EXPERIMENTAL PHYSICIST II (Noise)
Full time / Direct Hire: Burnaby, BC Canada (Hybrid)
D-Wave (NYSE: QBTS) is a leader in the development and delivery of quantum computing systems, software, and services, and is the world’s first commercial supplier of quantum computers—and the only company building both annealing quantum computers and gate-model quantum computers. Our mission is to unlock the power of quantum computing today to benefit business and society. We do this by delivering customer value with practical quantum applications for problems as diverse as logistics, artificial intelligence, materials sciences, drug discovery, scheduling, cybersecurity, fault detection, and financial modeling. D-Wave’s technology has been used by some of the world’s most advanced organizations including Mastercard, Deloitte, Davidson Technologies, ArcelorMittal, Siemens Healthineers, Unisys, NEC Corporation, Pattison Food Group Ltd., DENSO, Lockheed Martin, Forschungszentrum Jülich, University of Southern California, and Los Alamos National Laboratory.
Our company and its innovations have appeared in the pages of Time Magazine, Fast Company, MIT Technology Review, Forbes, INC Magazine and Wired. As of August 8, 2022, our company is publicly traded on the New York Stock Exchange as $QBTS.
About the role:
We are looking for a creative, energetic, and self-motivated Experimental Physicist to join our Processor Development (PD) team. The PD team at is composed of experienced and talented superconducting designers, fabrication engineers, software developers and physicists who work together to create the processors at the heart of our quantum computer and are constantly pushing the boundaries of the technology of the future.
In this challenging and exciting position, you will work as part of a small team experimentally characterizing noise in our superconducting qubits through a suite of measurements, with the goal of improving the real-world performance of our quantum processors. You will refine and develop models to further our understanding of the charge and flux noise in several frequency bands. You will closely with our fabrication, design and calibration teams to understand the impact of various materials, process, IO and design elements on different sources of noise and propose experiments to test your hypotheses. You will regularly communicate and collaborate with other PD scientists, designers, engineers, cryogenic experts and applications developers.
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What you will do:- Develop and execute experimental procedures to quantify, understand, and operate a wide range of superconducting devices
- Come up with new ideas to improve processor operation or performance and develop parametric designs to implement them
- Develop theoretical models and simulations to represent and understand experimental results on physical devices
- Develop analysis routines to fit theoretical models to data and to detect outlier behaviour in large complex systems of superconducting devices
- Regularly and clearly document experimental results for the broader processor development team
- Create and contribute to LISP software infrastructure for modeling, calibrating and operating processors
- Communicate and collaborate with other internal teams at D-Wave including marketing, intellectual property, applications development and engineering
About You- Ph.D. or M.Sc. in physics or a related discipline, or equivalent experimental research experience
- Strong critical thinking and technical problem solving skills
- Skill in independent research and evidence of deep understanding in your area of expertise
- An ability to come up to speed in new technical topics quickly and effectively
- Strong software development experience related to experimental design and automation, data acquisition, and data analysis; and a willingness to learn new programming languages and software concepts as needed
- A collaborative mindset and a demonstrated ability to work effectively on an interdisciplinary team, on a wide variety of problems
- Excellent communication skills and experience with summarizing experimental results for a broad audience
- Ability to adapt to shifting priorities in a time-sensitive environment
- Exceptional candidates will have a solid background in one or more of the following: quantum information, digital or analog superconducting devices, device physics, noise models and characterization
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$90,000 - $130,000 a year
The Canadian national average salary range for this role is $90,000 to $130,000. The disclosed range reflects the average base salary minimum and maximum target for new hires in the position within Canada. We are looking for candidates in multiple career levels and the respective salary range for the successful candidate will be adjusted for the applicable level and geographic differential associated with the location at which the position may be filled. Actual compensation within the range is based on factors including but not limited to relevant education, skills, licenses, training and certifications, experience, as well as business needs.
In addition to base salary, this role is also eligible to participate in our Annual Incentive Plan (Bonus plan), equity grants and programs, PTO, and a comprehensive benefit package including medical, dental, vision, life and AD&D insurance, STD, LTD, and Travel Insurance.
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Additional information:
We celebrate diverse perspectives to drive innovation in our pursuit. Our employees range from distinguished domain experts with decades of experience in their respective fields, to bright and motivated graduates eager to make their mark.
Our diverse and innovative team will make you feel appreciated, supported and empower your career growth at D-Wave. Join us today!
THE FINE PRINT:
No 3rd party candidates will be accepted.
It is D-Wave Systems Inc. policy to provide equal employment opportunity (EEO) to all persons regardless of race, color, religion, sex, national origin, age, sexual orientation, gender identity, genetic information, physical or mental disability, protected veteran status, or any other characteristic protected by federal, state/provincial, local law.
