Abstract: Systems and methods for transferring a sample from a transmission electron microscope (TEM) column are described herein. In one aspect, a method can include transferring a sample positioned in a holder capsule of a TEM sample holder from a vacuum chamber of a TEM into a load lock of the TEM; filling the load lock with a protecting gas; sealing the holder capsule of the TEM sample holder under the protecting gas; and removing the TEM sample holder from the load lock.

Abstract: The invention relates to a device and method for determining a property of a sample that is to be used in a charged particle microscope. The sample comprises a specimen embedded within a matrix layer. The device comprises a light source arranged for directing a beam of light towards said sample, and a detector arranged for detecting light emitted from said sample in response to said beam of light being incident on said sample. Finally, the device comprises a controller that is connected to said detector and arranged for determining a property of said matrix layer based on signals received by said detector.

Abstract: Cryo compatible sample grids having multi-modal cryo-EM compatible GUIDs, according to the present disclosure include an outer support structure that defines a region of the grid for holding one or more samples, and a plurality of inner support structures that define a plurality of apertures that are each configured to hold a sample. Cryo compatible sample grids further include a first identifier located on the outer support structure, and a second identifier located within the region of the grid for holding the one or more samples. The first identifier is readable with an optical detector, while the second identifier is readable with an electron detector (e.g., within an electron microscope). Specifically, the second identifier is readable with an electron detector when one or more teeth and/or holes that comprise the second identifier are filled with ice from a vitrification process.

Abstract: The invention relates to a device and method for determining a property of a sample that is to be used in a charged particle microscope. The sample comprises a specimen embedded within a matrix layer. The device comprises a light source arranged for directing a beam of light towards said sample, and a detector arranged for detecting light emitted from said sample in response to said beam of light being incident on said sample. Finally, the device comprises a controller that is connected to said detector and arranged for determining a property of said matrix layer based on signals received by said detector.

Abstract: Cryo compatible sample grids having multi-modal cryo-EM compatible GUIDs, according to the present disclosure include an outer support structure that defines a region of the grid for holding one or more samples, and a plurality of inner support structures that define a plurality of apertures that are each configured to hold a sample. Cryo compatible sample grids further include a first identifier located on the outer support structure, and a second identifier located within the region of the grid for holding the one or more samples. The first identifier is readable with an optical detector, while the second identifier is readable with an electron detector (e.g., within an electron microscope). Specifically, the second identifier is readable with an electron detector when one or more teeth and/or holes that comprise the second identifier are filled with ice from a vitrification process.