The invention relates to a liquid metal-ion beam system (1) or liquid metal electron beam system, including: a conductive emitter electrode (2), a conductive extractor electrode (3) opposite to the emitter electrode (2), a liquid metal reservoir (4) which is fluidically connected to the emitter electrode (2) for transporting liquid metal to the emitter electrode (2), a control unit (5) which is configured to apply a periodically varying operating voltage between emitter electrode (2) and extractor electrode (3).

The invention relates to a particle beam device (100) for imaging, analyzing and/or processing an object (114). The particle beam device (100) comprises a first particle beam generator (300) for generating a first particle beam, wherein the first particle beam generator (300) has a first generator beam axis (301), wherein an optical axis (OA) of the particle beam device (100) and the first generator beam axis (301) are identical; a second particle beam generator (400) for generating a second particle beam, wherein the second particle beam generator (400) has a second generator beam axis (401), wherein the optical axis (OA) and the second generator beam axis (401) are arranged at an angle being different from 0° and 180°; a deflection unit (500) for deflecting the second particle beam from the second generator beam axis (401) to the optical axis (OA) and along the optical axis (OA), wherein the deflection unit (500) has a first opening (501) and a second opening (502) being different from the first opening (501), wherein the optical axis (OA) runs through the first opening (501), wherein the second generator beam axis (401) runs through the second opening (502); an objective lens (107) for focusing the first particle beam or the second particle beam onto the object (114), wherein the optical axis (OA) runs through the objective lens (107); and at least one detector (116, 121, 122) for detecting interaction particles and/or interaction radiation.

The invention relates to a liquid metal-ion beam system (1) or liquid metal electron beam system, comprising: a conductive emitter electrode (2), a conductive extractor electrode (3) opposite to the emitter electrode (2), a liquid metal reservoir (4) which is fluidically connected to the emitter electrode (2) for transporting liquid metal to the emitter electrode (2), a control unit (5) which is configured to apply a periodically varying operating voltage between emitter electrode (2) and extractor electrode (3).

An ion source is configured to form an ion beam and has an arc chamber enclosing an arc chamber environment. A reservoir apparatus can be configured as a repeller and provides a liquid metal to the arc chamber environment. A biasing power supply electrically biases the reservoir apparatus with respect to the arc chamber to vaporize the liquid metal to form a plasma in the arc chamber environment. The reservoir apparatus has a cup and cap defining a reservoir environment for the liquid metal that is fluidly coupled to the arc chamber environment by holes in the cap. Features extend from the cup into the reservoir and contact the liquid metal to feed the liquid metal toward the arc chamber environment by capillary action. A structure, surface area, roughness, and material modifies the capillary action. The feature can be an annular ring, rod, or tube extending into the liquid metal.

A liquid metal ion source (50) includes: a reservoir (10) configured to hold an ion material (M) forming a liquid metal; a needle electrode (20); an extraction electrode (22) configured to cause an ion of the ion material to be emitted from a distal end of the needle electrode; a beam diaphragm (24), which is arranged on a downstream side of the extraction electrode, and is configured to limit a beam diameter of the ion; and a vacuum chamber (30) configured to accommodate and hold the reservoir, the needle electrode, the extraction electrode, and the beam diaphragm in vacuum, wherein the liquid metal ion source further includes an oxidizing gas introducing portion (40), and wherein the oxidizing gas introducing portion communicates to the vacuum chamber, and is configured to introduce an oxidizing gas into a periphery of the needle electrode.

A particle beam generator for a particle beam device may be operated. A liquid metal may be provided from a container of a particle source to an emission device of the particle source and a first heating cycle for cleaning the particle source performed, which may comprise supplying a heating current to a heating device arranged at the emission device using a current supply unit, heating the emission device during a heating time period, measuring a value of a voltage drop at the heating device and/or at the current supply unit and adjusting at least one of: the heating current and the heating time period using the current supply unit, depending on the measured value of the voltage drop. A second heating cycle for cleaning the particle source may include using at least one of: the adjusted heating current and the adjusted heating time period, for heating the emission device.

A liquid metal ion source (50) includes: a reservoir (10) configured to hold an ion material (M) forming a liquid metal; a needle electrode (20); an extraction electrode (22) configured to cause an ion of the ion material to be emitted from a distal end of the needle electrode; a beam diaphragm (24), which is arranged on a downstream side of the extraction electrode, and is configured to limit a beam diameter of the ion; and a vacuum chamber (30) configured to accommodate and hold the reservoir, the needle electrode, the extraction electrode, and the beam diaphragm in vacuum, wherein the liquid metal ion source further includes an oxidizing gas introducing portion (40), and wherein the oxidizing gas introducing portion communicates to the vacuum chamber, and is configured to introduce an oxidizing gas into a periphery of the needle electrode.

A charged particle beam system includes a charged particle source, an extraction electrode, a suppressor electrode, a first variable voltage supply for biasing the extraction electrode with an extraction voltage and a second variable voltage supply for biasing the suppressor electrode with a suppressor voltage.

An ion source is configured to form an ion beam and has an arc chamber enclosing an arc chamber environment. A reservoir apparatus can be configured as a repeller and provides a liquid metal to the arc chamber environment. A biasing power supply electrically biases the reservoir apparatus with respect to the arc chamber to vaporize the liquid metal to form a plasma in the arc chamber environment. The reservoir apparatus has a cup and cap defining a reservoir environment for the liquid metal that is fluidly coupled to the arc chamber environment by holes in the cap. Features extend from the cup into the reservoir and contact the liquid metal to feed the liquid metal toward the arc chamber environment by capillary action. A structure, surface area, roughness, and material modifies the capillary action. The feature can be an annular ring, rod, or tube extending into the liquid metal.

A method for operating a particle beam generator for a particle beam device, and a particle beam device for carrying out this method, are provided. An extractor voltage may be set to an extractor value using a first variable voltage supply unit. An emission current of the particle beam generator may be measured. When the emission current of the particle beam generator decreases, a suppressor voltage applied to a suppressor electrode may be adjusted using a second variable voltage supply unit such that a specific emission current of the particle beam generator is reached or maintained. When the emission current of the particle beam generator increases, the extractor voltage applied to the extractor electrode may be adjusted using the first variable voltage supply unit such that the specific emission current of the particle beam generator is reached or maintained.