A stage apparatus for a particle-beam apparatus is disclosed. A particle beam apparatus may comprise a conductive object and an object table, the object table being configured to support an object. The object table comprises a table body and a conductive coating, the conductive coating being provided on at least a portion of a surface of the table body. The conductive object is disposed proximate to the conductive coating and the table body is provided with a feature proximate to an edge portion of the conductive coating. Said feature is arranged so as to reduce an electric field strength in the vicinity of the edge portion of the conductive coating when a voltage is applied to both the conductive object and the conductive coating.

A charged particle beam device for imaging and/or inspecting a sample is described. The charged particle beam device includes a beam emitter for emitting a primary charged particle beam; a retarding field device for retarding the primary beam before impinging on the sample, the retarding field device including an objective lens and a proxy electrode; and a first detector for off-axial backscattered particles between the proxy electrode and the objective lens. The charged particle beam device is adapted for guiding the primary beam along an optical axis to the sample for releasing signal particles. The proxy electrode includes one opening allowing a passage of the primary charged particle beam and of the signal particles, wherein the one opening is sized to allow a passage of charged particles backscattered from the sample at angles from 0° to 20° or above relative to the optical axis. Further, a method for imaging and/or inspecting a sample with a charged particle beam device is described.

A charged particle beam device for imaging and/or inspecting a sample is described. The charged particle beam device includes a beam emitter for emitting a primary charged particle beam, the charged particle beam device adapted for guiding the primary charged particle beam along an optical axis to the sample for releasing signal particles; a retarding field device for retarding the primary charged particle beam before impinging on the sample, the retarding field device including an objective lens and a proxy electrode, wherein the proxy electrode includes an opening allowing a passage of the primary charged particle beam and of the signal particles; a first detector for off-axial backscattered particles between the proxy electrode and the objective lens; and a pre-amplifier for amplifying a signal of the first detector, wherein the pre-amplifier is at least one of (i) integrated with the first detector, (ii) arranged adjacent to the first detector inside a vacuum housing of the charged particle beam device, and (iii) fixedly mounted in a vacuum chamber of the charged particle beam device. Further, a method for imaging and/or inspecting a sample with a charged particle beam device is described.

A multi-cell detector may include a first layer having a region of a first conductivity type and a second layer including a plurality of regions of a second conductivity type. The second layer may also include one or more regions of the first conductivity type. The plurality of regions of the second conductivity type may be partitioned from one another by the one or more regions of the first conductivity type of the second layer. The plurality of regions of the second conductivity type may be spaced apart from one or more regions of the first conductivity type in the second layer. The detector may further include an intrinsic layer between the first and second layers.

A multi-cell detector may include a first layer having a region of a first conductivity type and a second layer including a plurality of regions of a second conductivity type. The second layer may also include one or more regions of the first conductivity type. The plurality of regions of the second conductivity type may be partitioned from one another, preferably by the one or more regions of the first conductivity type of the second layer. The plurality of regions of the second conductivity type may be spaced apart from one or more regions of the first conductivity type in the second layer. The detector may further include an intrinsic layer between the first and second layers.

The invention provides a power supply device and a charged particle beam device capable of reducing noise generated between a plurality of voltages. The charged particle beam device includes a charged particle gun configured to emit a charged particle beam, a stage on which a sample is to be placed, and a power supply circuit configured to generate a first voltage and a second voltage that determine energy of the charged particle beam and supply the first voltage to the charged particle gun. The power supply circuit includes a first booster circuit configured to generate the first voltage, a second booster circuit configured to generate the second voltage, and a switching control circuit configured to perform switching control of the first booster circuit and the second booster circuit using common switch signals.

A multi-cell detector may include a first layer having a region of a first conductivity type and a second layer including a plurality of regions of a second conductivity type. The second layer may also include one or more regions of the first conductivity type. The plurality of regions of the second conductivity type may be partitioned from one another, preferably by the one or more regions of the first conductivity type of the second layer. The plurality of regions of the second conductivity type may be spaced apart from one or more regions of the first conductivity type in the second layer. The detector may further include an intrinsic layer between the first and second layers.

The invention relates to a method of manufacturing a charged particle detector, comprising the steps of providing a sensor device, such as an Active Pixel Sensor (APS). Said sensor device at least comprises a substrate layer and a sensitive layer. The method further comprises the step of providing a mechanical supporting layer and connecting said mechanical supporting layer to said sensor device. After connection, the sensitive layer is situated in between said substrate layer and said mechanical supporting layer. By connecting the mechanical supporting layer, it is possible to thin said substrate layer for forming said charged particle detector. The mechanical supporting layer forms part of the manufactured detector. The detector can be used in a charged particle microscope, such as a Transmission Electron Microscope for direct electron detection.

An electron beam inspection apparatus includes a plurality of electrodes to surround an inspection substrate placed on a stage, a camera to measure, for each of the plurality of electrodes, a gap between a peripheral edge of the inspection substrate and an electrode of the plurality of electrodes, a retarding potential application circuit to apply a retarding potential to the inspection substrate, an electrode potential application circuit to apply, to each electrode, a corresponding potential of potentials each obtained by adding an offset potential, which is variable according to a measured gap, to the retarding potential to be applied to the inspection substrate, and an electron optical system to irradiate the inspection substrate with electron beams, in the state where the retarding potential has been applied to the inspection substrate and the corresponding potential of the potentials has been individually applied to each of the plurality of electrodes.

The invention provides a power supply device and a charged particle beam device capable of reducing noise generated between a plurality of voltages. The charged particle beam device includes a charged particle gun configured to emit a charged particle beam, a stage on which a sample is to be placed, and a power supply circuit configured to generate a first voltage and a second voltage that determine energy of the charged particle beam and supply the first voltage to the charged particle gun. The power supply circuit includes a first booster circuit configured to generate the first voltage, a second booster circuit configured to generate the second voltage, and a switching control circuit configured to perform switching control of the first booster circuit and the second booster circuit using common switch signals.