An inaugural cohort of students joins quantum research labs around the Midwest with the Open Quantum InitiativeOpen Quantum Initiative A summer undergraduate fellowship launched last week to support emerging scientists and engineers from historically unrepresented backgrounds who want to dive into a budding field of science and quantum information. (QISE).
Through a 10-week residency research program called the Open Quantum Initiative (OQI) Student Fellowship, a dozen students from colleges and universities across the country will expand their understanding of QISE and also connect with leaders in academia and industry.
“The more people from different backgrounds you have, the more ideas you have,” said Dr. Katherine Harmon, the Maria Goeppert Mayer Fellow at the Argonne National Laboratory of the U.S. Department of Energy and one of the early career researchers. who helped bring this about. initiative to life. “And with new ideas coming up, you find new approaches to solving problems that I may not even be aware of. It benefits us all. “
STEM fields, especially in computing and engineering, continue to suffer from a lack of racial, ethnic, and sexual diversity. According to a recent report by the Pew Research Center, black and Hispanic communities remain particularly underrepresented in the STEM workforce. However, almost 70% of OQI classmates identify as Hispanic, Latino, or black. And almost half are first-generation students. Women also make up half of the cohort.
“This will be my first formal opportunity to delve into quantum computing, which I have been interested in for some time,” said Ariadna Fernandez, a senior professor of computer science at the University of Illinois-Chicago (UIC). as one of the cohorts. “Because this field is so early, it can be hard to find these opportunities to explore it.”
Quantum science and engineering are still years away from full-scale commercial deployment. But it has the potential to address major issues that were previously almost impossible to solve – and to do so quickly. Drug discovery could also become much faster and more accurate. As this field takes off, researchers like Harmon want to make sure it’s inclusive.
“Most of us in the cohort didn’t follow the traditional university roadmap,” said Fernandez, who spoke about how she moved to UIC after going to a community college to save money. “We all had roadblocks on the way. Some of us, for example, have taken gap semesters between community college and university for different reasons. And sometimes when you want to enter these fields as quantum computing, it can be difficult to do so if you are not following specific paths. I appreciate that we still have this great opportunity. “
Students will receive a mentor from researchers through the Chicago Quantum Exchange (CQE), which is based at the University of Chicago. The CQE network is anchored by the U.S. Department of Energy’s Argonne National Laboratory and Close National Accelerator Laboratory, the University of Illinois Urbana-Champaign, the University of Wisconsin-Madison and Northwestern University.
Working with their mentors, students will complete a research project within a QISE group by the end of the program.
“This research experience in the program struck me as it can help students identify as scientists and engineers rather than passively receive information from textbooks,” said Dr. Wendy Hill, Rappolt, Professor Emeritus of Neuroscience and co-director of the Hanson Center for Inclusive STEM. Education at Lafayette College. “They become STEM makers. This helps them feel a sense of belonging. And there’s a lot of research on how cohorts help improve that sense of belonging and inclusion. “
Hill named the Meyerhoff Scholars Program at the University of Maryland Baltimore County (UMBC) a highly regarded national model of this cohort approach. For years, the Meyerhoff Program has consistently supported underrepresented students who are engaged in STEM research and careers. Much of that success comes from a focus on community.
“It’s about helping them understand the commitment we have to each other as a team,” said Mitsue Wiggs, deputy director of the Meyerhoff Scholars Program. “If I got an A, but my partner got a C, then that wasn’t a success, so how can I help my partner get that A? Another of Meyerhoff’s cornerstones is high expectations. We let them know it’s a compliment, which we hold so high for you. One of our mantras is that Meyerhoff is ten times the norm. “
To similarly grow a sense of community, the OQI cohort will stay connected after the summer is over. During the next academic year, like-minded people will have opportunities to meet almost every month. Past peers will additionally have the opportunity to guide future peers.
The OQI fellowship program for this summer is funded in part by the University of Chicago, Q-NEXT at Argonne National Laboratory, the Illinois Quantum Information Science and Technology Center at the University of Illinois Urbana-Champaign, HQAN at the University of Wisconsin. Madison. , and The Ohio State University.
Rebecca Kelliher can be reached at email@example.com.
Job Roles: Career roles can range from a quantum researcher, a quantum analyst, to a quantum computing leader. Quantum science is without a doubt one of the most exciting fields of research. It can be seen as the science of tomorrow, the field from which our next great inventions are likely to come.
What language is quantum computing written in?
QCL (Quantum Computer Language) is the most advanced implemented quantum programming language. Its syntax is similar to the C programming language and classical data types are similar to data types in C. Read also : Thomaston Grammar School students write non-fiction books with the help of a professional author. The basic built-in quantum data type in QCL is qreg (quantum register).
Is C++ used in quantum computing?
Quantum is a modern general-purpose multi-threaded quantum computer library written in C 11 and composed solely of title files. The library is not limited to quantum systems or specific quantum information processing tasks, being capable of simulating arbitrary quantum processes.
Does quantum computing needs coding?
To get started with quantum, you probably need to know some basics about programming. Although there are currently a number of programming languages that are entirely designed to program quantum computers, you do not need to learn such languages when entering the field.
What is the highest paid job in NASA?
What is the lowest paid job at NASA? At NASA, the highest paid work is Group Product Manager at $ 223,604 annually and the lowest is Sr-Table Support at $ 41,000 annually. Average NASA salaries by department include: Operations at $ 78,312, Engineering at $ 117,869, HR at $ 116,458 and Legal at $ 149,483. Half of NASA salaries are over $ 117,103.
Is NASA a high paying job?
NASA employees earn an average of $ 65,000 a year, or $ 31 an hour, which is 2% lower than the national average of $ 66,000 a year. According to our data, the highest paid job at NASA is Inventor at $ 240,000 annually, while the lowest paid job at NASA is Researcher at $ 18,000 annually.
Can I master in quantum physics?
While there are no master’s degrees specifically in quantum physics available in the United States, students may enroll in more general master’s programs in physics and use their coursework to concentrate on quantum physics.
How can I become a quantum physicist? If you are aiming to become a quantum physicist, you must complete four years of undergraduate training. You can also complete an additional two years of teaching to earn a master’s degree followed by five years of doctoral training.
Is quantum physics hard to study?
Quantum mechanics is considered the most difficult part of physics. Systems with quantum behavior do not follow the rules to which we are accustomed, they are difficult to see and difficult to “sense”, can have controversial features, exist in several different states at once – and even change depending. about whether they are observed or not.
Can you study quantum physics?
Currently, there are no degrees available specifically in the field of quantum physics, which is the study of quantities of energy called quantities. However, students can study quantum physics as part of physical education programs at the undergraduate level.