen
atoms is rendered blue in this image; hydrogen is shown as green, and
nitrogen as red.