High-resolution imaging of bone microstructure has undergone a rapid evolution, driven by advances in multi-scale modalities that bridge the nano- to millimetre domains. Electron-based approaches such ...

In modern Earth science research, how to “understand” the Earth’s internal structure and dynamic processes has always been a core issue of concern for scientists. However, due to the inaccessibility ...

Optical microscopes are indispensable research tools in fields such as life sciences, medical science, and materials science. The objective lens is the core component of the microscope, determining ...

Ultraviolet (UV) imaging provides a direct probe of the young, massive stellar populations that drive the evolution of galaxies across cosmic time. Far-ultraviolet (FUV) and near-ultraviolet (NUV) ...

A research team from the School of Engineering at The Hong Kong University of Science and Technology (HKUST) has achieved a breakthrough in brain imaging by developing the world's first technology to ...

Metalenses represent a revolutionary advancement in optical technology. Unlike conventional microscope objectives that rely on curved glass surfaces, metalenses employ nanoscale structures to ...

Researchers have developed a new two-photon fluorescence microscope that captures high-speed images of neural activity at cellular resolution. By imaging much faster and with less harm to brain tissue ...

To address lithium battery safety inspection requirements, the research group of Professor Qizhen Sun and Postdoctoral Researcher Hao Li from the School of Optical and Electronic Information at ...

In this interview, industry expert Dr. Yifan Jian discusses advancements in ultrawide-field optical coherence tomography (OCT), challenges in retinal imaging, AI’s role in biophotonics, and the future ...

Juan Tomas Hernani, CEO of Satlantis Group (left) and Daniel Waller, vice president and general manager of Teledyne Space Imaging mark a partnership between the two companies at Space Tech Expo Europe ...

A new two-photon fluorescence microscope developed at UC Davis can capture high-speed images of neural activity at cellular resolution thanks to a new adaptive sampling scheme and line illumination.