Abstract: The invention relates to a valve device for controlled passage of a medium, in particular in the high-pressure range, which is provided with: a housing (15) having a bore (11) and at least one inlet opening (12) and an outlet opening (13); a pressure chamber (14) which is formed in the bore (11) and can be acted upon by the medium; and a valve needle (16) which is movable to and fro therein and has a conical tip (16?). A guide means (20) for the valve needle (16), by means of which the valve needle (16) with its circumferential region (16?) is guided directly at the conical tip (16?) almost without play and concentrically with respect to the valve seat (17) until it is almost in the closed position, is located in a valve seat (17) in a valve seat block (18). This guide means (20) has passage openings (24) for the passage of the medium from the pressure chamber (14) into the outlet opening (13).

Abstract: A plasma cell for use in a laser-sustained plasma light source includes a plasma bulb configured to contain a gas suitable for generating a plasma. The plasma bulb is transparent to light from a pump laser, wherein the plasma bulb is transparent to at least a portion of a collectable spectral region of illumination emitted by the plasma. The plasma bulb of the plasma cell is configured to filter short wavelength radiation, such as VUV radiation, emitted by the plasma sustained within the bulb in order to keep the short wavelength radiation from impinging on the interior surface of the bulb.

Abstract: A plasma cell for use in a laser-sustained plasma light source includes a plasma bulb configured to contain a gas suitable for generating a plasma. The plasma bulb is transparent to light from a pump laser, wherein the plasma bulb is transparent to at least a portion of a collectable spectral region of illumination emitted by the plasma. The plasma bulb of the plasma cell is configured to filter short wavelength radiation, such as VUV radiation, emitted by the plasma sustained within the bulb in order to keep the short wavelength radiation from impinging on the interior surface of the bulb.

Abstract: An illumination source for igniting and sustaining a plasma in a plasma lamp of a laser-sustained plasma (LSP) broadband source includes one or more ignition lasers configured to ignite the plasma within a gas contained within the plasma lamp. The illumination sources also include one or more sustaining lasers configured to sustain the plasma. The illumination sources include a delivery optical fiber, one or more optical elements configured to selectively optically couple an output of the one or more ignition lasers, and an output of the one or more sustaining lasers to the delivery optical fiber.

Abstract: A plasma cell for use in a laser-sustained plasma light source includes a plasma bulb configured to contain a gas suitable for generating a plasma. The plasma bulb is transparent to light from a pump laser, wherein the plasma bulb is transparent to at least a portion of a collectable spectral region of illumination emitted by the plasma. The plasma bulb of the plasma cell is configured to filter short wavelength radiation, such as VUV radiation, emitted by the plasma sustained within the bulb in order to keep the short wavelength radiation from impinging on the interior surface of the bulb.

Abstract: A plasma cell for use in a laser-sustained plasma light source includes a plasma bulb configured to contain a gas suitable for generating a plasma, the plasma bulb being transparent to light from a pump laser, wherein the plasma bulb is transparent to at least a portion of a collectable spectral region of illumination emitted by the plasma. The plasma bulb of the plasma cell is configured to filter short wavelength radiation, such as VUV radiation, emitted by the plasma sustained within the bulb in order to keep the short wavelength radiation from impinging on the interior surface of the bulb.

Abstract: An illumination source for igniting and sustaining a plasma in a plasma lamp of a laser-sustained plasma (LSP) broadband source includes one or more ignition lasers configured to ignite the plasma within a gas contained within the plasma lamp. The illumination sources also includes one or more sustaining lasers configured to sustain the plasma. The illumination sources includes a delivery optical fiber one or more optical elements configured to selectively optically couple an output of the one or more ignition lasers and an output of the one or more sustaining lasers to the delivery optical fiber.

Abstract: A system for providing flexible optical aperture shapes in an optical inspection system (e.g., an optical wafer inspection system) is described. The system includes one or more mechanisms for providing multiple optical aperture shapes along an optical beam path in the optical wafer inspection system. The multiple optical apertures shapes are stacked or overlapped to combine the shapes and form a single combined optical aperture shape along the optical beam path.

Abstract: A fluid input manifold distributes injected fluid around the body of a bulb to cool the bulb below a threshold. The injected fluid also distributes heat more evenly along the surface of the bulb to reduce thermal stress. The fluid input manifold may comprise one or more airfoils to direct a substantially laminar fluid flow along the surface of the bulb or it may comprise a plurality of fluid injection nozzles oriented to produce a substantially laminar fluid flow. An output portion may be configured to facilitate fluid flow along the surface of the bulb by allowing injected fluid to easily escape after absorbing heat from the bulb or by applying negative pressure to actively draw injected fluid along the surface of the bulb and away.

Abstract: In an optical inspection tool, an illumination aperture is opened at each of a plurality of aperture positions of an illumination pupil area one at a time across the illumination pupil area. For each aperture opening position, an incident beam is directed towards the illumination pupil area so as to selectively pass a corresponding ray bundle of the illumination beam at a corresponding set of one or more incident angles towards the sample and an output beam, which is emitted from the sample in response to the corresponding ray bundle of the incident beam impinging on the sample at the corresponding set of one or more incident angles, is detected. A defect detection characteristic for each aperture position is determined based on the output beam detected for each aperture position. An optimum aperture configuration is determined based on the determined defect detection characteristic for each aperture position.

Abstract: In an optical inspection tool, an illumination aperture is opened at each of a plurality of aperture positions of an illumination pupil area one at a time across the illumination pupil area. For each aperture opening position, an incident beam is directed towards the illumination pupil area so as to selectively pass a corresponding ray bundle of the illumination beam at a corresponding set of one or more incident angles towards the sample and an output beam, which is emitted from the sample in response to the corresponding ray bundle of the incident beam impinging on the sample at the corresponding set of one or more incident angles, is detected. A defect detection characteristic for each aperture position is determined based on the output beam detected for each aperture position. An optimum aperture configuration is determined based on the determined defect detection characteristic for each aperture position.

Abstract: In an optical inspection tool, an illumination aperture is opened at each of a plurality of aperture positions of an illumination pupil area one at a time across the illumination pupil area. For each aperture opening position, an incident beam is directed towards the illumination pupil area so as to selectively pass a corresponding ray bundle of the illumination beam at a corresponding set of one or more incident angles towards the sample and an output beam, which is emitted from the sample in response to the corresponding ray bundle of the incident beam impinging on the sample at the corresponding set of one or more incident angles, is detected. A defect detection characteristic for each aperture position is determined based on the output beam detected for each aperture position. An optimum aperture configuration is determined based on the determined defect detection characteristic for each aperture position.

Abstract: Methods and systems for reconfiguring an aperture of an optical inspection system are presented. A programmable aperture system includes a two dimensional array of mechanical pixels that selectively block light passing through the aperture. An array of linear guiding elements is aligned parallel to one another, and each row of mechanical pixels is supported by a corresponding linear guiding element. Each mechanical pixel is configured to slide along the corresponding linear guiding element when pushed by an actuator subsystem. The actuator subsystem repositions one or more of the mechanical pixel elements to change the shape of the aperture. The actuator subsystem is configured to selectively engage one or more mechanical pixel elements and translate the one or more mechanical pixel elements along corresponding linear guiding elements to a new position.

Abstract: Disclosed are methods and apparatus for performing inspection or metrology of a semiconductor device. The apparatus includes a plurality of laser diode arrays that are configurable to provide an incident beam having different wavelength ranges. At least some of the laser diode arrays form two dimensional stacks that have different wavelength ranges from each other. The apparatus also includes optics for directing the incident beam towards the sample, a detector for generating an output signal or image based on an output beam emanating from the sample in response to the incident beam, and optics for directing the output beam towards the detector. The apparatus further includes a controller for configuring the laser diode arrays to provide the incident beam at the different wavelength ranges and detecting defects or characterizing a feature of the sample based on the output signal or image.

Abstract: Disclosed are methods and apparatus for performing inspection or metrology of a semiconductor device. The apparatus includes a plurality of laser diode arrays that are configurable to provide an incident beam having different wavelength ranges. At least some of the laser diode arrays form two dimensional stacks that have different wavelength ranges from each other. The apparatus also includes optics for directing the incident beam towards the sample, a detector for generating an output signal or image based on an output beam emanating from the sample in response to the incident beam, and optics for directing the output beam towards the detector. The apparatus further includes a controller for configuring the laser diode arrays to provide the incident beam at the different wavelength ranges and detecting defects or characterizing a feature of the sample based on the output signal or image.

Abstract: In an optical inspection tool, an illumination aperture is opened at each of a plurality of aperture positions of an illumination pupil area one at a time across the illumination pupil area. For each aperture opening position, an incident beam is directed towards the illumination pupil area so as to selectively pass a corresponding ray bundle of the illumination beam at a corresponding set of one or more incident angles towards the sample and an output beam, which is emitted from the sample in response to the corresponding ray bundle of the incident beam impinging on the sample at the corresponding set of one or more incident angles, is detected. A defect detection characteristic for each aperture position is determined based on the output beam detected for each aperture position. An optimum aperture configuration is determined based on the determined defect detection characteristic for each aperture position.

Abstract: Methods and systems for reconfiguring an aperture of an optical inspection system are presented. A programmable aperture system includes a two dimensional array of mechanical pixels that selectively block light passing through the aperture. An array of linear guiding elements is aligned parallel to one another, and each row of mechanical pixels is supported by a corresponding linear guiding element. Each mechanical pixel is configured to slide along the corresponding linear guiding element when pushed by an actuator subsystem. The actuator subsystem repositions one or more of the mechanical pixel elements to change the shape of the aperture. The actuator subsystem is configured to selectively engage one or more mechanical pixel elements and translate the one or more mechanical pixel elements along corresponding linear guiding elements to a new position.

Abstract: Disclosed are methods and apparatus for performing inspection or metrology of a semiconductor device. The apparatus includes a plurality of laser diode arrays that are configurable to provide an incident beam having different wavelength ranges. The apparatus also includes optics for directing the incident beam towards the sample, a detector for generating an output signal or image based on an output beam emanating from the sample in response to the incident beam, and optics for directing the output beam towards the detector. The apparatus further includes a controller for configuring the laser diode arrays to provide the incident beam at the different wavelength ranges and detecting defects or characterizing a feature of the sample based on the output signal or image.

Abstract: A system for providing flexible optical aperture shapes in an optical inspection system (e.g., an optical wafer inspection system) is described. The system includes one or more mechanisms for providing multiple optical aperture shapes along an optical beam path in the optical wafer inspection system. The multiple optical apertures shapes are stacked or overlapped to combine the shapes and form a single combined optical aperture shape along the optical beam path.

Abstract: A fluid input manifold distributes injected fluid around the body of a bulb to cool the bulb below a threshold. The injected fluid also distributes heat more evenly along the surface of the bulb to reduce thermal stress. The fluid input manifold may comprise one or more airfoils to direct a substantially laminar fluid flow along the surface of the bulb or it may comprise a plurality of fluid injection nozzles oriented to produce a substantially laminar fluid flow. An output portion may be configured to facilitate fluid flow along the surface of the bulb by allowing injected fluid to easily escape after absorbing heat from the bulb or by applying negative pressure to actively draw injected fluid along the surface of the bulb and away.