Apparatus, systems, and methods for processing workpieces are provided. An arc lamp can include a tube. The arc lamp can include one or more inlets configured to receive water to be circulated through the arc lamp during operation as a water wall, the water wall configured to cool the arc lamp. The arc lamp can include a plurality of electrodes configured to generate a plasma in a forming gas introduced into the arc lamp via the one or more inlets. The forming gas can be or can include a mixture of a hydrogen gas and an inert gas, the hydrogen gas in the mixture having a concentration less than 4% by volume. The hydrogen gas can be introduced into the arc lamp prior to generating the plasma. The arc lamp may be used for processing workpieces.

The subject of the invention is a method and device for reducing contamination in a plasma reactor, especially contamination by lubricants, particularly for plasma processing of materials. The method is based on the fact that the contaminated gas pumped out of at least one reduced pressure vacuum chamber in the form of a plasma lamp (LA.sub.1, LA.sub.2, LA.sub.3) is purified in at least one purifying plasma lamp (LA.sub.01, LA.sub.02, LA.sub.H, LA.sub.E), in which a glow discharge is initiated between the anodes of the purifying plasma lamp (A01, A02) and the cathodes of the purifying plasma lamp (K.sub.01, K.sub.02), favorably particles of lubricants are cracked and partially polymerized, while processed heavy particles of lubricants are collected in a buffer tank (ZB) and then discharged outside the pumping system. The device contains at least one reduced pressure vacuum chamber in the form of a plasma lamp (LA.sub.1, LA.sub.2, LA.sub.3), it is connected to at least one purifying plasma lamp (LA.sub.01, LA.sub.02, LA.sub.H, LA.sub.E) with a buffer tank (ZB) connected to a vacuum pump (PP). The vacuum tube connecting the plasma lamps (LA.sub.1, LA.sub.2, LA.sub.3) with the purifying plasma lamp (LA.sub.01, LA.sub.02, LA.sub.H, LA.sub.E)) is equipped with a dosing valve (V) for the gaseous admixture medium (MD) to plasma lamps (LA.sub.1, LA.sub.2, LA.sub.3), from which radiation (R.sub.1, R.sub.2, R.sub.3) is directed to the processed material (OM).

The subject of the invention is a method and device for reducing contamination in a plasma reactor, especially contamination by lubricants, particularly for plasma processing of materials. The method is based on the fact that the contaminated gas pumped out of at least one reduced pressure vacuum chamber in the form of a plasma lamp (LA.sub.1, LA.sub.2, LA.sub.3) is purified in at least one purifying plasma lamp (LA.sub.01, LA.sub.02, LA.sub.H, LA.sub.E), in which a glow discharge is initiated between the anodes of the purifying plasma lamp (A01, A02) and the cathodes of the purifying plasma lamp (K.sub.01, K.sub.02), favorably particles of lubricants are cracked and partially polymerized, while processed heavy particles of lubricants are collected in a buffer tank (ZB) and then discharged outside the pumping system. The device contains at least one reduced pressure vacuum chamber in the form of a plasma lamp (LA.sub.1, LA.sub.2, LA.sub.3), it is connected to at least one purifying plasma lamp (LA.sub.01, LA.sub.02, LA.sub.H, LA.sub.E) with a buffer tank (ZB) connected to a vacuum pump (PP). The vacuum tube connecting the plasma lamps (LA.sub.1, LA.sub.2, LA.sub.3) with the purifying plasma lamp (LA.sub.01, LA.sub.02, LA.sub.H, LA.sub.E)) is equipped with a dosing valve (V) for the gaseous admixture medium (MD) to plasma lamps (LA.sub.1, LA.sub.2, LA.sub.3), from which radiation (R.sub.1, R.sub.2, R.sub.3) is directed to the processed material (OM).

An ultraviolet lamp includes a lamp tube and an electrode. A discharge cavity is formed in the lamp tube. A thermistor is disposed on an end socket at a first end of the lamp tube. A receiving groove communicated with the discharge cavity is formed in the end socket and contains amalgam. The thermistor heats the amalgam in the receiving groove in the end socket. The Curie temperature of the thermistor ranges from [T1+(T2−T1)/5] to [T1+4*(T2−T1)/5], wherein T1 and T2 are respectively a minimum operating temperature and a maximum operating temperature of the amalgam in a continuous region where the ultraviolet radiation power is from 90% to 100% when the input power of the ultraviolet lamp is 100%.

Apparatus, systems, and methods for processing workpieces are provided. An arc lamp can include a tube. The arc lamp can include one or more inlets configured to receive water to be circulated through the arc lamp during operation as a water wall, the water wall configured to cool the arc lamp. The arc lamp can include a plurality of electrodes configured to generate a plasma in a forming gas introduced into the arc lamp via the one or more inlets. The forming gas can be or can include a mixture of a hydrogen gas and an inert gas, the hydrogen gas in the mixture having a concentration less than 4% by volume. The hydrogen gas can be introduced into the arc lamp prior to generating the plasma. The arc lamp may be used for processing workpieces.

Apparatus, systems, and methods for processing workpieces are provided. An arc lamp can include a tube. The arc lamp can include one or more inlets configured to receive water to be circulated through the arc lamp during operation as a water wall, the water wall configured to cool the arc lamp. The arc lamp can include a plurality of electrodes configured to generate a plasma in a forming gas introduced into the arc lamp via the one or more inlets. The forming gas can be or can include a mixture of a hydrogen gas and an inert gas, the hydrogen gas in the mixture having a concentration less than 4% by volume. The hydrogen gas can be introduced into the arc lamp prior to generating the plasma. The arc lamp may be used for processing workpieces.

An embodiment provides a lamp apparatus, including: at least one filament; an amount of amalgam; a heat-sink assembly connected to the lamp apparatus; and at least one control circuit comprising a heating element and a temperature measurement element connected to the at least one filament, wherein the control circuit varies the electrical power delivered to the heating element, thereby controlling an internal temperature of the lamp apparatus relative to a temperature set point. Other aspects are described and claimed.

A germicidal UV amalgam lamp with an elongated tubular lamp body and at least two filaments located on opposite ends of the lamp body. The lamp body is hermetically sealed with a pinch-sealed portion at both opposite ends, confining a gas volume in which a gas discharge can be produced along a discharge path between the filaments. Each filament has two electrical connectors, each including an internal portion connected to the filament and pinch-sealed into the lamp body. Each connector also includes an external portion located outside the lamp body for electrical connection of the lamp to a controlled power supply. The pinch-sealed portion bears a socket with an electrical temperature sensor and at least two electrical connections mounted to the socket. The at least two electrical connections of the temperature sensor are connected in parallel to the electrical connectors of the filament.

A laser-sustained broadband light source includes a gas containment structure and multiple jet nozzles. The jet nozzles are configured to direct multiple liquid jets of plasma-forming material in directions to collide with one another within the gas containment structure. The laser-sustained broadband light source further includes a laser pump source configured to generate an optical pump to sustain a plasma in a region of the gas containment structure at a collision point of the plurality of liquid jets and a light collector element configured to collect broadband light emitted from the plasma.

A laser-sustained broadband light source includes a gas containment structure and multiple jet nozzles. The jet nozzles are configured to direct multiple liquid jets of plasma-forming material in directions to collide with one another within the gas containment structure. The laser-sustained broadband light source further includes a laser pump source configured to generate an optical pump to sustain a plasma in a region of the gas containment structure at a collision point of the plurality of liquid jets and a light collector element configured to collect broadband light emitted from the plasma.