A new spot focusing technology was born, and the imaging resolution of new materials for electronic products exceeded 6 nm!

The development of new materials for next-generation electronic products is changing rapidly, but their application is still limited by many bottlenecks, and imaging and observation are a major difficulty.
Fortunately, researchers at the University of California Riverside have successfully developed a probe that can compress light into nano-sized spots for imaging the microstructure and details of new materials in electronic products.
They said that this “revolutionary imaging technology” has improved the resolution of color imaging to an unprecedented level of 6 nm, which can help scientists see the clear details of nanomaterials, allowing these nanomaterials to further expand their skills in electronic and other applications.
According to reports, under an optical microscope, carbon nanotubes appear gray. Traditional scopes cannot distinguish between subtle details and the differences between individual nanomaterials, making it difficult for scientists to study their unique properties and find ways to improve their industrial use.
The technology developed by UCR has been used in previous work to observe the vibration of molecular bonds at a spatial resolution of 1 nm without requiring any focusing lens.
In the latest development, UCR scientists have also improved tools to measure signals across the entire visible wavelength range, which can be used to render colors and describe the electronic band structure of objects, not just molecular vibrations.
Based on the latest technological advances, originally gray carbon nanotubes were created during the imaging process, producing the first color photo.https://www.stoneitech.com/
Researchers hope that this new technology can become an important tool to help the semiconductor industry manufacture uniform nanomaterials with consistent performance for electronic devices. New full color nano imaging technologies can also be used to improve understanding of catalysis, quantum optics, and nano electronics.