Atomic, Molecular, and Optical Physics research have a long history from building the foundations of quantum mechanics to continuing today at the cutting edge of science. AMO is a scientific study on matter-matter and light-matter interaction. Researchers study these interactions on various scales from the atomic to the molecular level. These studies can bring revolutionary advances in our ability to use light to manipulate, control and measure the properties of atoms and molecules. AMO physicists strive to understand and control atoms, molecules, and light in new ways that were hardly dreamed about, only a decade ago.
Atomic, Molecular and Optical Physics aim to bring together leading academic scientists, researchers and research scholars to exchange and share their experiences and research results on all aspects of Atomic, Molecular and Optical Physics. It also provides a premier interdisciplinary platform for researchers, practitioners, and educators to present and discuss the most recent innovations, trends, and concerns, as well as practical challenges, encounter and solutions adopted in the fields of Atomic, Molecular and Optical Physics.
How Oscine Nest Conference Help here?
OSCINE NEST organizing global scientific even on Atomic, Molecular and Optical Physics. Oscine brings leading researchers and physicists to discuss and speak about most relevant, advanced treatments, approaches in the field of Atomic, Molecular and Optical Physics. The conference theme- “Exploring current trends in Atomic, Molecular, and Optical Physics” mainly focuses on most recent innovations, trends, and concerns, as well as practical challenges, encounter and solutions adopted in the fields of Atomic, Molecular and Optical Physics.
GSEAMO-2019, Welcomes all physicists, researchers, scholars, speakers, professor to participate and discuss topics in the fields of Atomic, Molecular and Optical Physics.
How Lasers related to AMO?
AMO physicists strive to understand and control atoms, molecules, and light in new ways that were hardly dreamed about, only a decade ago. Experiments pioneered in the Department of Physics and in the affiliated institute JILA resulted in two shared Nobel Prizes in Physics in 2001 for the creation of ultracold quantum gases and another in 2005 for breakthroughs in ultraprecise laser and optical physics.
Some of the fastest lasers in the world, whose pulse of light last less than a millionth of a billionth of a second, reside in experimental laboratories here, as well as theoretical studies of their potential exploitation for new ways to probe and manipulate matter.
Experiments and theory also tackle the fundamental chemical physics processes and reactions that occur in the cold reaches of interstellar clouds in space, of interdisciplinary interest for chemistry and astrophysics in addition to physics. Another frontier pursued by cutting-edge research here is the crafting of atom-light interactions so precise that a new generation of atomic clocks can be envisioned, whose accuracy approaches 1 second in the lifetime of the universe. This is the age of controlling nature at the quantum level, and this forefront area generates tremendous excitement on the Boulder campus and beyond. For More
Research opportunities in Atomic, Molecular, and Optical physics
As such, the signature scientific achievements in AMO physics are the developments of enabling experimental methodologies, and the application of these methodologies to Nobel-prize winning discoveries and to developing scientific knowledge in areas that extend across all of physics and other scientific disciplines including biology and chemistry.
Research opportunities in atomic, molecular and optical physics span a broad spectrum of topics, from the making of precision measurements of fundamental constants of nature to the measurements of parity violating effects in atoms. Other exciting areas in AMO physics are quantum optics; laser cooling and atom trapping; atom interferometers; the search for the electric dipole moment of the electron; the search for dark matter; studies of the consequences of Bose-Einstein condensation; generation and application of ultra-short pulses of x-rays; quantum computing and information processing; antimatter research; the exploration of the fundamental properties of gravity; and the spectroscopy novel molecules and solid state systems. Atomic physics techniques are also exploited in experiments focusing on fundamental issues in particle and nuclear physics, as well as condensed matter physics. For More
Thanks to all institutes and information providers for your valuable information.
- Oscine Nest
Spread your excellence with our Wings