women-scientists-from-greece

"Unquestionably, the s approach the diagnostic task with a level of intelligence, flexibility, and common sense that is difficult to duplicate with a computer. Thus far, research findings have demonstrated only that computers are the best savants when it comes to executing mathematically rigorous steps toward the solution of narrowly defined problems. Nonetheless, the radiologist's approach is not devoid of limitations. There are well-documented errors and variations in the human interpretation of ... Some study findings even indicate that the same errors are being made now, as they were in earlier decades ..."

"has been the cornerstone for research advancement, scientific innovation, , and economic prosperity ... The ’s Leadership Computing Facilities have a long history of enabling researchers to accelerate and deliver practical breakthroughs for some of the most computationally challenging problems. These research and development advances happen across many disciplines such as , , , astrophysics, biology, and engineering to name a few. In addition, supercomputing has proven to be an effective ally to our society by helping us address critical and pressing challenges, such as climate change, , and . For instance, supercomputers help researchers develop personalized medical treatments as well as better predict and manage the effects of natural disasters such as floods and earthquakes through the use of advanced s. ... These discoveries help shape our understanding of the universe, bolster US economic competitiveness, and contribute to a better future. ..."

"... refers to s that can perform 1 billion, billion full precision calculations per second. ... the set that goal a decade ago, not only to achieve exascale computing but to achieve it with extreme . And both our laboratories are very proud to have delivered on that vision with these two systems that are dedicated to . We are already seeing how exascale computing is driving innovation and breakthroughs in many scientific domains, including medicine, from all the way to clinical care. And this is a crucial milestone for science and technology because, now, we can tackle challenges that previously we could not. We can tackle them faster. We can analyze large scales of data with extreme efficiency. We can do simulations of very s."

"My best memories are memories of physics questions — not even the answers. It's very bizarre."

"I grew up, indeed, in West Macedonia. This is in Greece. And I was a terror of a child because I was taking apart everything, just like all engineers and physicists and inventors. I come from a family that they're more artists, designers, and military people rather than scientists. So that was a surprise to my parents, that I was very determined to follow a scientific path in any way, form, or shape, or an engineering path. Initially, I really wanted to be an astronaut, like if you are in West Macedonia, what else would you want to be? An astronaut."

"The curveball is that we don’t understand the mass of the Higgs, which is about 125 times the mass of a . When we discovered the Higgs, the first thing we expected was to find these other new supersymmetric particles, because the mass we measured was unstable without their presence, but we haven’t found them yet. (If the Higgs field collapsed, we could bubble out into a different universe — and of course that hasn’t happened yet.) That has been a little bit crushing; for 20 years I’ve been chasing the supersymmetrical particles. So we’re like deer in the headlights: We didn’t find supersymmetry, we didn’t find as a particle."