The disclosure includes an outer electrode and an inner electrode. The outer electrode defines an inner volume and is configured to receive injected electrons through at least one aperture. The inner electrode positioned in the inner volume. The outer electrode and inner electrode are configured to confine the received electrons in orbits around the inner electrode in response to an electric potential between the outer electrode and the inner electrode. The apparatus does not include a component configured to generate an electron-confining magnetic field.

In a vacuum apparatus including an ultrahigh vacuum evacuation pump, the ultrahigh vacuum evacuation pump is provided with a rod-shaped cathode including a non-evaporable getter alloy, a cylindrical anode disposed so as to surround the cathode, and a coil or a ring-shaped permanent magnet disposed so as to sandwich upper and lower openings of the cylindrical anode and surround the rod-shaped cathode. As a result, it is possible to reduce the size and weight of the ultrahigh vacuum evacuation pump and to dispose the vacuum evacuation pump at a desired location in the vacuum apparatus.

In a vacuum apparatus including an ultrahigh vacuum evacuation pump, the ultrahigh vacuum evacuation pump is provided with a rod-shaped cathode including a non-evaporable getter alloy, a cylindrical anode disposed so as to surround the cathode, and a coil or a ring-shaped permanent magnet disposed so as to sandwich upper and lower openings of the cylindrical anode and surround the rod-shaped cathode. As a result, it is possible to reduce the size and weight of the ultrahigh vacuum evacuation pump and to dispose the vacuum evacuation pump at a desired location in the vacuum apparatus.

A vacuum pump includes a liquid getter that is sprayed into a pump chamber. The sprayed liquid getter can chemically bind with gaseous substance in the pump chamber to create ultra-low pressure in the pump chamber and an attached vacuum chamber. The liquefied getter can be circulated and recycled in the vacuum pump.

A vacuum pump includes a liquid getter that is sprayed into a pump chamber. The sprayed liquid getter can chemically bind with gaseous substance in the pump chamber to create ultra-low pressure in the pump chamber and an attached vacuum chamber. The liquefied getter can be circulated and recycled in the vacuum pump.

A hydrogen supply system includes: an electrochemical hydrogen pump which includes: an electrolyte membrane; a pair of anode and cathode provided on both surfaces of the electrolyte membrane; and a current adjuster which adjusts a current flowing between the anode and the cathode and which generates hydrogen boosted at a cathode side from an anode fluid supplied to an anode side when the current is allowed to flow between the anode and the cathode by the current adjuster; and a controller which controls the current adjuster to decrease the current flowing between the anode and the cathode when the pressure of a cathode gas containing the boosted hydrogen is increased.

A hydrogen supply system includes: an electrochemical hydrogen pump which includes: an electrolyte membrane; a pair of anode and cathode provided on both surfaces of the electrolyte membrane; and a current adjuster which adjusts a current flowing between the anode and the cathode and which generates hydrogen boosted at a cathode side from an anode fluid supplied to an anode side when the current is allowed to flow between the anode and the cathode by the current adjuster; and a controller which controls the current adjuster to decrease the current flowing between the anode and the cathode when the pressure of a cathode gas containing the boosted hydrogen is increased.

In a vacuum apparatus including an ultrahigh vacuum evacuation pump, the ultrahigh vacuum evacuation pump is provided with a rod-shaped cathode including a non-evaporable getter alloy, a cylindrical anode disposed so as to surround the cathode, and a coil or a ring-shaped permanent magnet disposed so as to sandwich upper and lower openings of the cylindrical anode and surround the rod-shaped cathode. As a result, it is possible to reduce the size and weight of the ultrahigh vacuum evacuation pump and to dispose the vacuum evacuation pump at a desired location in the vacuum apparatus.

In a vacuum apparatus including an ultrahigh vacuum evacuation pump, the ultrahigh vacuum evacuation pump is provided with a rod-shaped cathode including a non-evaporable getter alloy, a cylindrical anode disposed so as to surround the cathode, and a coil or a ring-shaped permanent magnet disposed so as to sandwich upper and lower openings of the cylindrical anode and surround the rod-shaped cathode. As a result, it is possible to reduce the size and weight of the ultrahigh vacuum evacuation pump and to dispose the vacuum evacuation pump at a desired location in the vacuum apparatus.

A cold-atom cell is formed by machining a block of silicon to define sites for an atom source chamber, an atom manipulation chamber, and an ion-pump chamber. A polished silicon panel is frit-bonded to an unpolished (due to machining) chamber wall (which would be difficult and costly to polish). The polished panel can then serve as a reflector or a sight for anodic bonding. A solid-phase atom source provides for vapor phase atoms in the source chamber. The source chamber also includes carbon and gold to regulate the atom pressure by sorbing and desorbing thermal atoms. The atom manipulation chamber includes components for magneto-optical trap and an atom chip, e.g., for forming a Bose-Einstein condensate. The ion-pump chamber serves as the site for an ion pump. By integrating the ion pump into the body of the cold-atom cell, a more compact, reliable, and robust cold-atom cell is achieved. In addition to the embodiment just described, several variations and alternatives are presented and within the scope of the claims.