Microscopy
| The world’s most advanced extreme-ultraviolet microscope is about to go online at the U.S. Department of Energy (DOE)’s Lawrence Berkeley National Laboratory (Berkeley Lab). SHARP gives researchers from the world's leading semiconductor companies a window into the future of computer-chip fabrication. |
The world’s most advanced extreme-ultraviolet microscope is about to go online at the U.S. Department of Energy (DOE)’s Lawrence Berkeley National Laboratory (Berkeley Lab).
The much-anticipated SHARP microscope (SEMATECH High-NA Actinic Recticle review Project) was conceived and built by scientists at Berkeley Lab’s Center for X-ray Optics (CXRO) and will provide semiconductor companies with the means to push their chip-making technology to new levels of miniaturization and complexity. The instrument is housed at the Advanced Light Source (ALS) at Berkeley Lab, widely known as one of the world’s preeminent laboratories for extreme-ultraviolet (EUV) research.
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“With the old tool we suffered greatly just to squeeze good results from it,” says Goldberg. “We always talked about what we’d do if we had the chance to do it right.”
Goldberg and his colleagues got that chance thanks to a partnership with SEMATECH, a consortium of semiconductor companies and chip-makers who recognized in CXRO the ideal combination of resources and expertise. The collaboration is part of a long-standing partnership between CXRO and SEMATECH that serves as a model for how industry and National Labs can combine forces to address critical challenges for the semiconductor industry.
SEMATECH’s constituent companies are interested in developing EUV fabrication techniques in order to shrink circuit elements in their computer chips down to a few nanometers in size – five to ten times smaller than they are today.
In semiconductor fabrication, circuits of silicon are made via photolithography.
“Photolithography works like darkroom photography, where an image on film is enlarged and projected onto light-sensitive paper,” says Goldberg. “But in photolithography you flip the optics backwards and shrink an image of a circuit from a mask down onto a silicon wafer coated with light sensitive film. So you want to use all the physics you can to make those circuits as small as possible.”
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| SHARP Microscope - Image Source: LBNL |
The SHARP microscope was built to examine defects in photolithography masks 10-40 nanometers wide – tiny, but big enough to interfere with circuit elements of similar size. The usual inspection tools, such as electron and atomic microscopy, can’t predict the impact of such defects on EUV wavelengths, which is necessary to make successful repairs.
One of the great advances of SHARP, compared to its predecessor, is the flexibility to emulate all current and future EUV illumination setups.
“This tool will let companies look way into the future,” says Goldberg. “Whatever they can dream as a future set up, they can test with our tool.”
SHARP is also dramatically more powerful and accurate than its predecessor. Goldberg and his team improved the optical efficiency 150 times, and took great pains to insulate the tool from mechanical vibrations. Eventually, the whole setup will go into a thermo-acoustic shell for further shielding.
“It has been so fun to be a part of this project,” says Goldberg. “It’s been one of the most creative periods in my life, and I’m so proud of what our team has accomplished. I have a huge sense of pride now to watch the tool produce great results.”
SOURCE Lawrence Berkeley National Laboratory
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