An X-ray tube has a housing enclosing a vacuum chamber. There is a primary field-emission cathode within the vacuum chamber, a secondary cathode within the vacuum chamber, spaced apart from the primary cathode, and an anode target within the vacuum chamber.

The present invention relates to a transmission type target having a diamond base material as the transmissive base material. The transmission type target includes a target layer containing a metal carbide constituted of at least one metal selected from the group consisting of molybdenum, tantalum, and tungsten and carbon; and a diamond base material supporting the target layer. The transmission type target inhibits the composition of the target layer from varying with the drive history of the transmission type target and inhibits the output of radiation from varying over a long time.

The present invention relates to a transmission type target having a diamond base material as the transmissive base material. The transmission type target includes a target layer containing a metal carbide constituted of at least one metal selected from the group consisting of molybdenum, tantalum, and tungsten and carbon; and a diamond base material supporting the target layer. The transmission type target inhibits the composition of the target layer from varying with the drive history of the transmission type target and inhibits the output of radiation from varying over a long time.

A sealed cold cathode X-ray tube for use in small X-ray source devices is provided. In one embodiment, a sealed cold cathode X-ray tube includes an elongate member, a cathode emitter, and an anode.

Systems and methods for generating X-ray photons. The methods comprise: generating an electron beam; positioning hollow pedestals in the path of the electron beam (the hollow pedestals being radially spaced apart from each other and extending out and away from a major planar face of a base plate); generating X-ray radiation as a result of an interaction of the electron beam with target element(s) disposed at a distal end of a respective pedestal of the hollow pedestals; causing the X-ray radiation to interact with a beam shield comprising wall elements extending out and away from the major planar face of the base plate; and setting at least one of a beam shape and direction of the X-ray radiation by selectively controlling a location where the electron beam intersects the target element(s) to determine an interaction of the X-ray radiation with the wall elements.

Systems and methods for generating X-ray photons. The methods comprise: generating an electron beam; positioning hollow pedestals in the path of the electron beam (the hollow pedestals being radially spaced apart from each other and extending out and away from a major planar face of a base plate); generating X-ray radiation as a result of an interaction of the electron beam with target element(s) disposed at a distal end of a respective pedestal of the hollow pedestals; causing the X-ray radiation to interact with a beam shield comprising wall elements extending out and away from the major planar face of the base plate; and setting at least one of a beam shape and direction of the X-ray radiation by selectively controlling a location where the electron beam intersects the target element(s) to determine an interaction of the X-ray radiation with the wall elements.

Systems and methods for generating X-ray photons. The methods comprise: generating an electron beam; positioning hollow pedestals in the path of the electron beam (the hollow pedestals being radially spaced apart from each other and extending out and away from a major planar face of a base plate); generating X-ray radiation as a result of an interaction of the electron beam with target element(s) disposed at a distal end of a respective pedestal of the hollow pedestals; causing the X-ray radiation to interact with a beam shield comprising wall elements extending out and away from the major planar face of the base plate; and setting at least one of a beam shape and direction of the X-ray radiation by selectively controlling a location where the electron beam intersects the target element(s) to determine an interaction of the X-ray radiation with the wall elements.

Systems and methods for generating X-ray photons. The methods comprise: generating an electron beam; positioning hollow pedestals in the path of the electron beam (the hollow pedestals being radially spaced apart from each other and extending out and away from a major planar face of a base plate); generating X-ray radiation as a result of an interaction of the electron beam with target element(s) disposed at a distal end of a respective pedestal of the hollow pedestals; causing the X-ray radiation to interact with a beam shield comprising wall elements extending out and away from the major planar face of the base plate; and setting at least one of a beam shape and direction of the X-ray radiation by selectively controlling a location where the electron beam intersects the target element(s) to determine an interaction of the X-ray radiation with the wall elements.