The present invention provides a packaging unit for liquid sample loading devices applied in an electron microscope. The liquid sample loading devices may be easily, rapidly, precisely and stably aligned and packaged by an engagement of an upper jig and a bottom jig as well as a first fixing pillar supported in a slide track of the packaging unit. Accordingly, efficiency and a yield of packaging the liquid sample loading devices may be improved. In addition, the packaging unit for the liquid sample loading devices of the present invention may directly package a liquid sample, and thus the liquid sample may maintain its original state.

A thin film liquid cell suitable for transmission electron microscopy at room temperature is fabricated as follows. A thin film floating on a liquid is prepared. A droplet of the liquid with the thin film floating thereon is transferred to a support by means of a loop. The loop carries the droplet and the droplet carries the thin film during this transfer. Sufficient liquid from the droplet on the support is removed to form the thin film liquid cell.

The observation device comprises: a scanning electron microscope for detecting secondary electrons generated by irradiating the sample with an electron beam within the analysis chamber; a sample holder having a cell for housing the observation target gas, an open window of the cell, and a sample mounting part to which the sample can be mounted so as to block the open window; and an observation target ion detecting unit for irradiating the front surface of the sample with an electron beam in a state where the observation target gas in the cell contacts the back surface of the sample and detecting observation target ions derived from the observation target gas generated by the electron beam. In a state where the observation target gas is housed in the cell and the sample is mounted to the sample mounting part of the sample holder, the entire hydrogen cell can be sealed.

A 3D nanoprinter electron beam lithography module for a lithography system, such as a scanning electron microscope (SEM) or an environmental SEM (ESEM) with a beam blanker and electron beam lithography attachment, but generally applicable to any electron beam lithography capable system. The module is comprised of an in-situ spin-coating stage that is compatible with a cooling-SEM stage, with a spin-coating motor, a spin-coating sample stub, a liquid waste collector cup, a liquid dispensing arm holding a tube bundle that is connected via tubing to micro-syringe pumps or a pressure driven flow controller or pumps connected to fluid reservoirs, an electron beam scan generator control box, electrical feedthroughs, control electronics, and a computing system responsible for controlling the entire module. The dispensing arm can be controlled by a servo motor.

The present disclosure discloses a transmission electron microscope in-situ chip and a preparation method thereof. The transmission electron microscope in-situ chip includes a transmission electron microscope high-resolution in-situ gas phase heating chip, a transmission electron microscope high-resolution in-situ liquid phase heating chip and a transmission electron microscope in-situ electrothermal coupling chip. The transmission electron microscope high-resolution in-situ gas phase heating chip and the transmission electron microscope high-resolution in-situ liquid phase heating chip are respectively suitable for gas samples and liquid samples, and the transmission electron microscope in-situ electrothermal coupling chip realizes the multi-functional embodiment of electrothermal coupling. The three transmission electron microscope in-situ chips have the advantages of high resolution and low sample drift rate.

The present disclosure discloses a transmission electron microscope in-situ chip and a preparation method thereof. The transmission electron microscope in-situ chip includes a transmission electron microscope high-resolution in-situ gas phase heating chip, a transmission electron microscope high-resolution in-situ liquid phase heating chip and a transmission electron microscope in-situ electrothermal coupling chip. The transmission electron microscope high-resolution in-situ gas phase heating chip and the transmission electron microscope high-resolution in-situ liquid phase heating chip are respectively suitable for gas samples and liquid samples, and the transmission electron microscope in-situ electrothermal coupling chip realizes the multi-functional embodiment of electrothermal coupling. The three transmission electron microscope in-situ chips have the advantages of high resolution and low sample drift rate.

Systems and methods for preparing a nanofluidic LCTEM cell are provided. An exemplary method includes coating a photoresist layer onto a top surface of a silicon nitride substrate; etching channels into the photoresist layer; depositing calcite into the etched channels; removing the photoresist; placing the cell on a holder; connecting a first end of an inlet line to the cell; connecting a second end of the inlet line to an ultrasound transducer configured to generate nanobubbles; and connecting an outlet line to the cell.

A cold trap is provided to reduce contamination gases that react with the beam during operations that use a process gas. The cold trap is set to a temperature that condenses the contamination gas but does not condense the process gas. Cold traps may be used in the sample chamber and in the gas line.

A sample collection device includes two substrates and a spacer. The two substrates are disposed oppositely. Each substrate has a first surface, a second surface opposing to the first surface, a first recess and at least one second recess. The two substrates are arranged with the first surfaces facing each other, and the first and second recesses are respectively located on each first surface. The first recesses of the substrates jointly form a first channel, and the second recesses of the substrates jointly form a second channel connected to the outside of the sample collection device. The first channel and the second channel are interconnected. The spacer is disposed between the two first surfaces for bonding and fixing the two substrates. A sample containing space is formed between the two substrates and the spacer. The sample containing space includes the first chancel and the second channel. In addition, a manufacturing method of the sample collection device is also provided.

A grid assembly for cryo-electron microscopy may be fabricated using standard nanofabrication processes. The grid assembly may comprise two support members, each support member comprising a silicon substrate coated with an electron-transparent silicon nitride layer. These two support members are positioned together with the silicon nitride layers facing each other with a rigid spacer layer disposed therebetween. The rigid spacer layer defines one or more chambers in which a biological sample may be provided and fast frozen with a high degree of control of the ice thickness.