A method for making field emitter is provided. A carbon nanotube array and a cathode substrate are provided. A pressure is applied on the carbon nanotube array to make the carbon nanotubes of the carbon nanotube array toppled over and form a carbon nanotube paper. An adhesive tape is placed on the carbon nanotube paper, and then the adhesive tape is peeled off to make the carbon nanotube paper bonded to the adhesive tape. The cathode substrate is placed on the carbon nanotube paper; and then the cathode substrate is peeled off, at least part of the plurality of carbon nanotubes are bonded to the cathode substrate and perpendicular to the cathode substrate.

A method for making field emitter is provided. A carbon nanotube array and a cathode substrate are provided. A pressure is applied on the carbon nanotube array to make the carbon nanotubes of the carbon nanotube array toppled over and form a carbon nanotube paper. An adhesive tape is placed on the carbon nanotube paper, and then the adhesive tape is peeled off to make the carbon nanotube paper bonded to the adhesive tape. The cathode substrate is placed on the carbon nanotube paper; and then the cathode substrate is peeled off, at least part of the plurality of carbon nanotubes are bonded to the cathode substrate and perpendicular to the cathode substrate.

Disclosed embodiments include vacuum electronic devices and methods of fabricating a vacuum electronic device. In a non-limiting embodiment, a vacuum electronic device includes an electrode that defines discrete support structures therein. A first film layer is disposed on the electrode about a periphery of the electrode and on the support structures. A second film layer is disposed on the first film layer. The second film layer includes electrically conductive grid lines patterned therein that are supported by and suspended between the support structures.

Disclosed embodiments include vacuum electronic devices and methods of fabricating a vacuum electronic device. In a non-limiting embodiment, a vacuum electronic device includes an electrode that defines discrete support structures therein. A first film layer is disposed on the electrode about a periphery of the electrode and on the support structures. A second film layer is disposed on the first film layer. The second film layer includes electrically conductive grid lines patterned therein that are supported by and suspended between the support structures.

A tunneling electro source, an array thereof and methods for making the same are provided. The tunneling electron source is a surface tunneling micro electron source having a planar multi-region structure. The tunneling electron source includes an insulating substrate, and two conductive regions and one insulating region arranged on a surface of the insulating substrate. The insulating region is arranged between the two conductive regions and abuts on the two conductive regions. Minimum spacing between the two conductive regions, which equals to a minimum width of the insulating region, is less than 100 nm.

A tunneling electro source, an array thereof and methods for making the same are provided. The tunneling electron source is a surface tunneling micro electron source having a planar multi-region structure. The tunneling electron source includes an insulating substrate, and two conductive regions and one insulating region arranged on a surface of the insulating substrate. The insulating region is arranged between the two conductive regions and abuts on the two conductive regions. Minimum spacing between the two conductive regions, which equals to a minimum width of the insulating region, is less than 100 nm.

Disclosed herein is a method comprising: emitting electrons from an electron ejector in response to an incident photon; driving the electrons through a hole toward a detector configured to collect the electrons and provide an output signal representative of the incident photon; driving the electrons away from sidewalls of the hole, using an electric field.

Disclosed herein is a method comprising: emitting electrons from an electron ejector in response to an incident photon; driving the electrons through a hole toward a detector configured to collect the electrons and provide an output signal representative of the incident photon; driving the electrons away from sidewalls of the hole, using an electric field.

Technology is described for steep angle of a focal track of an anode of an x-ray tube. In one example, an anode includes a disc-shaped anode and a focal track. The disc-shaped anode includes a bearing-facing surface, a window-facing surface positioned opposite the bearing-facing surface, and a focal track positioned between the window-facing surface and the bearing-facing surface, wherein the focal track is angled with respect to the window-facing surface, and the angle between the focal track and the window-facing surface is between 45 and 89.

Technology is described for steep angle of a focal track of an anode of an x-ray tube. In one example, an anode includes a disc-shaped anode and a focal track. The disc-shaped anode includes a bearing-facing surface, a window-facing surface positioned opposite the bearing-facing surface, and a focal track positioned between the window-facing surface and the bearing-facing surface, wherein the focal track is angled with respect to the window-facing surface, and the angle between the focal track and the window-facing surface is between 45 and 89.