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Quantum Hardware Engineer Jobs in Rochester, NY (NOW HIRING)

Quantum Computing Engineer I

Batavia, NY · On-site

$79K - $104K/yr

SQMS is seeking a quantum computing engineer to study device performance and improve measurement ... Deploying hardware and software controls for qubit characterization and readout, as well as ...

Quantum Hardware Engineer information

See Rochester, NY salary details

$50.3K

$144.3K

$193.9K

How much do quantum hardware engineer jobs pay per year?

As of Jul 8, 2026, the average yearly pay for quantum hardware engineer in Rochester, NY is $144,281.00, according to ZipRecruiter salary data. Most workers in this role earn between $121,900.00 and $160,800.00 per year, depending on experience, location, and employer.

What engineers make $300,000 a year?

Senior engineers in specialized fields such as quantum hardware engineering, software engineering, and data science can earn $300,000 or more annually, especially with extensive experience, advanced skills, and working in high-demand industries or companies. These roles often require advanced degrees, certifications, and expertise in cutting-edge technologies or tools.

What is the difference between Quantum Hardware Engineer vs Quantum Software Engineer?

AspectQuantum Hardware EngineerQuantum Software Engineer
Required CredentialsBachelor's/Master's in Physics, Electrical Engineering, or related fields; experience with hardware design and fabricationBachelor's/Master's in Computer Science, Software Engineering, or related; programming skills in Python, C++, or similar
Work EnvironmentLaboratories, hardware prototyping facilities, clean roomsSoftware development environments, cloud platforms, simulation tools
Employer & Industry UsageQuantum tech companies, research labs, hardware manufacturersTech firms, research institutions, software companies working on quantum algorithms

Quantum Hardware Engineers focus on designing, building, and testing physical quantum devices, while Quantum Software Engineers develop algorithms and software to run on quantum hardware. Both roles are essential in advancing quantum technology but differ in their focus and skill sets.

What are some common challenges faced by Quantum Hardware Engineers when scaling up quantum systems?

Quantum Hardware Engineers often encounter significant challenges when scaling quantum systems, such as maintaining qubit coherence and minimizing error rates as the number of qubits increases. Integrating control electronics and cryogenic systems while ensuring signal fidelity is another complex aspect of the role. Collaboration with physicists, materials scientists, and software engineers is essential to troubleshoot hardware limitations and develop scalable architectures. Overcoming these challenges requires creative problem-solving and a multidisciplinary approach, making the role both demanding and highly rewarding.

What engineers make $500,000?

Senior engineers in specialized fields such as software engineering, data engineering, and certain hardware engineering roles can earn $500,000 or more annually, especially with experience, bonuses, and stock options. High-level positions often require advanced skills, certifications, and leadership responsibilities within large companies or tech firms.

What are Quantum Hardware Engineers?

Quantum Hardware Engineers are professionals who design, develop, and maintain the physical systems that enable quantum computing. They work on building and optimizing quantum processors, cryogenic systems, control electronics, and other hardware components necessary for quantum computers. Their role is essential for advancing the practical implementation of quantum technologies, collaborating closely with physicists, software engineers, and researchers to push the boundaries of computational power. These engineers often have backgrounds in physics, electrical engineering, or materials science, and are skilled in both theoretical and hands-on laboratory work.

How much does a quantum hardware engineer make?

The average salary for a quantum hardware engineer ranges from $80,000 to $150,000 annually, depending on experience, education, and location. Senior roles or those with specialized skills in cryogenics, quantum circuits, or fabrication may earn higher salaries, often exceeding $180,000.

What does a quantum hardware engineer do?

A quantum hardware engineer designs, develops, and tests physical components of quantum computers, such as qubits, superconducting circuits, and cryogenic systems. They work with specialized tools and materials, often requiring knowledge of quantum physics, electrical engineering, and cryogenics, to improve the stability and performance of quantum devices.

What are the key skills and qualifications needed to thrive as a Quantum Hardware Engineer, and why are they important?

To thrive as a Quantum Hardware Engineer, you need a deep understanding of quantum physics, electrical engineering, and materials science, often supported by an advanced degree (such as a PhD) in a related field. Familiarity with technical tools like cryogenic systems, microwave electronics, and quantum measurement instruments, as well as programming languages such as Python, is typically required. Strong problem-solving abilities, attention to detail, and effective collaboration skills distinguish top candidates in this role. These competencies are critical for designing, building, and optimizing complex quantum devices that advance the field of quantum computing.
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Quantum Postdoctoral Researcher for 3D Cavity Quantum Hardware

Quantum Postdoctoral Researcher for 3D Cavity Quantum Hardware

Fermilab

Batavia, NY • On-site

$69K - $92K/yr

Full-time

Medical, Dental, Vision, Life, Retirement, PTO

Posted 14 days ago


Job description

The expected hiring range for this position is:

$69,800.00-$92,600.00.

Please note that the pay range information is a general guideline only. The pay offered to a selected candidate will be determined based on factors such the scope and responsibilities of the position, qualifications of the selected candidate, business considerations, internal equity, and external market pay for comparable jobs.

This position can potentially offer relocation. This is a fixed term position for the period of three years.

About the Position:

The Superconducting Quantum Materials and Systems Center (SQMS) at Fermilab seeks a Quantum Postdoctoral Research Associate - 3D Cavity Quantum Hardware to support critical research activities within the Superconducting Quantum Materials and Systems (SQMS) Center. This position focuses on the development of advanced superconducting quantum hardware, with particular emphasis on 3D cavity-based quantum processing units and ultra-coherent superconducting cavity platforms for quantum information processing. Under general direction and in consultation with senior scientists, the successful candidate will conduct independent research aligned with the Laboratory's mission and contribute to the development, measurement, control, and integration of next-generation quantum systems. This role will help maintain technical continuity, accelerate progress on key SQMS deliverables, and strengthen Fermilab's leadership in superconducting quantum technologies, modular quantum architectures, and quantum sensing applications.

What your day-to-day as a Quantum Postdoctoral Research Associate will look like:

  • Conduct research in superconducting quantum hardware, with emphasis on 3D cavity-based quantum processing units, bosonic modes, qudits, and circuit QED systems.
  • Design, simulate, build, install, commission, and characterize new or upgraded elements of superconducting quantum experiments, including ultra-coherent 3D cavities, ancilla qubits, tunable couplers, microwave control and readout hardware, filters, interconnects, and cryogenic measurement systems.
  • Develop and implement experimental techniques for quantum control, readout, calibration, and characterization of multimode superconducting quantum systems.
  • Contribute to the development of large-dimensional bosonic qudits and multimode quantum processors for quantum computing, HEP-relevant quantum simulation, and hardware-efficient quantum information processing.
  • Participate in data acquisition, conduct analysis, develop models and simulations, and present/publish outcomes at conferences and/or in refereed journals.
  • Contribute to research directions relevant to bosonic quantum information processing, modular superconducting quantum architectures, error-detected or error-corrected operations, quantum interconnects, and related quantum sensing applications.
  • Work collaboratively with Fermilab scientists, engineers, technicians, students, postdocs, and external collaborators across the SQMS Center.
  • Perform other duties as assigned by supervisor.
  • Abide by and is responsible for performing all duties in accordance with all environmental, health and safety regulations and practices pertinent to this position.


Essential Competencies and Attributes for Success:

  • Appointees usually have recently completed their PhD (often within the last two years) or are expected to complete it within the current calendar year.


Applicable Knowledge, Skills and Abilities Required:

  • Demonstrated potential to make contributions to the Laboratory that will subsequently qualify them for appointment as an Associate Scientist.
  • Strong background in quantum mechanics and experimental physics, applied physics, electrical engineering, or related areas.
  • Knowledge of superconducting quantum circuits, microwave resonators, circuit QED, quantum measurement, or related quantum hardware platforms.
  • Ability to work independently while contributing effectively to a highly collaborative research environment.
  • Ability to communicate effectively through written reports, presentations, publications, and technical discussions.
  • Self-motivation, scientific curiosity, and interest in developing next-generation superconducting quantum hardware platforms.

Additional Skills That Will Set You Apart:

  • Experience with superconducting qubits, 3D cavities, microwave resonators, bosonic modes, qudits, tunable couplers, or related superconducting quantum systems.
  • Experience with cryogenic microwave measurements, quantum control, microwave electronics, RF engineering, or low-temperature experimental techniques.
  • Experience with multimode quantum control, bosonic encoding, qudit operations, error-detected operations, or quantum processor calibration.
  • Experience with device modeling, electromagnetic simulation, circuit simulation, Hamiltonian modeling, or numerical analysis of quantum systems.
  • Experience with experimental automation, calibration, data acquisition, and data analysis.
  • Interest in the intersection of superconducting quantum computing, bosonic quantum information, modular quantum architectures, and HEP-relevant quantum applications.

Work Arrangement:

  • Onsite: This is an onsite role, and the candidate must be able to work from our Batavia office.

Benefits/Perks:

Fermilab offers a competitive and comprehensive benefits program, including:

  • Medical, Dental, Vision and Flexible Spending Account
  • Paid time-off
  • Life insurance
  • Short and Long-term disability insurance
  • Retirement benefits
  • Onsite day care

Why Fermilab:
Fermilab is America's premier laboratory for particle physics and accelerator research, funded by the U.S. Department of Energy. We support discovery science experiments in Illinois and locations around the world, including deep underground mines in South Dakota and Canada, mountaintops in Arizona and Chile, CERN in Europe and the South Pole.

Pre-Employment Screening:


Drug-Free Workplace & Pre-Employment Screening

Fermilab is dedicated to fostering a safe, productive and drug-free environment. An offer of employment is contingent upon the successful completion of a background check and drug screening.

HSPD-12

In accordance with Homeland Security Presidential Directive 12 (HSPD-12) new employees are required to obtain and maintain a HSPD-12 Personal Identity Verification (PIV) Credential. To obtain this credential, new employees must successfully complete and pass a federal background check investigation. This investigation includes a declaration of illegal drug activities, including use, supply, possession, or manufacture. This includes marijuana and cannabis derivatives, which are still considered illegal under federal law, regardless of state laws. Failure to obtain or maintain such government access authorization could result in the withdrawal of a job offer or future termination of employment.

Foreign Government Sponsored Activities

Fermilab employees, and certain guest researchers and contractors, are subject to particular restrictions related to participation in Foreign Government Sponsored or Affiliated Activities, as defined and detailed in United States Department of Energy Order 486.1A. Such individuals will be asked to disclose any participation for review by Fermilab's Office of General Counsel.

REAL-ID Requirement for access to Fermilab Campus
Fermilab requires all members of the public to produce a REAL-ID, or equivalent, to access the Fermilab Campus for interviews or career events. A list of acceptable forms of ID can be found here: https://get-connected.fnal.gov/wp-content/uploads/2021/09/REALID-Documents.pdf. If a candidate is selected for an interview but does not possess any of the equivalent documents, we may schedule a virtual interview.

Equal Opportunity Statement

Fermilab is an equal opportunity employer. We evaluate qualified applicants without regard to race, color, religion, sex, age, national origin, disability, veteran status, genetic information, and other legally protected categories.