Application of synchrotron radiation window in life science and physics

The synchrotron radiation silicon nitride membrane window is a special window material widely used in synchrotron radiation experiments. Primarily composed of silicon nitride thin membrane, it exhibits excellent mechanical properties and chemical stability, effectively resisting the radiation damage caused by synchrotron radiation sources.

The silicon nitride thin membrane boasts a wide range of light transmittance, achieving high transmission rates within the ultraviolet to infrared wavelength bands. This significant advantage makes it a valuable material in synchrotron radiation experiments. Furthermore, the unique structure of the silicon nitride membrane window minimizes beam scattering, enhancing the longitudinal consistency of the synchrotron radiation beam, thus further increasing its utility in experimental settings.

In life science research, the synchrotron radiation silicon nitride membrane window plays a pivotal role. It can be used for structural studies of biological molecules and assists in drug screening, accelerating the process of new drug development. Additionally, utilizing the scanning transmission soft X-ray microscopy (STXM) technique from synchrotron radiation sources, it enables sub-micron spatial and chemical analysis of biological samples in their natural state.

In physical science research, the synchrotron radiation silicon nitride membrane window also finds extensive applications. It can be employed to explore new physical phenomena and develop novel physical theories, thereby advancing scientific progress. Moreover, it serves as a vacuum window, separating the high-vacuum soft X-ray section from atmospheric pressure, making it suitable for the study of living cells. Additionally, it functions as a contamination barrier in synchrotron radiation beamlines, protecting experimental equipment from contamination.

Overall, the synchrotron radiation silicon nitride membrane window holds vast potential for widespread application in synchrotron radiation experiments. With the continuous advancement of science and technology, its performance and application fields are expected to expand further, providing robust support for scientific research and technological progress.