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A recent major investment in ���ӽ� University research infrastructure has resulted in the installation of a field emission scanning electron microscope in the University’s (MRC) facility. The instrument has introduced dramatic new imaging capabilities to researchers at the University and at partner institutions in the region.

The new instrument demonstrates the University’s commitment to supporting and enabling cutting-edge research in important fields like biomedical engineering, materials science and quantum computing, says , director of research operations in the .

The Zeiss will serve researchers across disciplines and career stages, from advanced undergraduates and graduate students to postdoctoral scholars and faculty. The Zeiss also supports the campus research group and Central New York’s rapidly expanding semiconductor and quantum technology ecosystem. The instrument was funded by a $335,000 investment by the Office of Research, the and individual faculty contributors.

On Campus and Beyond

The microscope is part of the Office of Research’s efforts to build shared, core facilities available to users across the University and the greater ���ӽ� region, says , vice president for research. “Strong core facilities are a force multiplier for our outstanding faculty and student researchers, providing access to state-of-the-art scientific instruments without the burden of having to purchase and maintain them individually.”

“For researchers who once drove an hour to use a scanning electron microscope, that capability is now right here, benefiting researchers on our campus, in our community and throughout the region,” Steinbacher says. It also serves as a recruiting tool because it demonstrates to prospective graduate students, postdoctoral scholars and faculty that state-of-the-art instrumentation is readily accessible at ���ӽ�, he says.

A Billionth of a Meter

Its resolution of 1.6 nanometers means the Zeiss can zoom down to the nanoscale, revealing details as small as a billionth of a meter, sharp enough to capture images of computer chip components, nanoparticles, bacteria and living cells, Steinbacher says.

It captures the shape and texture of an object’s surface in detailed, three-dimensional images versus thin cross-sections of materials. Because its electron beam works at lower energy levels, the microscope also offers highly detailed viewing of soft or non-metallic materials that typically are difficult or impossible to examine with older equipment, Steinbacher says.

Conventional electron microscopes require samples to be stripped of all moisture and placed under high vacuum, but some materials fall apart or change when dried out. Zeiss permits variable pressure imaging, so air pressure inside the imaging chamber can be adjusted to view samples that aren’t bone-dry. That lets researchers examine hydrogels, drug-delivery particles and biological samples in a more natural state. That capacity did not previously exist at ���ӽ� University or other area institutions, according to Steinbacher.

Who Will Use It

Biomedical and chemical engineering researchers can use the microscope to examine polymer film morphology. Environmental scientists can image rocks and fossils. Others will use it for battery technology research and catalyst design. The group and scientists in electrical engineering, computer science and physics can conduct device characterization—testing device effectiveness and checking for flaws.

, technical director of the , says the Zeiss enables exciting new levels of research. “It lets researchers image the surface appearance of synthetic materials, such as polymers or other engineered materials, and biological samples, such as cells, tissues and organisms, at higher resolution and better definition compared to existing instruments in the area.”

The instrument “is a critical addition to ���ӽ�’s growing suite of fabrication and characterization tools for next-generation quantum technologies,” says , assistant professor of electrical engineering and computer science in the College of Engineering and Computer Science. “We’ll use it to image our superconducting devices at the nanometer scale, hunting down the surface defects and contaminants that limit their performance.”

, assistant professor of physics in the College of Arts and Sciences, says the Zeiss will assist in prescreening superconducting qubit devices—the tiny, ultra-cold circuits that are the building blocks of quantum computers—from device batches fabricated elsewhere. “That will help us focus on the most promising devices and let students make the connection between the abstract shapes they draw on computer screens and the actual footprints of the tiny electrical circuits their designs imprint on the chips.”

For more information about of University instruments and facilities, visit the Core Facilities webpage.