An international
team of physicists working at the Institute of Nuclear Physics at Johannes Gutenberg University Mainz (JGU) in Germany has measured the mass of a «strange» atomic nucleus with the aid of an innovative technique that is capable of significantly greater precision than that of previous methods.
Not exact matches
«For the experimenters it's tremendous because you have to see the light at the end
of the tunnel,» says Ettore Majorana, a
physicist and Virgo
team member with INFN in Rome, who
worked on the specific technical problems.
Amazingly,
physicist Serge Haroche and his
team at École Normale Supérieure in Paris reported in August that they were able to watch the process
of this collapse as it happened in a photon, one
of the most difficult — and most useful — particles to
work with in experimental physics.
But the new
work, by a
team of engineers from the French ground improvement company Ménard and
physicists from Aix Marseille Université in France, is the first to put a seismic wave cloak to the test.
Working with a
team of mathematicians and
physicists, Osorio compared the timing and strength
of epileptic seizures with equivalent measurements
of earthquakes in Southern California.
For several years, I
worked on a small
team of physicists and biologists.
In their paper published in Nature the
physicists from the University's College
of Science,
working with an international collaborative
team at CERN, describe the first observation
of spectral line shapes in antihydrogen, the antimatter equivalent
of hydrogen.
The day before, Kevin Lesko, a
physicist at the University
of California, Berkeley, who leads the DUSEL design
team, explained how it would
work.
A
team led by chemist David Leigh
of the University
of Manchester Institute
of Science and Technology have been
working with
physicist colleagues to design stable and cheap materials with a property known as «photoluminescence».
A
team of scientists
working at the U.S. Department
of Energy's (DOE) Argonne National Laboratory and led by Northern Illinois University
physicist and Argonne materials scientist Zhili Xiao has created a new material, called «rewritable magnetic charge ice,» that permits an unprecedented degree
of control over local magnetic fields and could pave the way for new computing technologies.
Researchers at the U.S. Naval Research Laboratory (NRL) Center for Computational Materials Science,
working with an international
team of physicists, have revealed that nanocrystals made
of cesium lead halide perovskites (CsPbX3), is the first discovered material which the ground exciton state is «bright,» making it an attractive candidate for more efficient solid - state lasers and light emitting diodes (LEDs).
«There is the possibility that one could use the hollow spheres as a means
of chemical delivery agents, or microscopic containers
of some kind, but some more
work would need to be done here just to check what happens inside the spheres, in terms
of sample heating,» said David McGloin, a
physicist at the University
of Dundee in the U.K. not connected with the Australian
team.
You will therefore
work with diverse research
teams including space
physicists exploiting ground - based instruments and space missions to study the ionospheres and magnetospheres
of Earth and the other planets, and statisticians developing statistical methodology to understand the behaviour
of extreme events in real - life environmental applications.
Initially a particle
physicist working in the Higgs Boson group, Joel loved the Maths Pathway vision and joined the
team when it was run out
of Richard's shed.
I thought it worth noting how such discoveries almost always build on a body
of earlier
work — in this case by another
physicist, Nick Holonyak Jr., who paved the way for this
team's achievement with the invention
of the first practical (red) LED, in 1962.
Occupations in scientific research and development have become increasingly interdisciplinary, and as a result, it is common for
physicists, chemists, materials scientists, and engineers to
work together as part
of a
team.
Not just understand it well enough to say lots
of nifty words about it — well enough to start from the basic empirical laws and principles and derive and demonstrate nearly the whole thing through the introductory classical level at the blackboard, without notes, as I do several times a year in front
of several hundred very bright students a year,
working with a
team of Ph.D.
physicists who are my co-instructors (with perhaps a century
of teaching experience between us who, one would think, would correct my errors if I made any egregious ones along the way).
Experienced senior manager and
physicist with wide - ranging technical program and project management skills covering all aspects
of consumer electronics and telecommunications product delivery including OEM management, interdisciplinary
team building and emerging technology applications with demonstrated ability to
work in diverse cultural and organizational structures.