snom 成像技术应用于研究微纳尺度上光与原子、分子、二维材料、生物大分子、非线性结构等物质相互作用的时空细 节，并阐述了所揭示的微纳尺度上光和物质相互作用的深层次物理、化学和生物学一系列新现象和新规律。

Snom equips its various products with common, modern technologies to produce maximum compatible devices. The guide is intended to provide information on which Snom devices can be used in everyday situations and what to look for to get the best communication solution. Snom offers suitable and complementary services for the devices and solutions.

众多科学研究成果验证了“散射式近场光学显微技术”对科研工作的推动作用，NeaSNOM作为市场上一款散射型扫描近场光学显微镜，其化的散射式核心设计技术，地提高了光学分辨率，并且不依赖于入射激光的波长，能够在可见、红外和太赫兹光谱范围内，提供优于10nm空间分辨率的光谱和近场光学图像，成为纳米光学领域热点研究方向的优选科研设备，为光学物理、材料应用等方向的应用发展贡献力量。

扫描近场光学显微镜(scanning near-field optical microscopy, SNOM)，能在纳米尺度上探测样品的光学信息，打破了长久以来经典(或远场)光学显微镜理论分辨率的 阿贝衍射极限 ，将光学分辨率提高了几十甚至上百倍。且纵向分辨率优于横向分辨率，能够得到清晰的三维 ...

扫描近场显微术 (snom) 是一类对纳米尺度下光与物质的相互作用进行测量的扫描探针显微镜技术，可用于研究样品的局域光学特性。 通过运用光学近场效应，它的分辨率突破了传统远场测量中的衍射极限。

At visible wavelengths this principle (optical stethoscopy, near-field optical-scanning microscopy, SNOM) was demonstrated by Pohl et al [3, 4]. In [ 5 ] Betzig et al they have demonstrated using fiber probes to image a variety of samples with a number of different contrast mechanisms.

Snom Technology GmbH / s n ʊ m / is a German company which manufactures Voice over Internet Protocol (VoIP) telephones, based on the IETF standard Session Initiation Protocol (SIP). Snom's products are targeted at the small- to medium-sized business sector, home offices, Internet service providers, carriers, and original equipment manufacturers.

Scanning near-field microscopy (SNOM) is a type of scanning probe microscopy technique that measures light-matter interactions at the nanoscale to investigate local optical properties of a sample. It relies on optical near-field effects to push its resolution below the diffraction limit as obtained in conventional far-field measurements.

2023年8月28日 · Scientists at Stony Brook University, Columbia University, and the University of California San Diego have developed a new tool to image quantum particles called Dirac magnetoexcitons (DiMEs) at infrared frequencies for the first time.

Higher resolution Bohm is achieved by detecting scattering of light from the object under study at distances smaller than the wavelength of light. In the case that the probe (detector) of the near-field microscope provided with a device for the spatial scan, the scanning device called optical near-field microscope.