Graduate Students – Maine College of Engineering and Computing /mcec 91 Wed, 12 Nov 2025 18:53:00 +0000 en-US hourly 1 https://wordpress.org/?v=6.9.4 Electronics for Extreme Environments: 91 Pushes Sensors Beyond Limits /mcec/2025/11/12/electronics-for-extreme-environments-umaine-pushes-sensors-beyond-limits/ Wed, 12 Nov 2025 18:53:00 +0000 /mcec-new/?p=30406

ORONO, Maine — Imagine sensors that don’t just survive extreme heat — they turn it into power. University of Maine engineers have built a simple wireless circuit that can operate from room temperature to more than 550 degrees Fahrenheit, opening the door to rugged, self-powered monitoring systems in environments such as jet engines, oil wells and spacecraft.

In a breakthrough with sweeping industrial implications, 91 researchers designed a minimalist oscillator that enables sensors to  transmit critical data wirelessly in environments where people, and conventional electronics, cannot survive.

“This work is important because of the potential applications, especially in terms of industrial safety. Not only does constant monitoring in industrial applications allow for more efficient operation with minimal production time loss, but it maximizes safety for human operators by removing the possibility of a surprise failure” said lead author Jude Zanoni, an electrical engineering graduate student and lead author on the study. “By using commercial components, we also demonstrated a potential avenue for cheap development of this technology.”

The research contributes to solving a decades-old problem: how to keep electronics stable in extreme heat without complex biasing, bulky power supplies or fragile components. Traditional silicon devices fail well below 300 degrees, forcing industry to rely on expensive, short-lived or wired systems in high-temperature operations. 91’s solution is different — a single-supply oscillator built with one silicon carbide transistor, delivering more than 12 dBm of output power to extend detection range and reliability.

“This is about building electronics that don’t just survive the heat, they could make it useful,” Zanoni. “The circuit produces the same amount of power as a pair of Bluetooth earbuds — but it keeps working at more than 570 degrees Fahrenheit.”

By reducing parts and stabilizing operation under uniform high-temperature testing, the 91 circuit produced up to nine times the power of previous designs at room temperature and nearly doubled at nearly 500 degrees. In practical terms, that’s like turning a walkie-talkie that only works across your yard into one that can reach across your neighborhood. At extreme heat, it still boosts detection range by about 50 percent, meaning problems can be spotted earlier and from farther away. Because the design can be paired with thermoelectric generators, these sensors could power themselves from the very heat they monitor, which eliminates the need for batteries or wires and makes them easier to deploy in remote or dangerous places.

Zanoni, originally from Lubec, Maine, came to 91 where he participated in a Research Experience for Undergraduates program introducing him to this research. He continued on to complete his undergraduate Honor’s Thesis on this topic and will continue to study  high temperature, harsh environment sensing in pursuit of a PhD at 91. 

The research, demonstrating robust modeling and successful fabrication under realistic harsh-environment testing, was recently published in IEEE Access under the title “”

Contact: Taylor Ward, taylor.ward@maine.edu

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91 engineers find new method for stronger, lighter 3D-printed parts /mcec/2025/07/21/umaine-engineers-find-new-method-for-stronger-lighter-3d-printed-parts/ Mon, 21 Jul 2025 17:14:57 +0000 /mcec-new/?p=27137

Engineers at the University of Maine are developing a new method to more accurately predict the strength of lightweight 3D-printed objects. This research, conducted at the university’s (ASCC), will enable designers to create more robust and reliable components by controlling strength when lightweighting virtually any plastic component.

The research team was made up of Philip Bean, research engineer at the ASCC, and Senthil Vel, professor of mechanical engineering, alongside Roberto Lopez-Anido, professor of civil engineering. Their study, recently published in , integrates advanced computer modeling with physical experiments to provide a more comprehensive understanding of how these parts will perform under stress.

They focused on gyroid infill, an intricate, repeating internal structure commonly employed in 3D printing to minimize weight while preserving structural integrity. By utilizing computer simulations to analyze the gyroid’s response to various forces, the team validated these predictions through experiments on 3D-printed prototypes. The findings offer insights into how this complex internal pattern contributes to a part’s overall performance; a factor often not possible with conventional analytical methods.

“This work allows us to design 3D-printed parts with greater confidence and efficiency,” said Bean, one of the lead researchers. “By understanding the precise strength of these gyroid-infilled structures, we can reduce material use and improve performance across industries.”

This method is anticipated to significantly benefit sectors demanding strong, lightweight materials, including aerospace, automotive and medical device manufacturing.

See the full publication, “,” for more information.

Contact: Taylor Ward, taylor.ward@maine.edu

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Maine College of Engineering & Computing presents its top annual awards /mcec/2025/04/30/maine-college-of-engineering-computing-presents-its-top-annual-awards/ Wed, 30 Apr 2025 21:52:20 +0000 /mcec-new/?p=23497
Yifeng Zhu, Chair of Electrical and Computer Engineering – Anthony Paine – Giovanna Guidoboni, Dean Maine College of Engineering and Computing – Mohamad Musavi, Associate Dean Maine College of Engineering and Computing

Edward T. Bryand Distinguished Engineering Award
Anthony “Tony” Paine, Co-Founder and CEO of HighByte Inc., as the 2025 recipient of the prestigious Edward T. Bryand Distinguished Engineering Award. Renowned for his visionary leadership in industrial software, Paine has played a pivotal role in transforming modern manufacturing through innovative data integration solutions that power Industry 4.0.

With a career defined by technical excellence and a deep commitment to solving real-world challenges, Paine has positioned HighByte as a leader in the industrial intelligence space. His customer-first mindset, combined with a forward-thinking approach to software design, continues to influence the evolution of smart manufacturing globally.

Established in 1979, the Edward T. Bryand Distinguished Engineering Award is the highest honor granted by the MCEC. It recognizes individuals outside the University whose achievements in engineering, research, and public service bring distinction to the profession. Paine’s exceptional contributions embody the spirit of the award, making him a fitting and celebrated recipient.

Giovanna Guidoboni, Dean Maine College of Engineering and Computing – Jean MacRae, Associate Professor of Civil and Environmental Engineering – Bill Davids, Chair of Civil and Environmental Engineering

Ashley S. Campbell Award
The 2025 Ashley S. Campbell Award was awarded to Jean MacRae, a respected environmental microbiologist and long-standing faculty member in the Department of Civil and Environmental Engineering. With a career marked by outstanding teaching, impactful research, and meaningful service, Dr. MacRae has profoundly shaped the education and experience of engineering students at 91.

The Maine College of Engineering & Computing honored outstanding alumni, faculty, staff, and students at the 45th Annual Edward T. Bryand Awards Ceremony, held April 14, 2025, at Buchanan Alumni House. The event gathered faculty, staff, industry professionals, friends, and family to celebrate the individuals whose work and dedication advance the College’s mission.

A national leader in biological remediation, Dr. MacRae has advanced the field through her innovative research and dedication to sustainability. Equally transformative has been her leadership of 91’s Engineers Without Borders chapter, where she has guided students in applying their engineering skills to improve infrastructure and quality of life in communities around the world.

Established in 1979, the Ashley S. Campbell Award is the College’s highest faculty honor, recognizing individuals whose teaching excellence, scholarly achievements, and service have brought distinction to engineering education. Dr. MacRae exemplifies the purpose of this award through her unwavering commitment to student success and her contributions to global engineering challenges.

Giovanna Guidoboni, Dean Maine College of Engineering and Computing – Kyle Guerrette, Building Manager – Masoud Rais-Rohani, Chair of Mechanical Engineering

Leila C. Lowell Award for Exemplary Staff Support

Kyle Guerrette, Building Manager of the Ferland Engineering Education and Design Center was recognized as the 2025 recipient of the Leila C. Lowell Award. Guerrette’s unwavering commitment to student success, safety, and hands-on learning has made him an essential figure in the day-to-day excellence of the College.

Established in 1983, the Leila C. Lowell Award honors staff members whose work has brought distinction to the field of engineering through outstanding support, service, and achievement. Kyle Guerrette exemplifies the spirit of this award and continues to be a cornerstone of the College’s thriving academic community.

Giovanna Guidoboni, Dean Maine College of Engineering and Computing – Evan K. Wujcik, Assistant Professor in Chemical and Biomedical Engineering – Peter Van Walsum, Chair of Chemical and Biomedical Engineering

Early Career Research Award

Evan K. Wujcik, Assistant Professor in Chemical and Biomedical Engineering and researcher at the Advanced Structures & Composites Center, received the Early Career Research Award. Dr. Wujcik’s work on nanosensors, green composites, and wearable technologies reflects a deep commitment to sustainable innovation across environmental and health applications.

Giovanna Guidoboni, Dean Maine College of Engineering and Computing – Reed Miller, Assistant Professor of Environmental Engineering

Early Career Teaching Award

Reed Miller, Assistant Professor in Civil and Environmental Engineering, received the Early Career Teaching Award for his student-centered teaching in life cycle assessment and engineering decision-making, and his impactful research applying Industrial Ecology to sustainability challenges.

Danilo Botero Lopez and family

Danilo Botero Lopez received the Graduate Teaching Assistant Award for his instructional excellence in Civil and Environmental Engineering, where he also contributes cutting-edge research in geotechnical and earthquake engineering.

Andre Khalil, Professor of Chemical and Biomedical Engineering – Jeremy Juybari – Yifeng Zhu, Chair of Electrical and Computer Engineering

Jeremy Juybari, Ph.D. candidate in Computer Engineering, earned the Graduate Research Assistant Award for his groundbreaking work at the intersection of machine learning and medical imaging in the CompuMAINE Lab.

91 the Bryand Awards

Established in 1979 by then-Dean Jim Clapp, the Edward T. Bryand Awards Ceremony recognizes individuals who exemplify excellence in teaching, research, engineering, and service. The first ceremony was held in 1980, with the Ashley S. Campbell and Edward T. Bryand Distinguished Engineering Awards as its founding honors. Over time, additional awards—including the Leila C. Lowell Award for staff and graduate student awards—were added, continuing a proud tradition of celebrating the remarkable people who shape 91 Engineering.


Contact: Christopher Karlen, christopher.karlen@maine.edu

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