Implantable medical devices including a housing that contains operational circuitry for the implantable medical device and a dispensed hydrogen getter. The hydrogen getter may include a getter carrier material and one or more getter materials carried as suspensions in the getter carrier material, with the getter materials taking the form of organic compounds, such as fatty acids, or powdered metal oxides, or combinations thereof. The hydrogen getter may instead be comprised of two fatty acids having different melt temperatures. The hydrogen getter may be dispensed onto an encapsulant layer or other component of the implantable medical device, or may be blended into an encapsulant layer.

An X-ray tube includes a vacuum-sealed tube housing evacuated to a pressure of 10.sup.?7 mbar or lower, a cathode assembly inside the housing including an electron emitter adapted to emit electrons when heated at a temperature included in a defined working temperature range and at least one component containing carbon in an amount of at least 20% by weight, especially at least 30% by weight, even more especially at least 50% by weight, the at least one component being preferably designed for holding the emitter, and an anode assembly inside the housing including a target layer for receiving electrons emitted by the electron emitter, wherein the electron emitter preferably includes boride, preferably lanthanum hexaboride (LaB.sub.6), and wherein the cathode assembly is designed such that if the emitter temperature is included in the working temperature range.

An X-ray tube includes a vacuum-sealed tube housing evacuated to a pressure of 10.sup.?7 mbar or lower, a cathode assembly inside the housing including an electron emitter adapted to emit electrons when heated at a temperature included in a defined working temperature range and at least one component containing carbon in an amount of at least 20% by weight, especially at least 30% by weight, even more especially at least 50% by weight, the at least one component being preferably designed for holding the emitter, and an anode assembly inside the housing including a target layer for receiving electrons emitted by the electron emitter, wherein the electron emitter preferably includes boride, preferably lanthanum hexaboride (LaB.sub.6), and wherein the cathode assembly is designed such that if the emitter temperature is included in the working temperature range.

A semiconductor device may include the following elements: a semiconductor substrate, an insulator positioned on the substrate, a source electrode positioned on the insulator, a drain electrode positioned on the insulator, a gate electrode positioned between the source electrode and the drain electrode, a hollow channel surrounded by the gate electrode and positioned between the source electrode and the drain electrode, a dielectric member positioned between the hollow channel and the gate electrode, a first insulating member positioned between the gate electrode and the source electrode, and a second insulating member positioned between the gate electrode and the drain electrode.

A semiconductor device may include the following elements: a semiconductor substrate, an insulator positioned on the substrate, a source electrode positioned on the insulator, a drain electrode positioned on the insulator, a gate electrode positioned between the source electrode and the drain electrode, a hollow channel surrounded by the gate electrode and positioned between the source electrode and the drain electrode, a dielectric member positioned between the hollow channel and the gate electrode, a first insulating member positioned between the gate electrode and the source electrode, and a second insulating member positioned between the gate electrode and the drain electrode.

An apparatus for forming a vacuum in a sealed enclosure through an electrochemical reaction includes an electrochemical cell comprising a cathode and an anode supported on a solid electrolyte. The solid electrolyte is a Li-ion non-volatile electrolyte containing a dissolved metal salt. The cathode is constructed of a material with which lithium is known to form alloys. The anode is constructed of a lithium-ion containing material. The cell is operable to expose lithium metal on the cathode.

Provided herein are approaches for improving ion beam extraction stability and ion beam current for an ion extraction system. In one approach, a source housing assembly may include a source housing surrounding an ion source including an arc chamber, the source housing having an extraction aperture plate mounted at a proximal end thereof. The source housing assembly further includes a vacuum liner disposed within an interior of the source housing to form a barrier around a set of vacuum pumping apertures. As configured, openings in the source housing assembly, other than an opening in the extraction aperture plate, are enclosed by the extraction aperture plate and the vacuum liner, thus ensuring appendix arcs or extraneous ions produced outside the arc chamber remain within the source housing. Just those ions produced within the arc chamber exit the source housing through the opening of the extraction aperture plate.

Provided herein are approaches for improving ion beam extraction stability and ion beam current for an ion extraction system. In one approach, a source housing assembly may include a source housing surrounding an ion source including an arc chamber, the source housing having an extraction aperture plate mounted at a proximal end thereof. The source housing assembly further includes a vacuum liner disposed within an interior of the source housing to form a barrier around a set of vacuum pumping apertures. As configured, openings in the source housing assembly, other than an opening in the extraction aperture plate, are enclosed by the extraction aperture plate and the vacuum liner, thus ensuring appendix arcs or extraneous ions produced outside the arc chamber remain within the source housing. Just those ions produced within the arc chamber exit the source housing through the opening of the extraction aperture plate.

An apparatus for forming a vacuum in a sealed enclosure through an electrochemical reaction includes an electrochemical cell comprising a cathode and an anode supported on a solid electrolyte. The solid electrolyte is a Li-ion non-volatile electrolyte containing a dissolved metal salt. The cathode is constructed of a material with which lithium is known to form alloys. The anode is constructed of a lithium-ion containing material. The cell is operable to expose lithium metal on the cathode.

A semiconductor device may include the following elements: a semiconductor substrate, an insulator positioned on the substrate, a source electrode positioned on the insulator, a drain electrode positioned on the insulator, a gate electrode positioned between the source electrode and the drain electrode, a hallow channel surrounded by the gate electrode and positioned between the source electrode and the drain electrode, a dielectric member positioned between the hollow channel and the gate electrode, a first insulating member positioned between the gate electrode and the source electrode, and a second insulating member positioned between the gate electrode and the drain electrode.