A greater understanding of
the dynamics of chemical reactions is leading to better models of atmospheric chemistry.
«Astonishingly close agreement of our theoretical work and experimental data is providing important insights into
the dynamics of chemical reactions,» said Klippenstein.
Not exact matches
In the remaining years
of the 20th century, there is no doubt that the experimental investigation
of the
dynamics and mechanisms
of elementary
chemical reactions will play a very important role in bridging the gap between the basic laws
of mechanics and the real world
of chemistry.
The advance in modern microscopic experimental methods, especially crossed molecular beams and laser technology, has made it possible to explore the
dynamics and mechanisms
of important elementary
chemical reactions in great detail.
«With LCLS - II, we'll be able to bring the motions
of atoms much more into focus, which will help us better understand the
dynamics of crucial
chemical reactions.»
Understanding how particles mix in fluids has a number
of important applications — among them modeling
chemical reactions and cloud
dynamics.
These light pulses with different wavelengths, whose time separation can be adjusted with attosecond accuracy, are very powerful tools to investigate the structure
of matter and the
dynamics of ultrafast physical processes and
chemical reactions.
In order to fully understand the
dynamics during a
chemical reaction, scientists must be able to study all movements
of atoms and molecules on their basic time scale.
As the smallest structural change in the scale
of biological world, the isomerization and the catalysis
of this
reaction by isomerases is
of great interest, to bridge the
dynamics of chemical bonds and the biological functions
of the macromolecules.
Dr. Bruce Kay and his colleagues are applying and extending molecular - beam surface scattering techniques to ice surfaces to examine the
chemical kinetics and
reaction dynamics of molecular processes occurring both on the surface and within the bulk
of amorphous and crystalline ice films.
The origin -
of - life problem has been traditionally conceived as the
chemical challenge to find the type
of molecule and free - solution
reaction dynamics that could have started Darwinian evolution.
If the theory isn't correct then it undermines our understanding
of the science
of atoms, the electromagnetic spectrum, isotopes, fluid
dynamics and
chemical reactions.