Laser-driven light source with electrodeless ignition

Abstract
An electrodeless laser-driven light source includes a laser that generates a CW sustaining light. A pump laser generates pump light. A Q-switched laser crystal receives the pump light generated by the pump laser and generates pulsed laser light at an output in response to the generated pump light. A first optical element projects the pulsed laser light along a first axis to a breakdown region in a gas-filled bulb comprising an ionizing gas. A second optical element projects the CW sustaining light along a second axis to a CW plasma region in the gas-filled bulb comprising the ionizing gas. A detector detects plasma light generated by a CW plasma and generates a detection signal at an output. A controller generates control signals that control the pump light to the Q-switched laser crystal so as to extinguish the pulsed laser light within a time delay after the detection signal exceeds a threshold level.
Description

The section headings used herein are for organizational purposes only and should not be construed as limiting the subject matter described in the present application in any way.


INTRODUCTION

Numerous commercial and academic applications have need for high brightness light over a broad wavelength range. For example, laser-driven light sources are available that provide high brightness over spectral ranges from the extreme UV through visible and into the infrared regions of the spectrum with high reliability and long lifetimes. Various examples of such high-brightness light sources are produced by Energetiq, a Hamamatsu Company, located in Wilmington, MA.


There is growing demand for high-brightness light sources for applications including, for example, semiconductor metrology, sensor calibration and testing, creating shaped light, surface metrology, spectroscopy and other optical measurement applications in diverse fields including biology, chemistry, climate, and physics. As such, advances are needed in high-brightness light sources that can improve, for example, size, cost, complexity, reliability, stability and efficiency of this important type of broadband light sources.





BRIEF DESCRIPTION OF THE DRAWINGS

The present teaching, in accordance with preferred and exemplary embodiments, together with further advantages thereof, is more particularly described in the following detailed description, taken in conjunction with the accompanying drawings. The skilled person in the art will understand that the drawings, described below, are for illustration purposes only. The drawings are not necessarily to scale; emphasis instead generally being placed upon illustrating principles of the teaching. The drawings are not intended to limit the scope of the Applicant's teaching in any way.



FIG. 1A illustrates an embodiment of an electrodeless laser-driven light source that uses pulsed laser light projected into a gas-filled bulb along one axis and CW laser light projected into the gas-filled bulb along a different axis according to the present teaching.



FIG. 1B illustrates an embodiment of an electrodeless laser-driven light source that uses pulsed laser light projected into a gas-filled bulb along one axis and CW laser light projected into the gas-filled bulb along the same axis according to the present teaching.



FIG. 2A illustrates images of a gas-filled bulb in an embodiment of an electrodeless laser-driven light source according to the present teaching that shows the emission with only pulse laser excitation.



FIG. 2B illustrates images of the gas-filled bulb shown in FIG. 2A that shows the emission with only CW laser excitation.



FIG. 3 illustrates a flow diagram of steps of a method to ignite a plasma in an electrodeless laser-driven light source according to the present teaching.



FIG. 4 illustrates a set of oscilloscope traces for each of the pulsed laser illumination, the pump laser illumination, and the plasma emission from an electrodeless laser-driven light source according to the present teaching.



FIG. 5A illustrates an embodiment of a Q-switched crystal that includes a gain region and a saturable absorber region according to the present teaching.



FIG. 5B illustrates an embodiment of a YAG-based passively Q-switched laser rod with a curved face suitable for use in an electrodeless laser-driven light source according to the present teaching.



FIG. 6 illustrates a graph of the pulse energy and pump current threshold for a pump laser that creates a laser pulse sufficient to result in gas breakdown as a function of the pulse length of the quasi-CW pump pulse used in an embodiment of an electrodeless laser-driven light source according to the present teaching.



FIG. 7 illustrates a bare bulb with focusing lens assembly used in an embodiment of an electrodeless laser-driven light source according to the present teaching.





DESCRIPTION OF VARIOUS EMBODIMENTS

The present teaching will now be described in more detail with reference to exemplary embodiments thereof as shown in the accompanying drawings. While the present teaching is described in conjunction with various embodiments and examples, it is not intended that the present teaching be limited to such embodiments. On the contrary, the present teaching encompasses various alternatives, modifications and equivalents, as will be appreciated by those of skill in the art. Those of ordinary skill in the art having access to the teaching herein will recognize additional implementations, modifications, and embodiments, as well as other fields of use, which are within the scope of the present disclosure as described herein.


Reference in the specification to “one embodiment” or “an embodiment” means that a particular feature, structure, or characteristic described in connection with the embodiment is included in at least one embodiment of the teaching. The appearances of the phrase “in one embodiment” in various places in the specification are not necessarily all referring to the same embodiment.


It should be understood that the individual steps of the method of the present teaching can be performed in any order and/or simultaneously as long as the teaching remains operable. Furthermore, it should be understood that the apparatus and method of the present teaching can include any number or all of the described embodiments as long as the teaching remains operable.


Laser driven light sources use a CW laser to directly heat a gas plasma to the high temperature needed to produce broadband optical light. High-brightness laser driven light sources have a significant advantage compared to light sources that use high-voltage electrodes to sustain a plasma. Laser driven sources depend on optical-discharge plasma as opposed to electric discharge plasma used in, for example, arc-lamp devices. In electric discharge lamps, electrode materials can evaporate, and change the properties of the discharge over the life of the lamp. This reduces lamp lifetime. Also, electrode-based systems lead to thermal, mechanical and electrical stress of the light source. Known laser driven light sources do not rely on electrodes to sustain the plasma, however they still utilize electrodes for plasma ignition.


Known light sources that rely on electrodes can have serious limitations. For example, electrode-based light sources can have limits on the lamp head size and restrictions on how bulb can be mounted. Electrode-based light sources must be designed to avoid parasitic arcs, and the lamp head needs be configured with sufficient volume for electrodes and for ignition circuit. Electrode-based light sources have limitations on the cold fill pressure of the bulb because, for example, the glass-to-metal seal of electrodes can limit the maximum fill pressure. Also, the size of the bulb can be larger in electrode-based light sources, which can affect bulb fill pressure. Electrode-based light sources also have limited bulb shapes that can be accommodated. This is because, for example, electrode-based light sources require positioning, securing, and connecting electrodes. These design constraints can result in producing noise in the light source.


Thus, providing a laser driven light source with electrodeless ignition can lead to improved reliability, performance, reduced cost and complexity in addition to other benefits. Igniting a plasma with optical illumination requires careful design and control of the light source and associated light delivery mechanisms used to ignite the plasma. One feature of the present teaching is providing a laser-driven light source with electrodeless ignition. In these sources, the plasma is ignited by optical illumination, and not by electrical energy provided by an electrode as in known laser driven high-brightness light sources.


There are numerous features and benefits of electrodeless laser driven light sources. Electrodeless light sources can be implemented using a smaller bulb with higher maximum fill pressures than prior art light sources. A higher fill pressure can result in higher brightness, especially in certain laser power regimes. Electrodeless light sources have no contamination from electrode material. In addition, there are fewer lamp shape geometry limitations. Generally smaller lamp heads can be used for the same characteristics. Also, there are no active electrical components to power, thereby reducing the need for an associated power supplies, control electronics and electrical connection, which significantly reduces the number of required components. However, some embodiments of electrodeless laser drive light source can be implemented in the existing lamp package of laser-driven light sources that do have electrode ignition. This is at least, in part, because the electrodeless device is generally less complex and smaller than electrode-lased laser driven light sources.



FIG. 1A illustrates an embodiment of an electrodeless laser-driven light source 100 that uses pulsed laser light 102 projected into a gas-filled bulb 104 along one axis 106 and CW laser light 108 projected into the gas-filled bulb 104 along a different axis 110 according to the present teaching. The pulsed laser light 102 is generated using a Q-switch crystal 112 that is pumped with pump laser light 114 generated by a pump laser 116. Coupling optics 118 are used to couple the pump laser light 114 into the Q-switch crystal 112. An optical element 120 is used to direct the pulsed laser light 102 generated in the Q-switch crystal 112 toward the bulb 104 and to direct the pump laser light 114 away from the bulb. In some embodiments, the optical element 120 is a dichroic optical element. Energy from the pulsed laser light 102 provided to the plasma breakdown region 126 ignites the plasma.


A CW laser generates the CW laser light 108. An optical element 124 projects and/or focuses the CW sustaining light to a region comprising a plasma breakdown region 126 in the bulb 104. In some embodiments, the optical element 124 is a focusing element such as a lens. An optical element 128 projects and/or focuses the pulsed laser light 102 to a region comprising a plasma breakdown region 126 in the bulb 104. In some embodiments, the optical element 128 is a focusing element such as a lens. The region illuminated by the pulse laser light is referred to as the pulse illumination region, and has a well-defined position and shape based on the projection elements used to direct the optical light from the Q-switch crystal 112. Energy from the pulsed laser light 102 provided to the plasma breakdown region 126 ignites the plasma. The region illuminated by the CW sustaining light is referred to as the CW sustaining illumination region, and has a well-defined position and shape based on the projection elements used to direct the optical light from the CW laser 122. Energy from the CW laser light 108 provided to the plasma breakdown region 126 sustains the plasma.


The plasma breakdown region 126 produces CW plasma light 130. The CW plasma light 130 is incident on a detector 132. The CW plasma light 130 may be directed to the detector 132 by the optical element 120, or via free space and/or by other optical transmission means. The detector 132 generates a detection signal at an output that is connected to a controller 134. The controller 134 is connected to a control input of the pump laser 116. The controller 134 generates control signals that control the parameters of the pump light 114 that is directed to the Q-switch laser crystal 112. In some embodiments, the controller 134 is configured to control the pump laser 116 and parameters of the pump light 114 in such a way as to extinguish the pulsed laser light 102 within a time delay after the detection signal from the detector 132 exceeds a predetermined threshold level.


The high-peak-power pulsed light 102 is needed to ignite the plasma in the plasma breakdown region 126. However, to generate sustained CW plasma light 130, the pulsed light must not exceed a certain threshold, which can occur if pulses are present in the plasma after a predetermined delay after the plasma light reaches a predetermined threshold. Too much pulse light can extinguish the plasma. By extinguishing the pulsed light before the threshold is achieved, the plasma light can be sustained by application of only the CW sustaining light 108.


In some embodiments, a certain number, for example, one or more of pulses from the pulse light are needed to ignite a plasma, but additional pulses after ignition will quench the plasma. As such, once plasma light 130 is detected at the detector 132, the pulses are extinguished before a next pulse is generated after the igniting pulse. It should be understood that this configuration is just one example of this aspect of the present teaching. Various algorithms and thresholds for extinguishing the pump light 114 after various delays relative to the onset of plasma light 130 can be used by systems according to the present teaching. These parameters would be dependent on various factors including, for example, the type, density and/or temperature of gas. Also, these parameters would be dependent on the relative powers of the pulsed light, and CW sustaining light 108. Also, these parameters would be dependent on the focusing and other optical properties of optical elements 124, 128. In addition, these parameters would be dependent on the energy density of the CW sustaining light 108 and/or the pulsed light 102 in the plasma breakdown region.


One feature of the present teaching is that the axes of the pulsed light and the CW sustaining light can take on various relative positions. For example, referring to FIG. 1A, the axes 106, 110 are nominally orthogonal. It is also possible to configure the electrodeless laser-drive light source so the pulsed light and CW light are on the same axis.



FIG. 1B illustrates an embodiment of an electrodeless laser-driven light source 150 that uses pulsed laser light 152 projected into a gas-filled bulb 154 along one axis and CW laser light 156 projected into the gas-filled bulb along the same axis according to the present teaching. The electrodeless laser-driven light source 150 shares many common elements as the electrodeless laser-driven light source 100 of FIG. 1A. A Q-switch crystal 158 is pumped with pump laser light 160 generated by a pump laser 162. Coupling optics 164, which in some embodiments, is a collimation package that nominally collimates light, receives the light generated by the pump laser 162 and directs it to the Q-switch crystal 158.


An optical element 166 is used to direct the pulsed laser light 152 generated in the Q-switch crystal 158 toward the bulb 154. The optical element 166 can direct (e.g. reflect) the pump laser light 160 away from the bulb 154. In some embodiments, the optical elements 166, 168 are dichroic optical elements. In some embodiments, optical element 166 transmit light with the pulsed light wavelength 152 and also transmits CW laser light 156. A CW laser 170 generates the CW laser light 156. An optical element 172 projects and/or focuses the CW sustaining light 156 and the pulsed laser light 152 to a region comprising a plasma breakdown region 174 in the bulb 154. In some embodiments, the optical element 172 is a focusing element such as a lens.


The plasma breakdown region 174 produces CW plasma light 176. The CW plasma light 176 is incident on a detector 178. The CW plasma light 176 may be directed to the detector 178 by the optical element 166, or via free space and/or by other optical transmission means. The detector 178 generates a detection signal at an output in response to the detected CW plasma light. The output of the detector 178 is connected to a controller 180. The controller 180 is connected to a control input of the pump laser 162. The controller 180 generates control signals that control the parameters of the pump light 160 that is directed to the Q-switch laser crystal 158. In some embodiments, the controller 180 is configured to control the pump laser 162 and associated parameters of the pump light 160 in such a way as to extinguish the pulsed laser light 152 within a time delay after the detection signal from the detector 178 exceeds a predetermined threshold level. In some embodiments, the light from the CW laser 170 is collimated using a collimation package 182. An optical element 184, which may comprise one or more optical elements, is used to focus the pump laser light 160 onto the Q-switch crystal 158.


Another feature of the present teaching is that the pulsed light and the CW sustaining light can, in some embodiments, be directed to form independent illumination regions in the plasma region. The two illumination regions can be distinct or can overlap in part or in whole, as desired. The control over the relative positions and shapes of the pulsed illumination region and the CW sustaining illumination region can be used to provide particular spatial distributions of energy delivered by these two sources. As described further herein, the energy density of each of the CW sustaining light and the pulsed light impact the ignition and sustainability of the plasma. As such, the ability to control the relative positions and shapes of the pulsed illumination region and the CW sustaining illumination region allows control of the energy density profiles provided to the plasma. This positioning affects the ability for the ignited plasma generated in the pulsed illumination region to transition to the CW illumination region as a stable CW plasma.



FIG. 2A illustrates images 200 of a gas-filled bulb in an embodiment of an electrodeless laser-driven light source according to the present teaching that shows the emission with only pulse laser excitation. Both images 202, 204 are shown from their side-view, but they are offset in angle to illustrate the three-dimensional positioning of the locations of the pulsed illumination region and the focus of the CW laser. The extent and position of the pulsed illumination region is visible in these images 202, 204. Note that the position of pulse breakdown depends on the pulse energy. As the energy increases, breakdown location moves toward pulsed laser. Three-dimensional alignment of the pulse laser breakdown plasma relative to the pulsed light and relative to the focus of the CW laser allows the method to work with lower CW laser power and/or lower pulse energy.



FIG. 2B illustrates images 250 of the gas-filled bulb shown in FIG. 2A that shows the emission with only CW laser excitation. Both images 252, 254 are shown from their side-view, but they are offset in angle to illustrate the three-dimensional positioning of the locations of the pulsed illumination region and the focus of the CW laser. The extent and position of the pulsed illumination region is visible in these images 252, 254. Outlines 256, 258 of the pulse illumination regions from the images 202, 204 of FIG. 2A are also illustrated. In this embodiment, the relative positions and shapes of the pulsed illumination region and the CW sustaining illumination region are such that the two regions are distinct and do not overlap. The pulse illumination region is smaller as the light is more tightly focus, resulting in a high density of pulsed energy delivered to the plasma by the illumination.


The images of FIGS. 2A-B were collected during experiments to determine operating parameters for pulses that provide plasma ignition. Some details of the experimental conditions are described below. For example, with a 2-kHz pulse rate and 1-ns-duration pulse, stable plasma ignition can be realized in a xenon gas-filled bulb over a range of energies from 135 to 225 micro Joule. The pulse light had a 1064 nm wavelength. For this particular example of an experimental configuration, the threshold energy to breakdown light to achieve a stable CW plasma was 135 micro Joule. Furthermore, at 210 micro Joules, the plasma ignites and can eventually be stable, but there can be ignition and extinguishing of CW plasma before the stable operation. It is also possible to realize ignition at 225 micro Joules. Above 240 micro Joules, the CW plasma was not stable in some configurations. The relative position of the pulsed light illumination and the CW light illumination is critical. Adjusting the bulb and CW laser alignment along the optical axis of the pulsed laser improves or ‘turns off’ ignition. After a CW plasma was lit, the CW laser power could be lowered to 8-10 Watts and still sustain the CW laser plasma. At any value of CW laser power above 15.5 Watts, there was reliable transition from pulse to CW. There was no upper limit on CW laser power. As understood by those skilled in the art, the beam quality affects the energy delivered to the gas for a given laser power.


Another feature of the electrodeless ignition of the present teaching is the recognition that CW plasma ignition can be implemented as a two-step process. In a first step, the xenon gas breaks down with the application of a laser pulse. In a second step, there is a transition or a “handoff” from the pulse plasma to a sustained CW plasma. Then, a shut-off for the pulse laser light is performed after the sustained plasma begins to be produces results in a successful handoff. For example, by performing a shutoff at “first light” of the CW plasma, a handoff can be realized. It is important to shut off the pulse light before additional pulses after ignition, because subsequent pulses can knock-out the CW plasma light. The number of pulses that can be tolerated is dependent of the power of the CW plasma light. In some embodiments, the pulse light is extinguished in a time delay that is short enough so that the next pulse in the period after the igniting pulse is extinguished.



FIG. 3 illustrates a flow diagram 300 of steps of a method to ignite a plasma in an electrodeless laser-driven light source according to the present teaching. The flow diagram 300 illustrates the steps to control the delivery of energy into a plasma region contained in a gas-filled bulb to produce high brightness light in which the plasma is ignited by illumination rather than by electrical energy provided by an electrode as in prior art high-brightness light sources. In a first step 302, electromagnetic energy is provided to a gas within a bulb using continuous CW laser light. This may be referred to a CW sustaining light. In some embodiments, the gas is xenon gas. In a second step 304, laser pulses are generated by providing pump laser light to a Q-switched crystal. One feature of the present teaching is the recognition that the pulses provided by the Q-switch crystal can be controlled by controlling the application of the pump light to the crustal. In a third step 306, the laser pulses are provided to the gas in the bulb, which causes a breakdown region to form in the gas. In a fourth step 308, the CW laser light provided to the bulb is absorbed when the appropriate density of ions and electrons generated by the pulse light is achieved. In a fifth step 310, the absorption of the CW laser light energizes the ions and electrons and produces a CW plasma that emits a high brightness light in a plasma region. That is, the electromagnetic energy provided by the CW sustaining light leads to production of CW plasma light from the bulb.


In a sixth step 312, a portion of the emitted high brightness light from the bulb is detected in a detector. The detector generates a plasma-detect signal in response to the portion of the CW plasma light that it receives. This signal can be provided to a controller. In a seventh step 314, the pump laser is stopped when the plasma-detect signal exceeds a predetermined threshold. The cessation of the pump causes discontinuation of the pulses. That is, the pulse light is extinguished in response to stopping the pump light from reaching the Q-switch crystal. In some embodiments, the controller stops the laser pump. In an eighth step 316, the CW plasma is sustained using the CW sustaining light. We note that in some embodiments the CW continuous light is nominally a continuous light source that is produced by pulsed laser operation at a high pulse rate.


Various embodiments of the laser-driven high brightness sources with electrodeless ignition of the present teaching use different parameters of the light provided to the gas. For example, the repetition rate of Q-switched laser pulses can be controlled. The pulse energy of the pulse light that is provided to the gas can be controlled. The duration of the Q-switch laser pulses can also be controlled. In addition, the power of the CW laser light is also controlled. In some embodiments, a pulse repetition rate of the pulsed laser light is in a range of 1 kHz to 20 kHz.


Experimental and/or theoretical evaluations have determined that quality CW plasma can be provided, for example, when the Q-switch laser crystal is configured so that a pulse repetition rate of the pulsed laser light is less than or equal to 1 kHz. Continuous wave plasma can be produced when the Q-switched laser crystal is configured so that a pulse energy of the pulsed laser light is in a range of 50 micro Joules to 500 micro Joules.


Continuous wave plasma is produced under a variety of pulse energy, pulse duration, and CW power conditions depending on the particular configuration. For example, continuous wave plasma is produced when the Q-switch laser crystal is configured so that a pulse energy of the pulsed laser light is in a range of 500 micro Joules to 5 millijoules. In addition, continuous wave plasma can be produced when the Q-switch laser crystal is configured so that a pulse duration of the pulsed laser light is in a range of 0.1 ns to 10 ns. Continuous wave plasma can also be produced when the CW laser source is configured so that a power of the CW sustaining light is in a range of 5 W to 50 W. Also, continuous wave plasma can be produced when the CW laser source is configured so that a power of the CW sustaining light is in a range of 5 W to 1500 W. The ranges described above are just examples of operating ranges, and not intended to limit the present teaching in any way.


One feature of the present teaching is that the detection of CW plasma can be used to control the igniting pulsed laser light. In some embodiments, this control prevents the extinguishing or other undesirable impact of pulses on the CW plasma light after the plasma is ignited. FIG. 4 illustrates a set of oscilloscope traces 400 for each of the pulsed laser illumination, the pump laser illumination, and the plasma emission from an electrodeless laser-driven light source according to the present teaching. The set of oscilloscope traces 400 illustrates the timing of the laser operation and plasma light generation in an embodiment of an electrodeless laser-driven light source of the present teaching. In FIG. 4, a measured pulsed laser illumination trace 402, a measured pump laser illumination trace 404, and a measured plasma emission trace 406 are shown as a function of time in the set of oscilloscope traces 400. The presence of pump light shown in trace 404 generates the two pulses 408, 410 visible in the pulse light trace 402. Plasma ignition begins after the second pulse 410, causing an increase in measured CW plasma light shown in trace 406.


The controller used in the system that generated these data is configured such that when the detected CW plasma light shown in trace 406 reached a threshold value 412, the pump was shut down 414. The extinguished pulses from the Q-switch crystal are shown in trace 402. Various control configurations are possible instead of or in addition to the conditions shown in the set of oscilloscope traces 400 of FIG. 4. The shutdown of the pump laser or extinguishing of the pump laser light be configured to occur nominally immediately after a threshold of CW plasma light is realized. The shutdown of the pump laser or extinguishing of the pump laser light can also be configured to occur after a predetermine delay after a threshold of CW plasma light is realized. In various methods according to the present teaching, various threshold can be utilized to achieve the desired performance.


In some embodiments, a detection signal represents a power of the plasma light and a threshold is chosen to be a desired ratio of the power of the plasma light to an operating power. In some embodiments, the desired ratio is nominally 50%. In other embodiments, the desired ratio is nominally 90%. In yet other embodiments, the desired ratio falls within a range between 30% and 95%.


The predetermined delay can be chosen to have a particular relationship to the pulse period of the pulsed laser light. This allows that the pump is shut off before a next pulse in the sequence of pulses is generated. In some embodiments, a period between pulses in the pulsed laser light is greater than the time delay. In some embodiments, the controller is configured so that the time delay is less than one pulse period of the pulsed laser light. It should be understood that the Q-switch crystal and/or pumping configuration and power levels can be adjusted to control the pulse period.


One feature of the present teaching is that it can use different known Q-switch crystals. The wavelength of the pulsed light should be appropriate to cause a breakdown of the gas specie(s) in the bulb. FIG. 5A illustrates an embodiment of a Q-switch crystal 500 that includes a gain region 502 and a saturable absorber region 504 according to the present teaching. As understood by those skilled in the art, different host materials and dopants can be used to provide a suitable gain region 502 and a saturable absorber region 504. For example, the crystal 500 can have a host material that can be a glass host, an yttrium aluminum garnet host, or a spinel host. For example, the crystal 500 can have a dopant in one or both of the gain region 502 and saturable absorber region 504 that can be an ytterbium dopant, a chromium dopant, a cobalt dopant or a vanadium dopant. The Q-switch crystal can also include a narrow-band filter that can be used, for example, to reflect at least some of the plasma light and/or block wavelengths in the xenon spectrum. In some embodiments, the Q-switched laser crystal has a coating on one surface. This coating, for example, can be a protective coating, a reflective coating, and/or an anti-reflection coating.



FIG. 5B illustrates an embodiment of an yttrium aluminum garnet based (YAG-based) passively Q-switched laser rod 550 with a curved face 552 suitable for use in an electrodeless laser-driven light source according to the present teaching. The saturable absorber region 554 is a chromium dopant in an yttrium aluminum garnet host. The gain region 556 is an ytterbium dopant in an yttrium aluminum garnet host. The dopant and host contribute to setting the wavelength of the pulsed light as well as the rise and fall time of the pulses. A saturable absorber region length 558, L2, a gain region length 560, L1, and a crystal width 562, W, are chosen to provide desired output pulse parameters, including, for example, pulse repetition rate, pulse duration, pulse energy.


Q-switch crystals are a proven technology. For example, Q-switch crystals are used in known passively Q-switched microchip lasers. As one particular example, a microchip laser using a crystal similar to the crystal 550 described in connection with FIG. 5B, with a saturable absorber region length 558, L2=1.36 mm, a gain region length 560, L1=3 mm, and a crystal width 562, W=3 mm, provided 1.6 ns pulses having 74 microJoules of energy at 14-kH repetition rate and was realized from a 10-W pump power at 970 nm wavelength pump laser. With increasing pump power, the mean output power, and generated pulse repetition rate can be increased to 1 W and 13.6 kHz, respectively, for a pumping power 9.3 W. A maximum output power can be reached without observable thermal roll-over. An average pulse width of 1.58±0.04 ns can also be realized. In practice, a pulse energy and peak power value of 73.8±0.7 μJ, and 46.0±0.8 kW, respectively, was realized. One feature of the present teaching is that electrodeless ignition can be realized with pulsed light parameters that can be realized by these highly available, compact, reliable sources of optical pulses provided by Q-switch crystals 500, 550.


Pumping efficiency and pulse output depend on various properties of the crystal 500, 550 including for the gain crystal 502, 556, the doping element (e.g. YB or Nd), the doping percentage, and the diameter and length. For the saturable absorber crystal 504, 552, the doping element (e.g. Cr or V), the doping percentage, initial absorption percent, diameter and/or length. In some embodiments, reflection and/or transmission coatings for pump wavelength and pulsed light wavelength are provided on one or more ends of the crystal 500, 550. For example, a Yb:YAG-Cr:YAG bonded crystal can include a coating on the Yb:YAG end that is high transmission for 940 nm, and high reflection for 1030 nm. And, on the Cr:YAG end, the crystal can have a coating that is only partially reflective at 1030 nm (i.e. output coupler). While many Q-switched lasers have pump configurations that have the saturable absorber and output coupler on the opposite end from the incoming pump laser, pulsed Q-switch crystals for electrodeless ignition can have the output coupler at the pump input end, rather than the saturable absorber end.


Some embodiments of the crystal 500, 550, can have undoped end sections around the Yb&Cr YAG, which can be referred to as a non-absorbing mirror. Such a configuration avoids thermal overload and facet failure. In the gain region 502, 556, a gain medium of Nd:YAG is common and relatively low cost. A Nd:YAG gain region 502, 556 is pumped at 808 nm, and emits light at 1064 nm. A gain region 502, 556 of Yb:YAG is less common and more expensive. This material is pumped at 940 or 970 nm wavelength and emits light at 1030 nm. These Yb:YAG crystals are most commonly coated to accommodate for 940 nm pumping. Crystals coated for 940 nm may not work well at 970 nm (e.g. coating at 940 nm only 60% transmissive at 970 nm.). In addition, 940 nm wavelength light is generally easier than 970 nm light to separate from 1030 nm. It is also possible for Yb doped glass to be pumped at 975 nm. This pump wavelength is the same as used in known laser driven light source laser wavelengths.


Some important features in the design of a Q-switch crystal for producing pulsed light for electrodeless ignition according to the present teaching include, for example, choice of laser wavelength, the order of arrangement of coatings, gain section, saturable absorber section, and the direction of the pump pulse input and output. Other important features include the combining/separation of the pump and plasma beams and accommodation of a need to protect the CW laser from the pulses produced by the Q-switch crystal. Referring back to FIGS. 1A-B, different embodiments of the light source 100, 150 have different configurations for the positions of the pump laser 116, 162, Q-switch crystal 112, 158 and CW laser 122, 170 that impact these design choices. In addition, because of the high pulse energies, the mounting of the crystal and associated thermal management are important considerations.



FIG. 6 illustrates a graph 600 of the pulse energy and pump current threshold for a pump laser that creates a laser pulse sufficient to result in gas breakdown as a function of the pulse length of the quasi-CW (QCW) pump pulse used in an embodiment of an electrodeless laser-driven light source according to the present teaching. That is, the pulse length is a width of a pulse that is repetitive (e.g., width of pulse in a square wave signal) that is used to generate a quasi-CW pump light signal. The graph 600 represents measurements on a bulb containing xenon gas. The graph 600 illustrates an example operating point, and shows that operation can occur over a range of pulse durations. The threshold levels out above pulse lengths of ˜500 microseconds. Note that various embodiments of the light source of the present teaching can operate with parameters that are different from those illustrated in this example data. Some examples of operational parameters of pulsed ignition and transition handoff for a 22 atmosphere pressure cold bulb fill with xenon gas as on particular example are as follows: (1) a CW transition handoff can be realized with CW laser power as low as 14 W at a 980 nm wavelength; (2) a CW transition handoff can be realized with CW laser light center wavelength as low as 972 nm; (3) a nearly instantaneous CW transition handoff can be realized with CW laser light center wavelength as low as 975 nm; and 4) a CW transition handoff can be realized with CW laser power as high as 50 Watts. When the content of laser spectrum at 980 nm goes to zero, a transition handoff may take from seconds to one or two minutes. When the CW laser power is at 20 Watts, the variation of the center wavelength is between 1-2 nm away from a 980 nm center wavelength for successful transition handoff. With a 30 atmosphere cold-fill bulb, it is possible to achieve a CW transition handoff at 30 Watts and 976 nm center wavelength from the CW laser. In general, ignition is more robust with a higher pressure bulb than a lower pressure bulb. For examples, a bulb with a pressures over 30 atm would in general have a more robust ignition than a bulb with a pressure of about 22 atm.



FIG. 7 illustrates a bulb system 700 including a bare bulb 702 with focusing lens assemblies 704, 706 used in an embodiment of an electrodeless laser-driven light source according to the present teaching. The plasma region 708 is shown. The focusing lens assemblies 704, 706 are configured at planes that are oriented at 90-degrees from one another. One assembly 704 directs the pulse light to the plasma region 708 in the bulb 702, and the other assembly 706 directs the CW sustaining light to the plasma region 708 in the bulb 702. As described herein, the shapes of the pulsed illumination and the CW sustaining illumination in the plasma region 708 can be the same or different. The positions of the pulsed illumination and the CW sustaining illumination in the plasma region 708 can be overlapped or can be distinct. In some embodiments, the bulb 702 is filled with xenon gas. In some embodiments, the bulb 702 is formed in a spherical shape. Also, in some embodiments, a pressure in the bulb 702 filled with gas can be a pressure in a range of 20 atm to 50 atm.


EQUIVALENTS

While the Applicant's teaching is described in conjunction with various embodiments, it is not intended that the Applicant's teaching be limited to such embodiments. On the contrary, the Applicant's teaching encompasses various alternatives, modifications, and equivalents, as will be appreciated by those of skill in the art, which may be made therein without departing from the spirit and scope of the teaching.

Claims
  • 1. An electrodeless laser-driven light source comprising: a) a gas filled bulb;b) a source that generates a continuous wave (CW) sustaining light that propagates to the gas filled bulb;c) a Q-switched laser crystal;d) a pump source that generates pump light that irradiates the Q-switched laser crystal, wherein the Q-switched laser crystal generates pulsed light that propagates to the gas-filled bulb when irradiated, and the pulsed light generates a CW plasma in the gas-filled bulb that emits light;e) a detector positioned to receive light emitted from the CW plasma in the gas-filled bulb, the detector generating a detection signal in response to the received light; andf) a controller that is connected to the detector and to the pump source, wherein the controller is configured to control the pump source so that the pump source extinguishes the pulsed laser light in response to the detection signal.
  • 2. The electrodeless laser-driven light source of claim 1 wherein the controller controls the pump source so that it extinguishes the pulsed laser light within a time delay after the detection signal exceeds a threshold level.
  • 3. The electrodeless laser-driven light source of claim 2 wherein the pump laser and the Q-switched laser crystal are configured so that a period between pulses in the pulsed laser light is greater than the time delay.
  • 4. The electrodeless laser-driven light source of claim 2 wherein the pump laser and the Q-switched laser crystal are configured so that a period between pulses in the pulsed laser light is less than the time delay.
  • 5. The electrodeless laser-driven light source of claim 2 wherein the controller is configured so that the time delay is less than one pulse period of the pulsed laser light.
  • 6. The electrodeless laser-driven light source of claim 2 wherein the detection signal generated by the detector represents a power of the plasma light and the threshold level is a desired ratio of the power of the plasma light to an operating power.
  • 7. The electrodeless laser-driven light source of claim 6 wherein the desired ratio is nominally 50%.
  • 8. The electrodeless laser-driven light source of claim 6 wherein the desired ratio is nominally 90%.
  • 9. The electrodeless laser-driven light source of claim 6 wherein the desired ratio falls within a range between 30% and 95%.
  • 10. The electrodeless laser-driven light source of claim 1 wherein the pump laser and the Q-switched laser crystal are configured so that a pulse repetition rate of the pulsed laser light is in a range of 1 kHz to 20 kHz.
  • 11. The electrodeless laser-driven light source of claim 1 wherein the pump laser and the Q-switched laser crystal are configured so that a pulse repetition rate of the pulsed laser light is less than or equal to 1 kHz.
  • 12. The electrodeless laser-driven light source of claim 1 wherein the pump laser and the Q-switched laser crystal are configured so that a pulse energy of the pulsed laser light is in a range of 50 μJoules to 500 μJoules.
  • 13. The electrodeless laser-driven light source of claim 1 wherein the pump laser and the Q-switched laser crystal are configured so that a pulse energy of the pulsed laser light is in a range of 500 μJoules to 5 mJoules.
  • 14. The electrodeless laser-driven light source of claim 1 wherein the pump laser and the Q-switched laser crystal are configured so that a pulse duration of the pulsed laser light is in a range of 0.1 ns to 10 ns.
  • 15. The electrodeless laser-driven light source of claim 1 wherein the laser source is configured so that a power of the CW sustaining light is in a range of 5 W to 50 W.
  • 16. The electrodeless laser-driven light source of claim 1 wherein the laser source is configured so that a power of the CW sustaining light is in a range of 5 W to 1500 W.
  • 17. The electrodeless laser-driven light source of claim 1 wherein the Q-switched laser crystal comprises a gain section and a saturable absorber section.
  • 18. The electrodeless laser-driven light source of claim 1 wherein the Q-switched laser crystal comprises a glass host.
  • 19. The electrodeless laser-driven light source of claim 1 wherein the Q-switched laser crystal comprises an yttrium aluminum garnet host.
  • 20. The electrodeless laser-driven light source of claim 1 wherein the Q-switched laser crystal comprises a spinel host.
  • 21. The electrodeless laser-driven light source of claim 1 wherein the Q-switched laser crystal comprises a chromium dopant.
  • 22. The electrodeless laser-driven light source of claim 1 wherein the Q-switched laser crystal comprises a cobalt dopant.
  • 23. The electrodeless laser-driven light source of claim 1 wherein the Q-switched laser crystal comprises a vanadium dopant.
  • 24. The electrodeless laser-driven light source of claim 1 wherein the Q-switched laser crystal comprises a narrow-band filter.
  • 25. The electrodeless laser-driven light source of claim 24 wherein the narrow-band filter reflects at least some of the plasma light.
  • 26. The electrodeless laser-driven light source of claim 24 wherein the narrow-band filter blocks wavelengths in the xenon spectrum.
  • 27. The electrodeless laser-driven light source of claim 1 wherein the Q-switched laser crystal comprises a coating on one surface.
  • 28. The electrodeless laser-driven light source of claim 1 wherein the gas-filled bulb comprises xenon gas.
  • 29. The electrodeless laser-driven light source of claim 1 wherein the gas-filled bulb is formed in a spherical shape.
  • 30. The electrodeless laser-driven light source of claim 1 wherein a pressure in the gas-filled bulb comprises a pressure in a range of 20 atm to 50 atm.
CROSS REFERENCE TO RELATED APPLICATION

The present application is a continuation of U.S. patent application Ser. No. 18/465,022, filed on Sep. 11, 2023, entitled “Laser-Driven Light Source with Electrodeless Ignition”, which is a continuation of U.S. patent application Ser. No. 18/161,282, filed on Jan. 30, 2023, entitled “Laser-Driven Light Source with Electrodeless Ignition”, now U.S. Pat. No. 11,784,037 issued on Oct. 10, 2023, which is a continuation of U.S. patent application Ser. No. 17/328,433, filed on May 24, 2021, entitled “Laser-Driven Light Source with Electrodeless Ignition”, now U.S. Pat. No. 11,587,781 issued on Feb. 21, 2023. The entire contents of U.S. patent application Ser. No. 18/465,022, and U.S. Pat. Nos. 11,784,037 and 11,587,781 are incorporated herein by reference.

US Referenced Citations (280)
Number Name Date Kind
3054921 Lye Sep 1962 A
3227923 Marrison Jan 1966 A
3418507 Young Dec 1968 A
3427564 Okaya et al. Feb 1969 A
3495118 Richter Feb 1970 A
3502929 Richter Mar 1970 A
3582822 Kamey Jun 1971 A
3619588 Chambers Nov 1971 A
3636395 Banes, Jr. et al. Jan 1972 A
3641389 Leidigh Feb 1972 A
3657588 McRae Apr 1972 A
3731133 McRae et al. May 1973 A
3764466 Dawson Oct 1973 A
3808496 McRae et al. Apr 1974 A
3826996 Jaegle et al. Jul 1974 A
3900803 Silfvast et al. Aug 1975 A
3911318 Spero et al. Oct 1975 A
3949258 Soodak Apr 1976 A
3982201 Rosenkrantz et al. Sep 1976 A
4054812 Lessner et al. Oct 1977 A
4063803 Wright et al. Dec 1977 A
4088966 Samis May 1978 A
4152625 Conrad May 1979 A
4177435 Brown Dec 1979 A
4179037 Chan et al. Dec 1979 A
4179566 Nadelson Dec 1979 A
4263095 Thode Apr 1981 A
4272681 Fill et al. Jun 1981 A
4485333 Goldberg Nov 1984 A
4498029 Yoshizawa et al. Feb 1985 A
4536640 Vukanovic Aug 1985 A
4599540 Roberts Jul 1986 A
4633128 Roberts Dec 1986 A
4646215 Levin et al. Feb 1987 A
4702716 Roberts Oct 1987 A
4724352 Schuda et al. Feb 1988 A
RE32626 Yoshizawa et al. Mar 1988 E
4780608 Cross et al. Oct 1988 A
4785216 Roberts et al. Nov 1988 A
4789788 Cox Dec 1988 A
4866517 Mohizuki et al. Sep 1989 A
4868458 Davenport et al. Sep 1989 A
4872189 Frankel et al. Oct 1989 A
4889605 Asmus et al. Dec 1989 A
4901330 Wolfram et al. Feb 1990 A
4978893 Brannon et al. Dec 1990 A
5052780 Klein Oct 1991 A
5153673 Amirav Oct 1992 A
5299279 Roberts Mar 1994 A
5317618 Nakahara et al. May 1994 A
5334913 Ury et al. Aug 1994 A
5359621 Tsunoda et al. Oct 1994 A
5418420 Roberts May 1995 A
5442184 Palmer et al. Aug 1995 A
5506857 Meinzer Apr 1996 A
5508934 Moslehi et al. Apr 1996 A
5561338 Roberts et al. Oct 1996 A
5672931 Kiss et al. Sep 1997 A
5686996 Fidler et al. Nov 1997 A
5789863 Takahashi et al. Aug 1998 A
5790575 Zamel et al. Aug 1998 A
5801495 Smolka et al. Sep 1998 A
5903088 Sugitani et al. May 1999 A
5905268 Garcia et al. May 1999 A
5923116 Mercer et al. Jul 1999 A
5940182 Lepper, Jr. et al. Aug 1999 A
6005332 Mercer Dec 1999 A
6025916 Quick et al. Feb 2000 A
6061379 Schoen May 2000 A
6074516 Howald et al. Jun 2000 A
6108091 Pecen et al. Aug 2000 A
6129807 Grimbergen et al. Oct 2000 A
6181053 Roberts Jan 2001 B1
6184517 Sawada et al. Feb 2001 B1
6200005 Roberts et al. Mar 2001 B1
6212989 Beyer et al. Apr 2001 B1
6236147 Capobianco May 2001 B1
6265813 Knox et al. Jul 2001 B1
6274970 Capobianco Aug 2001 B1
6275565 Tomie Aug 2001 B1
6281629 Tanaka et al. Aug 2001 B1
6285131 Kiss et al. Sep 2001 B1
6288780 Fairley et al. Sep 2001 B1
6316867 Roberts et al. Nov 2001 B1
6331993 Brown Dec 2001 B1
6339279 Miyamoto et al. Jan 2002 B1
6339280 Miyamoto et al. Jan 2002 B1
6351058 Roberts Feb 2002 B1
6374012 Bergmann et al. Apr 2002 B1
6400067 Manning et al. Jun 2002 B1
6400089 Salvermoser et al. Jun 2002 B1
6414436 Eastlund et al. Jul 2002 B1
6417625 Brooks et al. Jul 2002 B1
6445134 Asmus Sep 2002 B1
6493364 Baumler et al. Dec 2002 B1
6504319 Herter Jan 2003 B2
6504903 Kondo et al. Jan 2003 B1
6532100 Partanen et al. Mar 2003 B1
6541924 Kane et al. Apr 2003 B1
6597087 Roberts et al. Jul 2003 B2
6602104 Roberts Aug 2003 B1
6670758 Beech et al. Dec 2003 B2
6737809 Espiau et al. May 2004 B2
6762849 Rulkens Jul 2004 B1
6768264 Beech et al. Jul 2004 B2
6788404 Lange Sep 2004 B2
6816323 Colin et al. Nov 2004 B2
6821377 Saito et al. Nov 2004 B2
6834984 Tausch et al. Dec 2004 B2
6865255 Richardson Mar 2005 B2
6867419 Tajima Mar 2005 B2
6914919 Watson et al. Jul 2005 B2
6956329 Brooks et al. Oct 2005 B2
6956885 Taylor et al. Oct 2005 B2
6970492 Govorkov et al. Nov 2005 B2
6972421 Melnychuk et al. Dec 2005 B2
7050149 Owa et al. May 2006 B2
7072367 Arisawa et al. Jul 2006 B2
7087914 Akins et al. Aug 2006 B2
7158221 Davis et al. Jan 2007 B2
7164144 Partlo et al. Jan 2007 B2
7176633 Roberts Feb 2007 B1
7274435 Hiura et al. Sep 2007 B2
7307375 Smith et al. Dec 2007 B2
7368741 Melnychuk et al. May 2008 B2
7399981 Cheymol et al. Jul 2008 B2
7427167 Holder et al. Sep 2008 B2
7429818 Chang et al. Sep 2008 B2
7435982 Smith Oct 2008 B2
7439497 Dantus et al. Oct 2008 B2
7439530 Ershov et al. Oct 2008 B2
7456417 Murakami et al. Nov 2008 B2
7567607 Knowles et al. Jul 2009 B2
7598509 Ershov et al. Oct 2009 B2
7632419 Grimgergen et al. Dec 2009 B1
7652430 Delgado Jan 2010 B1
7671349 Bykanov et al. Mar 2010 B2
7679027 Bogatu Mar 2010 B2
7679276 Blondia et al. Mar 2010 B2
7680158 Endo et al. Mar 2010 B2
7705331 Kirk et al. Apr 2010 B1
7773656 Mills Aug 2010 B1
7786455 Smith Aug 2010 B2
7795816 Jennings et al. Sep 2010 B2
7989786 Smith et al. Aug 2011 B2
8143790 Smith Mar 2012 B2
8148900 Kirk et al. Apr 2012 B1
8242671 Blondia et al. Aug 2012 B2
8242695 Sumitomo et al. Aug 2012 B2
8253926 Sumitomo et al. Aug 2012 B2
8309943 Smith et al. Nov 2012 B2
8320424 Bolt et al. Nov 2012 B2
8427067 Espiau et al. Apr 2013 B2
8525138 Smith et al. Sep 2013 B2
8969841 Smith Mar 2015 B2
9048000 Smith Jun 2015 B2
9185786 Smith Nov 2015 B2
9576785 Blondia Feb 2017 B2
9609732 Smith Mar 2017 B2
9678262 Görtz et al. Jun 2017 B2
9741553 Blondia Aug 2017 B2
9748086 Blondia Aug 2017 B2
9922814 Blondia Mar 2018 B2
10008378 Blondia Jun 2018 B2
10057973 Blondia Aug 2018 B2
10078167 Brune et al. Sep 2018 B2
10109473 Blondia et al. Oct 2018 B1
10186414 Blondia Jan 2019 B2
10186416 Blondia Jan 2019 B2
10203247 Brady et al. Feb 2019 B2
10217625 Bezel et al. Feb 2019 B2
10222701 Zhao et al. Mar 2019 B2
10770282 Abramenko et al. Sep 2020 B1
10964523 Gayasov et al. Mar 2021 B1
11587781 Partlow et al. Feb 2023 B2
11637008 Kumar et al. Apr 2023 B1
11784037 Partlow et al. Oct 2023 B2
20010035720 Guthrie et al. Nov 2001 A1
20020021508 Ishihara Feb 2002 A1
20020036820 Merriam et al. Mar 2002 A1
20020044624 Davis et al. Apr 2002 A1
20020044629 Hertz et al. Apr 2002 A1
20020080834 Kusunose Jun 2002 A1
20020172235 Chang et al. Nov 2002 A1
20030006383 Melnychuk et al. Jan 2003 A1
20030034736 Eastlund et al. Feb 2003 A1
20030052609 Eastlund et al. Mar 2003 A1
20030068012 Ahmad et al. Apr 2003 A1
20030086139 Wing So May 2003 A1
20030090902 Kavanagh May 2003 A1
20030147499 Kondo Aug 2003 A1
20030168982 Kim Sep 2003 A1
20030193281 Manning Oct 2003 A1
20030231496 Sato et al. Dec 2003 A1
20040008433 Margeson Jan 2004 A1
20040016894 Wester Jan 2004 A1
20040018647 Jones et al. Jan 2004 A1
20040084406 Kamp et al. May 2004 A1
20040108473 Melnychuk et al. Jun 2004 A1
20040129896 Schmidt et al. Jul 2004 A1
20040134426 Tomoyasu Jul 2004 A1
20040183031 Silverman et al. Sep 2004 A1
20040183038 Hiramoto et al. Sep 2004 A1
20040026512 Otsubo Dec 2004 A1
20040238762 Mizoguchi et al. Dec 2004 A1
20040239894 Shimada Dec 2004 A1
20040245350 Zeng Dec 2004 A1
20040264512 Hartlove et al. Dec 2004 A1
20050057158 Chang et al. Mar 2005 A1
20050167618 Hoshino et al. Aug 2005 A1
20050168148 Allen et al. Aug 2005 A1
20050199829 Partlo et al. Sep 2005 A1
20050205803 Mizoguchi Sep 2005 A1
20050205811 Partlo et al. Sep 2005 A1
20050207454 Starodoumov et al. Sep 2005 A1
20050225739 Hiura Oct 2005 A1
20050243390 Tejnil Nov 2005 A1
20050276285 Huang et al. Dec 2005 A1
20060017387 Smith Jan 2006 A1
20060039435 Cheymol et al. Feb 2006 A1
20060078017 Endo et al. Apr 2006 A1
20060103952 Gouch May 2006 A1
20060131515 Partlo et al. Jun 2006 A1
20060152128 Manning Jul 2006 A1
20060176925 Nakano Aug 2006 A1
20060186356 Imai et al. Aug 2006 A1
20060192152 Ershov et al. Aug 2006 A1
20060202625 Song Sep 2006 A1
20060215712 Ziener et al. Sep 2006 A1
20060219957 Ershov et al. Oct 2006 A1
20060255298 Bykanov et al. Nov 2006 A1
20070001131 Ershov et al. Jan 2007 A1
20070210717 Smith Sep 2007 A1
20070228288 Smith Oct 2007 A1
20070228300 Smith Oct 2007 A1
20070285921 Zulim et al. Dec 2007 A1
20080048133 Bykanov et al. Feb 2008 A1
20080055712 Noelscher et al. Mar 2008 A1
20080059096 Stenstrom et al. Mar 2008 A1
20080099699 Yabuta May 2008 A1
20090032740 Smith et al. Feb 2009 A1
20090091273 Horioka Apr 2009 A1
20090196801 Mills Aug 2009 A1
20090267003 Moriya et al. Oct 2009 A1
20090314967 Moriya et al. Dec 2009 A1
20100164380 Sumitomo Jul 2010 A1
20100172014 Kanade et al. Jul 2010 A1
20100181503 Yanagida et al. Jul 2010 A1
20100253935 Machinnon et al. Oct 2010 A1
20100264820 Sumitomo et al. Oct 2010 A1
20110181191 Smith et al. Jul 2011 A1
20110204265 Smith et al. Aug 2011 A1
20110291566 Bezel et al. Dec 2011 A1
20140117258 Smith May 2014 A1
20140197733 Delgado Jul 2014 A1
20150021500 Smith Jan 2015 A1
20150034838 Bezel Feb 2015 A1
20150131137 Burry et al. May 2015 A1
20150289353 Smith Oct 2015 A1
20160057845 Smith Feb 2016 A1
20160093463 Bhattacharjee et al. Mar 2016 A1
20170135192 Blondia May 2017 A1
20170150590 Chimmalgi et al. May 2017 A1
20170213704 Chen Jul 2017 A1
20190037676 Khodykin et al. Jan 2019 A1
20190045615 Mori et al. Feb 2019 A1
20190053364 Mori et al. Feb 2019 A1
20190075641 Kuritsyn et al. Mar 2019 A1
20190021158 Nozaki Jul 2019 A1
20200012165 Haller Jan 2020 A1
20200051785 Miller et al. Feb 2020 A1
20200393687 Yabu et al. Dec 2020 A1
20210120659 Szilagyi et al. Apr 2021 A1
20210282256 Abramenko et al. Sep 2021 A1
20220229307 Wang et al. Jul 2022 A1
20220375740 Partlow et al. Nov 2022 A1
20230031995 Yoon et al. Feb 2023 A1
20230178357 Partlow et al. Jun 2023 A1
20230268167 Horne et al. Aug 2023 A1
20230420242 Partlow et al. Dec 2023 A1
Foreign Referenced Citations (67)
Number Date Country
1509419 Jun 2004 CN
210533985 May 2020 CN
19910725 Oct 1999 DE
102011113681 Mar 2013 DE
0151188 Nov 1991 EP
1083777 Mar 2001 EP
1313128 May 2011 EP
2534672 Jun 2016 EP
1471215 Mar 1967 FR
2554302 May 1985 FR
2266406 Oct 1993 GB
53-103395 Sep 1978 JP
61-193358 Aug 1986 JP
1-296560 Nov 1989 JP
4-144053 May 1992 JP
05-061397 Mar 1993 JP
5-82087 Apr 1993 JP
H05-82087 Nov 1993 JP
8-299951 Nov 1996 JP
9-288995 Nov 1997 JP
2003-317675 Nov 2003 JP
2004-134166 Apr 2004 JP
2006-010675 Jan 2006 JP
2006-080255 Mar 2006 JP
2006-194925 Jul 2006 JP
2007-506947 Mar 2007 JP
4255662 Apr 2009 JP
2010-087388 Apr 2010 JP
2010-171159 Aug 2010 JP
2011-048285 Mar 2011 JP
2012-018415 Jan 2012 JP
2015-519605 Jul 2015 JP
2015-166757 Sep 2015 JP
2016-138989 Aug 2016 JP
6243845 Dec 2017 JP
10-2005-0003392 Jan 2005 KR
10-2006-0064319 Jun 2006 KR
10-2006-0087004 Aug 2006 KR
10-2008-0108111 Dec 2008 KR
10-2010-0114455 Oct 2010 KR
10-2016-0071231 Jun 2016 KR
10-1639963 Jul 2016 KR
8403294 Jun 1985 NL
2266628 Dec 2005 RU
2278483 Jun 2006 RU
2326463 Jun 2008 RU
2780202 Sep 2022 RU
9410729 May 1994 WO
9811388 Mar 1998 WO
9854611 Dec 1998 WO
9918594 Apr 1999 WO
02087291 Oct 2002 WO
03079391 Sep 2003 WO
2004023061 Mar 2004 WO
2004084592 Sep 2004 WO
2004097520 Nov 2004 WO
2005004555 Jan 2005 WO
2006017119 Feb 2006 WO
2007002170 Jan 2007 WO
2010093903 Aug 2010 WO
2018136683 Jul 2018 WO
2019023150 Jan 2019 WO
2019023303 Jan 2019 WO
2022159352 Jul 2022 WO
2022251000 Dec 2022 WO
2023158909 Aug 2023 WO
2023192696 Oct 2023 WO
Non-Patent Literature Citations (328)
Entry
US 8,471,227 B2, 06/2013, Kakizaki (withdrawn)
User Manual: Cyberlight, Cyberlight Cx, Cyberlight Sv (VERSION 2.0), High End Systems, Inc., (1996).
Ushio Super-High Pressure Mercury Lamps, including USH-102D, USH-102DH, USH-205DP, USH-2055, USH-206D/M4. USH-250D, USH-250BY, USH-350DS, USH-351DS, USH-350DP, USH-450G5, USH-450GL, USH-500BY,USH-500MB, USH-502MB, USH-500T, USH-505MC,USH-5085, USH-508SA, USH-5095, USH-1000DW,USH-1000MC, USH-1000KS, USH-1002DW, Ushio.
Vadla et al., “Resonantly Laser Induced Plasmas in Gases: The Role of Energy Pooling and Exothermic Collisions in Plasma Breakdown and Heating”, Spectrochimica Acta Part B, vol. 65, 2010, pp. 33-45.
Vampola, “P78-2 Engineering Overview”, Defence Technical Information Centre, 1981, pp. 1-36.
Vukanovic et al., “A New Type of D.C. Arc as Spectrochemical Light Source”, Spectrochimica Acta, vol. 298, 1974, pp. 33-36.
Wang, “Self-Assembled Indium Arsenide Quantum-Dash Lasers of Indium Phosphide Substrates”, Electrical and Computer Engineering, 2002, pp. vi-150.
Waynant et al., “Electro-Optics Handbook”, Eds., 20002, pp. 1-1000.
Webb et al., “Handbook of Laser Technology and Applications”, Applications, vol. III, 2004, pp. 1587-1611.
Wei, “Transparent Ceramic Lamp Envelope Materials”, J. Phys. D: Appl. Phys., vol. 38, 2005, pp. 3057-3065.
Weinrotter et al., “Application of Laser Ignition to Hydrogen-Air Mixtures at High Pressures”, International Journal of Hydrogen Energy, vol. 30, 2005, pp. 319-326.
Weinrotter et al., “Laser Ignition of Engines”, Laser Physics, vol. 15, No. 7, 2005, pp. 947-953.
Wiehle et al., “Dynamics of Strong-Field Above-Threshold Ionization of Argon: Comparison Between Experiment and Theory”, Physical Review A, vol. 67, 2003, pp. 063405-1-063405-7.
Wieman et al., “Using Diode Lasers for Atomic Physics”, Rev. Sci. Instrum., vol. 62, No. 1, 1991, pp. 1-20.
Wilbers et al., “The Continuum Emission of an Arc Plasma,” J. Ouant. Spectrosc. Radiat. Transfer, vol. 45, No. 1, 1991, pp. 1-10.
Wilbers et al., “The VUV Emissivity of a High-Pressure Cascade Argon Arc from 125 to 200 nm,” J. Ouant. Spectrosc. Radiat. Transfer, vol. 46, 1991, pp. 299-308.
Winter et al., “Experimental and Theoretical Investigations of a Helium-Xenon Discharge in Spot Mode”, 28th ICGQP, 2007 pp. 1979-1982.
Wood, “Atomic Processes: Bound-bound transitions (Einstein coefficients)”, available at http://www-star.st-and.ac.uk-kw25/teaching/nebulae/lecture06_einstein.pdf, 2014, pp. 1-10.
World Record Powers Achieved in Single-Mode Fiber Lasers—Powers Scalable to IkW and Beyond, Southampton Photonics, Inc., 2003, pp. 1-2.
Wroblewski et al., “An Experimental Investigation of the Continuous Optical Discharge”, Journal of Physique, 1979, pp. 733-734.
Wu et al., “Extreme Ultraviolet Lithography: Towards the Next Generation of Integrated Circuits”, vol. 7, 2009, pp. 1-4.
Xenakis et al., “Laser-plasma X-ray Generation Using an Injection-mode-locked XeCI Excimer Laser”, J. Appl. Phys., vol. 71, No. 1, 1992, pp. 85-93.
Xu et al., “Wavelength- and Time-Resolved Investigation of Laser-Induced Plasmas as a Continuum Source”, Applied Spectroscopy, vol. 47, No. 8, 1993, pp. 1134-1139.
Yamamda et al., “Ionization Mechanism of Cesium Plasma Produced by Irradiation of Dye Laser”, 1992,Jpn. J. Appl. Phys. vol. 31, pp. 377-380.
Swiderski et al., “Q-switched Nd-doped double-clad fiber laser”, Opto Electronics Review, vol. 13, No. 3, 2005, pp. 187-191.
International Search Report and Written Opinion received for PCT Application Serial No. PCT/US2022/029536 dated Sep. 7, 2022, 8 pages.
Sereda et al., “High-power IR Lasers Operating on Xe I Transitions”, Quantum Electron, vol. 23, No. 6, 1993, pp. 459-480.
International Preliminary Report on Patentability received for corresponding PCT Application No. PCT/US2022/029536 mailed on Dec. 7, 2023, 5 pages.
Abe et al., “KrF Laser Driven Xenon Plasma Light Source of a Small Field Exposure Tool”, Proc. of SPIE, vol. 6151, 2006, pp. 61513T-1-61513T-5.
Agrawal et al., “Infrared and Visible Semiconductor Lasers”, 1993, pp. xiii-616.
Agrawal et al., “Semiconductor Lasers”, Second edition, 1993, p. 547.
Ahmed et al., “Laser Optogalvanic Spectroscopic Studies of Xenon”, J. Phys. B: At. Mol. Opt. Phys. 31, 1998, pp. 4017-4028.
Aitoumeziane et al., “Theoretical and Numerical Study of the Interaction of a Nanosecond Laser Pulse with a Copper Target for Laser-Induced Breakdown Spectroscopy Applications”, J. Opt. Soc. Am. B, vol. 31, No. 1, 2014, pp. 53-61.
Al-Muhanna et al., High-Power (>10 W) Continuous-Wave Operation from 100-um-Aperture 0.97-um-emitting Al-Free Diode Lasers, Applied Physics Letters, vol. 73, No. 9, Aug. 31, 1998, pp. 1182-1184.
Angel, “LIBS Using Dual-Laser Pulses”, 2002, p. 14.
Apter, “High-power Diode Lasers Offer Efficient Answer, Product Guide”, 2005, pp. 1-3.
Aragon et al., “Determination of Carbon Content in Molten Steel Using Laser-Induced Breakdown Spectroscopy”, 1993, pp. 306-608.
Arieli, Excitation of Gas Laser by Optical Pumping, Chapter 6.1, Gas Laser, 2006, p. 2b.
Arp et al., “Argon Mini-Arc Meets its Match: Use of a Laser-Driven Plasma Source in Ultraviolet-Detector Calibrations”,Applied Optics vol. 53, Issue 6 , 2014, pp. 1089-1093.
Arp et al., “Feasibility of Generating a Useful Laser-Induced Breakdown Spectroscopy Plasma on Rocks at High Pressure: reliminary Study for a Venus Mission”, Spectrochimica Acta Part B 59, 2004, pp. 987-999.
Arzuov et al., Self-Maintenance of a Continuous Optical Discharge in Gases Near Solid Targets, Soy. J. Quant. Electron., vol. 5, No. 5, 1975, pp. 523-525.
Azuma et al., Debris from Tape-Target Irradiated with Pulsed YAG Laser, Applied Surface Science, 2002, pp. 224-228.
8 11 3mmaxoe, 011THLIECKHE PA3PFIRb1,110fIREPK4BAEMbIE I4311YLIEHMEM J1A3EPOB Efill)KHEI-0 ilk-.I4-EIA11A3OHA Ommixo-xmknyeckasi Kmue-ra B ra3ouoii gmuamme, www.chemphys.edu.ru/pdf/2014-11-29-001.pdf.
B.B. Kostin, I4311YLIEH14EF1J1A3Mbl, HAIPETOC4 KOPOTKI4MI4 11A3EPHb1MI4 14M11YIIbCAM 14 23(2) 014314KA EffIA3Mbl 118 (1997).
B.T. Apxpinkmu and A. K. Dona HEIII4HEOHAFI 011T14KA 14 11PEOBPASOBAHHE CBETA B IA3AX 153(3) YalEXI4IM3144ECK14X HAYK 423 (1987).
Babucke et al., “On the Energy Balance in the Core of Electrode-Stabilized High-Pressure Mercury Discharges”, J. Phys. D: Appl. Phys. vol. 24, 1991, pp. 1316-1321.
Bachmann, “Goals and status of the German national research initiative BRIOLAS (brilliant diode lasers)”, Proc. of SPIE vol. 6456, 2007, 645608-1.
Bachmann, “Industrial Applications of High Power Diode Lasers in Materials Processing”, Applied Surface Science, 208-209, 2003, pp. 125-136.
Baer, “Plasma Diagnostics With Semiconductor Lasers Using Fluorescence and Absorption Spectroscopy”, Stanford University ProQuest Dissertations Publishing, 1993, pp. 1-194.
Ball, “Raman Spectroscopy”, vol. 17, No. 2, 2002, pp. 50-52.
Ballman et al., “Synthetic Quartz with High Ultraviolet Transmission”, Applied Optics, vol. 7, No. 7, 1968, pp. 1387-1390.
Barnes et al., “Argon Arc Lamps”, Applied Optics, vol. 24, No. 13, 1985, pp. 1947-1949.
Barnes et al., “High Power Diode Laser Cladding”, Journal of Materials Processing Technology, vol. 138, 2003, pp. 411-416.
Bartz et al., “Optical Reflectivity Measurements Using a Laser Plasma Light Source”, Appl. Phys. Lett. Vol. 55, No. 19, 1989, pp. 1955-1957.
Bataller et al., “Nanosecond High-Power Dense Microplasma Switch for Visible Light”, Applied Physics Letters, vol. 105, 2014, pp. 1-5.
Bauder, Radiation from High-Pressure Plasmas, Journal of Applied Physics, vol. 39. No. 1, 1968, pp. 148-152.
Beam Samplers; UV Fused Silica Beam Samplers, (AR Coating: 250-420 nm) (AR Coating: 350-700 nm) (AR Coating: 550-1050 nm) (AR Coating: 1050-1700 nm), 3 pages.
Beck, “Simple Pulse Generator for Pulsing Xenon Arcs with High Repetition Rate,” Rev. Sci. Instrum., vol. 45, No. 2, Feb. 1974, pp. 318-319.
Belasri et al., “Electrical Approach of Homogenous High Pressure NelXe/CHI Dielectric Barrier Discharge for XeCI (308 nm) Lamp”, Plasma Chem Plasma Process, vol. 31, 2011, pp. 787-798.
Bloch et al., “Field Test of a Novel Microlaser-Based Probe for in Situ Fluorescence Sensing of Soil Contamination”, Applied Spectroscopy, vol. 52, No. 10, 1998, pp. 1299-1304.
Bogaerts et al., “Gas Discharge Plasmas and their Applications”, Spectrochimica Acta Part B 57, 2001, pp. 609-658.
Bolshov et al., “Investigation of the Dynamic of an Expanding Laser Plume by a Shadowgraphic Technique”, Spectrochimica Acta Part B 63, 2008, pp. 324-331.
Borghese et al., “Time-Resolved Spectral and Spatial Description of Laser-Induced Breakdown in Air as a Pulsed, Bright, and Broadband Ultraviolet-Visible Light Source”, Applied Optics, vol. 37, No. 18, Jun. 20, 1998, pp. 3977-3983.
Brauch et al., “High-Power Diode Lasers for Direct Applications”, Topics Appl. Phys., vol. 78, 1000, pp. 303-368.
Breton et al., “Vacuum-UV Radiation of Laser-Produced Plasmas”, Journal of the Optical Society of America, vol. 63, No. 10, 1973, pp. 1225-1232.
Bridges et al., “Investigation of a Laser-Produced Plasma VUV Light Source”, Applied Optics, vol. 25, No. 13, Jul. 1, 1986, pp. 2208-2214.
Bridges, “Characteristics of an Opto-Galvanic Effect in Cesium and Other Gas Discharge Plasmas”, J. Opt. Soc. Am., vol. 68, No. 3, Mar. 1978, pp. 352-360.
Bussiahn, R., et al., “Experimental and theoretical investigations of a low-pressure He—Xe discharge for lighting purpose,” Journal of Applied Physics, vol. 95, No. 9, May 1, 2004, pp. 4627-4634.
Byer, “Laser-Produced Plasmas: A Compact Soft X-Ray Source with High Peak Brightness”, Defence Technical Information Centre, 1989, pp. 1-26.
C10T/C6 Lightshield System Parts Listing, Heraeus Noblelight America LLC, 2015, pp. 1-8.
Cann, “Light Sources in the 0.15-20-μ Spectral Range”, Applied Optics, vol. 8. No. 8, 1969, pp. 1645-1661.
Carlhoff et al., “Continuous Optical Discharges at Very High Pressure,” Physica 103C, 1981, pp. 439-447.
Carlhoff et al., “High Pressure Optical Discharges”, Journal of Physics, 1979, pp. 757-758.
Cedolin et al., “Laser-Induced Fluorescence Measurements of Resonance Broadening in Xenon”, Physical Review A, vol. 54, No. 1, 2006, pp. 335-342.
Cedolin, “Laser-Induced Fluorescence Diagnostics of Xenon Plasmas”, 1997, pp. 1-96.
Cermax lamps, including models LX300F, LX1000CF, EX300-10F, EX500-13F, EX900C-10F, EX900C-13F,EX1000C-13F, LX125F, LX175F, LX500CF, EX125-10F, EX175-10F, EX500-10F,EX1000C-10F . EX900-10F;PerkinElmer Optoelectronics.
Cesar et al., “High-power fibre lasers”, Nature Photonics, vol. 7, 2013, pp. 861-867.
Chang et al., “Fiber Laser Driven EUV Generation”, Conference on Lasers and Electro-Optics, 2005, pp. 2200-2202.
Mobarhan, “Test and Characterization of Laser Diodes: Determination of Principal Parameters”, 1999, pp. 1-7.
Moody, “Maintenance of a Gas Breakdown in Argon Using 10.6-μ cw Radiation”, Journal of Applied Physics, vol. 46, No. 6, Jun. 1975, pp. 2475-2482.
Mora, “Theoretical Model of Absorption of Laser Light by a Plasma”, Phys. Fluids, vol. 25, No. 6, 1982, pp. 1051-1056.
Mordovanakis et al., “Demonstration of Fiber-laser-produced Plasma Source and Application to Efficient Extreme UV Light Generation”, Optics Letter, vol. 31, No. 17, 2006, pp. 2517-2519.
Mosier-Boss et al., “Detection of Lead Derived from Automotive Scrap Residue Using a Direct Push Fiber-Optic Laser-Induced Breakdown Spectroscopy Metal Sensor”, Applied Spectroscopy, vol. 59, No. 12, 2005, pp. 1445-1456.
Mosier-Boss et al., “Field Demonstrations of a Direct Push FO-LIBS Metal Sensor”, Environ. Sci. Technol., vol. 36, 2002, pp. 3968-3976.
Motomura et al., “Temporal VUV Emission Characteristics Related to Generations and Losses of Metastable Atoms in Xenon Pulsed Barrier Discharge”, J. Light & Vis. Env. vol.30, No. 2, 2006, pp. 81-86.
Moulton, “Tunable Solid-State Lasers”, Proceedings of the IEEE, vol. 80, No. 3, 1992, pp. 348-364.
Muller et al., “Theoretical Model for a Continuous Optical Discharge”, Physica, 112C, 1982, pp. 259-270.
Nagano et al., “Present Status of Laser-Produced Plasma EUV Light Source”, Proc. of SPIE, vol. 7636, 2010, pp. 76363C-1-76363C-9.
Nakar et al.. “Radiometric Characterization of Ultrahigh Radiance Xenon Short-Arc Discharge Lamps, Ben-Gurion University”, Applied Optics, vol. 47, No. 2, Jan. 9, 2008.
Neukum, “Vom Halbleiterchip zum Laserwerkzeug”, 2007, pp. 18-20.
Nikitin et al., “Guiding of Intense Femtosecond Pulses in Preformed Plasma Channels”, Optics Letter, vol. 22, No. 23, 1997, pp. 1787-1789.
Norimatsu et al., “Cryostat to Provide a Solid Deuterium Layer in a Plastic Shell for the Gekko XII Glass Laser System”, Review of Scientific Instruments, vol. 63, No. 6,1992, pp. 3378-3383.
Zajac et al., “10 W cw Nd-Doped Double-clad Fiber Laser Operating at 1.06 μm”, Proceedings of SPIE vol. 5036, 2003, pp. 135-138.
OEM Compact Fiber Laser module 1090nm 10-20W CW/M With GTWave Technology, SPI Lasers LLC.
Oettinger et al., Plasma Ionization Enhancement by Laser Line Radiation, AIAA Journal, vol. 8, No. 5, 1970, pp. 880-885.
Yusim et al., “100 Watt, single-mode, CW, Linearly Polarized All-fiber Format 1.56um Laser with Suppression of Parasitic Lasing Effects”, Proceedings of SPIE, vol. 5709, 2005, pp. 69-77.
Yoshizawa et al., “Disk-shaped Vacuum Ultraviolet Light Source Driven by Microwave Discharge for Photoexcited Processes”, Appl. Physc. Lett., vol. 559, 1991, pp. 1678-1680.
Yoshino et al., “Absorption Spectrum of Xenon in the Vacuum-Ultraviolet Region”,J. Opt. Soc. Am. B/vol. 2, No. 8, 1985, pp. 1268-1274.
Yamanaka, “Inertial Confinement Fusion Research at ILE Osaka”, Nuclear Fusion, vol. 25, No. 9, 1985, pp. 1343-1349.
Yamakoshi et al., “Extreme-Ultraviolet Laser Photo-Pumped by a Self-Healing Hg Target”, SPIE, Vo .. 2015, 1994, pp. 227-231.
Orth et al., “High-Resolution Spectra of Laser Plasma Light Sources in the Normal Incidence XUV Region”, Applied Optics, vol. 25, No. 13, 1986, pp. 2215-2217.
OSRAM Opto Semiconductors Announces New Solutions for Laser Applications; New Offerings Provide High Output and Enhanced Reliability, Business Wire, Jun. 28, 2005, pp. 1-3.
Oxford Dictionary of Astronomy, definition of bound-bound transition, 2003, p. 59.
Pankertet al., “EUV Sources for the Alpha-Tools”, Proc. of SPIE, vol. 6151, 2006, pp. 1-9.
Pappas et al., “Formation of a Cesium Plasma by Continuous-Wave Resonance Excitation”, Applied Spectroscopy, vol. 54, No. 8, 2000, pp. 1245-1249.
Parker, “McGraw-Hill Dictionary of Scientific and Technical Terms”,5th Edition, 1994, p. 561.
Patel et al., “The Suitability of Sapphire for Laser Windows”,Meas. Sci. Technol., vol. 10, 1999, pp. 146-151.
Pebler et al., “Stabilizing the Radiant Flux of a Xenon Arc Lamp”, Applied Optice, vol. 20, No. 23, 1981, pp. 4059-4061.
Perry, “Solar Thermal Propulsion: An Investigation of Solar Radiation Absorption In A Working Fluid”, 1984 pp. 1-70.
Petring et al., “High Power Diode Lasers”, Technology and Applications, 2007, pp. 285-533.
Phillip, “Optical Properties of Non-Crystalline Si, SiO, SiOx and SiO2”, J. Phys. Chem, Solids, vol. 32, 1971, pp. 1935-1945.
Phillip, “Optical Transitions in Crystalline and Fused Quartz”, Solid State Communications vol. 4, 1966, pp. 73-75.
Phillips et al., “Characterization and Stabilization of Fiber-Coupled Laser Diode Arrays”, Review of Scientific Instruments, vol. 70, No. 7, 1999, pp. 2905-2909.
Plyler et al., “Precise Measurement of Wavelengths in Infrared Spectra”, Journal of Research of the National Bureau of Standards, vol. 55, No. 5, 1955, pp. 279-284.
Polijanczuk et al., “Semiconductor Lasers for Microsoldering”, 1991, p. 6/1-6/4.
Prabhu et al., “High-Power CW Raman Fiber Laser Using Phosphosilicate Fiber Pumped by Yb-doped Double-clad Fiber Laser”, IEE Colloquium on Advances in Interconnection Technology, 2001, pp. 482-485.
Raizer, “Continuous Optical Discharge: Generation and Support of Dense Low-Temperature Plasma by Laser Irradiation”, 1996, pp. 87-94.
Raizer, “Gas Discharge Physics”, 1991, pp. 1-449.
Raizer, “Optical Discharges,” Sov. Phys. Usp., vol. 23, No. 11, 1980, pp. 789-806.
Rhemet, “Xenon Lamps”, IEE Proc., vol. 127, Pt. A, No. 3. 1980, pp. 190-195.
Richardson et al., “High Conversion Efficiency Mass-Limited Sn-Based Laser Plasma Source for Extreme Ultraviolet Lithography”, J. Vac. Sci. Technol. B., vol. 22, No. 2, 2004, pp. 785-790.
Rietdorf et al., “Special Optical Elements”, J. (eds) Handbook of Biological Confocal Microscopy, 2006, pp. 43-58.
Rockstroh et al., “Spectroscopic Studies of Plasma During CW Laser Materials Interaction”, J. Appl. Phys., vol. 61, No. 3, 1987, pp. 917-922.
Roth et al., “Directly Diode-laser-pumped Ti:sapphire laser”, Optics Letters, vol. 34, No. 21, 2009, pp. 3334-3336.
Sacchi, “Laser-Induced Electric Breakdown in Water”, J. Opt. Soc. Am. B, vol. 28, No. 2, 1991, pp. 337-345.
Sakamoto et al., “120W CW Output Power from Monolithic AlGaAs (800nm) Laser Diode Array Mounted on Diamond Fleatsink”, Electronic Letter, vol. 28, No. 2, 1992, pp. 197-199.
Saloman, “Energy Levels and Observed Spectral Lines of Xenon, Xe(I) through Xe(LIV)”, J. Phys. Chem. Ref. Data, vol. 33, No. 3, 2004, pp. 765-921.
Saraswat et al., “Single Wafer Rapid Thermal Multiprocessing”, Mat. Res. Soc. Symp. Proc. vol. 146, 1989, pp. 3-13.
Ballard et al., “High-Power, Laser-Produced-Plasma EUV Source”,Proc. SPIE, vol. 4688, 2002, pp. 302-309.
Chen et al., “High-temperature Operation of Periodic Index Separate Confinement Heterostructure Quantum Well Laser”, Apr. Phys. Lett., vol. 59, No. 22, 1991, pp. 2784-2786.
Coffey. “Fiber Lasers Achieve World-Record Powers”. 2003, pp. 13-14.
Coherent, “Conduction-Cooled Bar Packages (CCPs), 965-985 nm”, 2015, pp. 1-4.
Cohn et al., “Magnetic-Field-Dependent Breakdown of CO2-Laser-Produced Plasma”, Appl. Phys. Lett., vol. 20, No. 6, 1972, pp. 225-227.
Cooley et al., “Fundamentals of Discharge Initiation in Gas-Fed Pulsed Plasma Thrusters”, The 29th International Electric Propulsion Conference, Princeton University, 2005, pp. 1-11.
Cooper, “Spectroscopic Identification of Water-Oxygen and Water-Hydroxyl Complexes and their Importance to lcy Duter Solar System Bodies”, Chemistry School of Biomedical and Chemical Sciences, 2004, pp. 1-116.
Cremers et al., “Evaluation of the Continuous Optical No. 4, 1985, pp. 665-679. Discharge for Spectrochemical Analysis,” Spectrochimica Acta, vol. 40B, No. 4, 1985, pp. 665-679.
Cross et al., “High Kinetic Energy (1-10eV) Laser Sustained Neutral Atom Beam Source”, Nuclear Instruments and Methods in Physics Research B13, 198, pp. 658-662.
Cu-Nguyen et al., “Tunable Confocal Hyperspectral Imaging System”, Optical MEMS and Nanophotonics, 2013, pp. 9-10.
Cu-Nguyen et al., “Tunable Hyperchromatic Lens System for Confocal Hyperspectral Sensing”, Optics Express, vol. 21, No. 13, 2013, pp. 27611-27621.
Daily et al., “Two-Photon Photoionization of the Ca 4s3d(1)D(2) Level in an Optical Dipole Trap”, Physical Review A, vol. 71. 2005, pp. 043406-1-343406-5.
Davis, “Lasers and Electra-Optics: Fundamentals and Engineering”, 1996, pp. 1-35.
De Jong et al., “A Pulsed Arc-Glow Hollow Cathode Lamp”, Spectroehimlea Acta, vol. 29B, 1974, pp. 179-190.
Demtroder, “Laser Spectroscopy: Basic Concepts and Instrumentation”, Second Enlarged Edition, 1982, pp. 395-398.
Derra et al., “UHP Lamp Systems for Projection Applications”, J. Phys. D: Appl. Phys. vol. 38, 2005, pp. 2995-3010.
DET25K-GaP Detector, 150-550 nm, 1 ns Rise Time, 4.8 mm2, 8-32 Taps, Thorlabs, 2005, p. 1.
Digonnet, “Rare-Earth-Doped Fiber Lasers and Amplifiers”, Optical Engineering, 2001, pp. 144-170.
Diwakar et al., “Role of Laser Pre-Pulse Wavelength and Inter-Pulse Delay on Signal Enhancement in Collinear Double-Pulse LaserIinduced Breakdown Spectroscopy”, Spectrochimia Acta, Part B, 2013, pp. 65-73.
Dorsch et al., “Performance and Lifetime of High-Power Diode Lasers and Diode Laser Systems”, Proc. SPIE, vol. 3628, 1999, pp. 56-63.
Dorsch et al., 2 KW cw Fiber-coupled Diode Laser System, Proceedings of SPIE vol. 3889, 2000, pp. 45-53.
Durfee III et al., “Development of a Plasma Waveguide for High-Intensity Laser Pulses”, Physical Review E, vol. 51, No. 3, 1995, pp. 2368-2389.
Dusterer et al., “Optimization of EUVRradiation Yield from Laser-Produced Plasma”, Appl. Phys., B-73, 2001, pp. 693-698.
Eckstrom et al., “Microwave Interactions With Plasmas”, IEEE Trans. Plasma Sci. vol. 18, 1992, pp. 1-9 with appendixes.
Edmund Optics, Lens UV-SCX 25MM DIA x 25MM FL Uncoated (Drawing), p. 1.
Eletskii et al., “Formation kinetics and parameters of a photoresonant plasma”, Soy. Phys. JETP, vol. 67, No. 5, 1988, pp. 920-924.
Emmett et al., “Direct Measurement of Xenon Flashtube Opacity”, Journal of Applied Physics, vol. 35, No. 9, 1964, pp. 2601-2604.
Endo et al., “Laser Produced EUV Light Source Development for HVM”, SPIE Advanced Lithography, 2007, pp. 1-25.
Erskine et al., “Measuring Opacity of Shock Generated Argon Plasmas” ,J. Quart Spectro. Radial Transfer, vol. 51, No. 12, 1994, pp. 97-100.
F10T/F10T2 and F6 Lightshield Systems Parts Listing, Heraeus Noblelight America LLC, 2015, pp. 1-12.
F300S/F300SQ UV Lamp System Parts Listing, Heraeus Noblelight America LLC, 2015, pp. 1-26.
Feng et al., “A stigmatic Ultraviolet-Visible Monochromator for Use with a High Brightness Laser Driven Plasma Light Source”, Review of Scientific Instruments, vol. 84, 2013, pp. 1-6.
Fiedorowicz et al., “X-Ray Emission form Laser-Irradiated Gas Puff Targets,” Appl. Phys. Lett., vol. 62, No. 22, May 31, 1993, pp. 2778-2780.
Fomenkov et al., “Laser Produced Plasma Light Source for EUVL”,Cymer Inc., 17075 Thommint Court, San Diego, CA 92127, USA, 2011, pp. 1-6.
Franzen, “Continuous Laser-Sustained Plasmas”, 1973, J. Appl. Phys., vol. 44, pp. 1727-1732.
Franzen, “CW Gas Breakdown in Argon Using 10.6-μm Laser Radiation,” Appl. Phys. Lett., vol. 21, No. 2, Jul. 15, 1972, pp. 62-64.
Frey et al., “Spectroscopy and kinetics of the ionic cesium flouride excimer excited by a Laser-Produced Plasma”, Joumal of the Optical Society of America B, vol. 6, No. 8, 1989, pp. 1529-1535.
Fujimoto et al., “High Power InGaAs/AlGaAs laser Diodes with Decoupled Confinement Heterostructure”, SPIE vol. 3628, 1999, pp. 38-45.
Galvanauskas, “Fiber laser based EUV lithography sources”, Panel discussion presentation at the SEMATECH EUV Source Workshop (2007).
Geisler et al., “Spectrometer System Using a Modular Echelle Spectrograph and a Laser-Driven Continuum Source for Simultaneous Multi-Element Determination by Graphite Fumace Absorption Spectrometry”, Spectrochimica Acta Part B, vol. 107, 2015, pp. 11-16.
Generalov et al., “Experimental Investigation of a Continuous 1972, pp. 763-769. Optical Discharge,” Soviet Physics JETP, vol. 34, No. 4, Apr. 1972, pp. 763-769.
Gentile et al., “Oxidative Decontamination of Tritiated Materials Employing Ozone Gas”, PPPL, 2002, pp. 1-9.
Gentile et al., “Tritium Decontamination of TFTR D-T Graphite Tiles Employing Ultra Violet Light and a Nd:YAG Laser”, Japan Atomic Energy Research Institute, 1999, p. 321-322.
George et al., “13.5 nm EUV Generation from Tin-doped Droplets Using a Fiber Laser”, Optics Express, vol. 15, No. 25, 2007, pp. 16348-16356.
Girard et al., “Generating Conditions of a Laser-Sustained Argon Plasma Jet”, J. Phys. D: Appl. Phys., vol. 26, 1993, pp. 1382-1393.
Glangetas, “New Design for a Microwave Discharge Lamp”, Rev. Sci. Instrum., vol. 51, No. 3, 1980, pp. 390-391.
Griem, “Plasma Spectroscopy”, 1964, pp. 172-176.
Gullikson et al., “A Soft X-Ray/EUV Reflectometer Based on a Laser Produced Plasma Source”, Journal: Journal of X-Ray Science and Technology, vol. 3, No. 4, 1992, pp. 283-299.
Gwyn, “EVU Lithography Update: The timeline puts the screws to extreme ultraviolet lithography, but engineers rise to the challenge”, SPIE, 2002, pp. 1-4.
Hadal et al., “Influence of Ambient Gas on the Temperature and Density of Laser Produced Carbon Plasma”, Appl. Phys. Lett. Vol. 72, No. 2, 1998, pp. 167-169.
Schohl et al., “Absolute Detection of Metastable Rare Gas Atoms by a CW Laser Photoionization Method”, Z. Phys. D—Atoms, Molecules and Clusters, vol. 21, 1991, pp. 25-39.
Jin et al., New Laser Plasma Source for Extreme-Ultraviolet, 1995, pp. 2256-2258.
Shaw et al., “Preliminary Design of Laser-Induced Breakdown Spectroscopy for Proto-Material Plasma Exposure Experiment”, Review of Scientific Instruments, vol. 85, 2014, pp. 11D806-1-11D806-3.
Shen et al., “Highly Efficient Er, Yb-Doped Fiber Laser with 188W Free-Running and >100W Tunable Output Power”, Optics Express, vol. 13, No. 13, 2005, pp. 4916-4921.
Shigeyoshi et al., “Near Infrared Absorptions of Neon, Argon, Krypton, and Xenon Excited Diatomic Molecules”, J. Chem. Phys., vol. 68, 1978, pp. 7595-4603.
Shimada et al., “Characterization of Extreme Ultraviolet Emission from Laser-Produced Spherical Tin Plasm Generated with Multiple Laser Beams”, Applied Physics Letters, vol. 86, 2005, pp. 051501-1-051501-3.
Shirakawa et al., “CW 7-W, 900-nm-wide Supercontinuum Source by Phosphosilicate Fiber Raman Laser and Highnonlinear Fiber”, Proceedings of SPIE, vol. 5709, 2005, pp. 199-205.
Sidawi, “Fiber Lasers Gain Power”, www.rdmag.com, 2003, p. 26.
Silfvast et al., “Comparison of Radiation from Laser-Produced and DC-Heated Plasmas in Xenon”, Applied Physics Letters, vol. 25, No. 5, 1974, pp. 274-277.
Silfvast, Laser Fundamentals, Schhol of Optics, 2004, pp. 1-6, pp. 199-222 & 565-568.
Skenderovic et al., “Laser-ignited glow discharge in lithium vapor”, Physical Review A, vol. 62, 2000, pp. 052707-1-052707-7.
Smith, “Gas-Breakdown Dependence on Beam Size and Pulse Duration with 10.6-μ Wavelength Radiation”, Applied Physics Letters, vol. 19, No. 10, 1971, pp. 405-408.
Snyder et al., “Laser-Induced Breakdown Spectroscopy of High-Pressure Bulk Aqueous Solutions”, Applied Spectroscopy, vol. 60, No. 7, 2006, pp. 786-790.
Sabota et al., “The Role of Metastables in the Formation of an Argon Discharge in a Two-Pin Geometry”, IEEE Transactions on Plasma Science, vol. 38, No. 9, 2010, pp. 2289-2299.
Song et al., “Mechanisms of Absorption in Pulsed Excimer Laser-Induced Plasma”, Appl. Phys. A, vol. 65, 1997, pp. 477-485.
Stamm, “Extreme Ultraviolet Light Sources for use in Semiconductor Lithography—State of the Art and Future Development”, J. Phys. D: Appl. Phys., vol. 37, 2004, pp. 3244-3253.
Stulen et al., “Developing A Soft X-Ray Projection Lithography Tool”, AT & T Technical Journal, 1991, pp. 37-48.
Su et al., “Note: A Transient Absorption Spectrometer Using an Ultra Bright Laser-Driven Light Source”, Review of Scientific Instruments, vol. 84, 2013, pp. 086106-1-386106-3.
Sundvold et al., “Optical Firing System”, Proc. of SPIE, vol. 5871, 2005, pp. 587104-1-587104-10.
Super-Quiet Xenon Lamp Super-Quiet Mercury-Xenon Lamp, Hamamatsu Product Information, Nov. 2005, 16 pages.
Surzhikov, “Numerical Simulation of Subsonic Gasdynamical Instabilities Near Heat Release Regions”, AIAA, 1996, pp. 1-11.
Generalov et al., “Continuous Optical Discharge,” ZhETF Pis. Red. 11, No. 9, May 5, 1970, pp. 302-304.
Szymanski et al., “Nonstationary Laser-Sustained Plasma”, Joumal of Applied Physics, vol. 69, No. 6, 1990, pp. 3480-3484.
Szymanski et al., “Spectroscopic Study of a Supersonic Jet of Laser-Heated Argon Plasma”, J. Phys. D: Appl. Phys., vol. 30, 1997, pp. 998-1006.
Takahashi et al., “Numerical Analysis of Ar(2) Excimer Production in Laser-Produced Plasmas”, Journal of Applied Physics, 1998, pp. 390-393.
Takahashi et al., “Ar(2) Excimer Emission from a Laser-Heated Plasma in a High-Pressure Argon Gas”, Applied Physics Letters, vol. 77, No. 5, 2000, pp. 4115-4117.
Tam et al., “Plasma Production In a Cs Vapor by a Weak cw Laser Beam at 6010 A, Optics Communications”, vol. 21, No. 3, 1977, pp. 403-407.
Tam, “Dynamic Response of a cw Laser-produced Cs Plasma to Laser Modulations”, Appl. Phys. Lett., vol. 35, No. 9, 1979, pp. 683-685.
Tam, “Quasiresonant Laser-Produced Plasma: An Efficient Mechanism for Localized Breakdown”, J. Appl. Phys., vol. 51, No. 9, 1980, pp. 4682-4687.
Tanaka et al., “Production of Laser-Heated Plasma in High-Pressure Ar Gas and Emission Characteristics of Vacuum Ultraviolet Radiation from Ar(2) Excimers”, Appl. Phys. B, vol. 74, 2002, pp. 323-326.
Tansu, “Novel Quantum-Wells GaAs-Based Lasers for All Transmission Windows in Optical Communication”, 2003, pp. i-291.
Theriault et al., “A Real-Time Fiber-Optic LIBS Probe for the In Situ Delineation of Metals in Soils”, Field Analytical Chemistry and Technology, vol. 2, No. 2, 1998, pp. 117-125.
Theriault et al., “Field Deployment of a LIBS Probe for Rapid Delineation of Metals in Soils”, SPIE, vol. 2835, 1996, pp. 83-88.
Thermoelectric Cooler Controller, Analog Devices Inc., 2002, pp. 1-24.
Tichenor et al., “Soft-x-ray projection lithography experiments using Schwarzschild imaging optics”, Applied Optics, vol. 32, No. 34, 1993, pp. 7068-7071.
Tombelaine, et al. “Spectrally Shaped Light From Supercontinuum Fiber Light Sources”, Optics Communications, vol. 284, Issue 7, Apr. 1, 2011, pp. 1970-1974.
Tooman, “The Sandia Laser Plasma Extreme Ultraviolet and Soft X-ray (XUV) Light Source”, SPIE vol. 664, 1986, pp. 186-191.
Topanga Advanced Plasma Lighting APL1000-4000SF, p. 1.
Topanga Advanced Plasma Lighting APL1000-5000SF, p. 1.
Topanga Advanced Plasma Lighting APL250-4000BF, p. 1.
Topanga Advanced Plasma Lighting APL250-4000SF, p. 1.
Topanga Advanced Plasma Lighting APL250-5500SF, p. 1.
Topanga Advanced Plasma Lighting APL400-4000BF, p. 1,.
Topanga Advanced Plasma Lighting APL400-4000SF, p. 1.
Topanga Advanced Plasma Lighting APL400-5500BF, p. 1.
Topanga Advanced Plasma Lighting APL400-5500SF, p. 1.
Topanga's Advanced Plasma Lighting System, Topanga USA, 2016, pp. 1-5.
Treshchalov et al., “Spectroscopic Diagnostics of Pulsed Discharge in High-Pressure Argon”, Quantum Electmics, vol. 40, No. 3, 2010, pp. 234-240.
Tsuboi et al., “Nanosecond Imaging Study on Laser Ablation of Liquid Benzene”, Appl. Phys. Lett, vol. 64, 1994, pp. 2745-2747.
Uhlenbusch, et al., “Hβ-Line Profile Measurements in Optical Discharges”, J. Quant. Spectrosc. Radiat. Transfer vol. 44, No. 1, 1990, pp. 47-56.
Hanselman, “Laser-Light Thomson and Rayleigh Scattering in Atmospheric-Pressure Laboratory Plasmas”, 1993, Department of Chemistry. pp. ii-385.
Hansson et al., “Liquid-Xenon-Jet Laser-Plasma Source for EUV Lithography”, SPIE, vol. 4506, 2001, pp. 1-8.
Hansson, “Laser-Plasma Sources For Extreme-Ultraviolet Chaps. 5 & 6”, 2003, pp. 1-58.
Harris, “A Century of Sapphire Crystal Growth Proceedings”, Proceedings of the 10th DoD Electromagnetic Windows Symposium Norfolk, 2004, pp. 1-56.
Harris, “Review of Navy Program to Develop Optical Quality Diamond Windows and Domes”, Naval Air Systems Command, 2002, pp. 1-16.
Harrison et al., “Low-threshold, cw, All-solid-state Ti:AI203 Laser”, Optics Letter, vol. 16, No. 8, 1991, pp. 581-583.
Hawke et al., “An Apparatus for High Pressure Raman Spectroscopy”, Rev. Sci. Instrum., vol. 45, No. 12, 1974, pp. 1598-1601.
Haysom, “Quantum Well Intermixing of InGaAs(P)/InP Heterostructures”, Department of Physics, 2001, pp. ii-224.
Hebner et al., “Measured Pressure Broadening and Shift Rates of the 1.73 μm (5d[3/21]1-6p[5/2]2) Transition of Xenon”, Applied Physics Letters, vol. 59, No. 9, 1991, pp. 537-539.
Hecht, “Fiber Lasers: Fiber Lasers; The state of the art”, Laser Focus World, 2012, pp. 1-11.
Hecht, “Refraction”, Optics (Third Edition), Chapter 4, 1998, pp. 100-101.
High Power Diode Laser, Rofin-Sinar Technologies, Inc., 2000, pp. 1-26.
Horn et al., “Evaluation and Design of a Solid-State 193 nm OPO-Nd:YAG Laser Ablation System”, Spectroch mica Acta Part B, vol. 58, 2003, pp. 1837-1846.
Hou et al., “Fiber Laser For EUV Generation”, EUV Source Workshop, 2006.
Hou et al., “High Intensity Fiber Lasers: Emerging New Applications and New Fiber Technologies”, IEEE LEOS Newsletter, 2007, pp. 22-25.
Hou et al., “High Power Fiber Laser Driver for Efficient EUV Lithography Source with Tin-Doped Water Droplet Targets”, Optics Expres,, vol. 16, No. 2, 2008, pp. 965-974.
Hu et al., “Laser Induced Stabilisation of the Welding Arc”, 2005, Science and Technology of Welding and Joining, vol. 10, No. 1, pp. 76-81.
Huffman et al., “Absorption Coefficients of Xenon and Argon in the 600-1025 Angstrom Wavelength Regions”, The Journal of Chemical Physocs, vol. 39, 1963, pp. 902-909.
Hughes, “Plasmas and Laser Light”, University of Essex, 1975, pp. 200-272.
I.M. Beterov et al. “Resonance radiation plasma (photoresonance plasma)”, Soy. Phys. Usp. vol. 31, No. 66, 1988, pp. 535-554.
Instruction Manual: LDC-3722 Laser Diode Controller, ILX Lightwave Corporation, 1990, pp. 1-1-4-33.
Zimakov, “Continuous Optical Discharges Sustained by Near-IR Laser Radiation”, 42th international conference on plasma physics and CF, 2015, p. 1.
Zhang et al., “Designing a High Performance TEC Controller”, Proceedings of SPIE vol. 4913, 2002, pp. 177-183.
Jahier et al., “Implementation of a Sapphire Cell with External Electrodes for Laser Excitation of a Forbidden Atomic Transition in a Pulsed E-Field”, Eur. Phys. J.D., vol. 13, 2001, pp. 221-229.
Jansson et al., “Liquid-Tin-Jet Laser-Plasma Extreme Ultraviolet Generation”, Applied Physics Letters, vol. 84, No. 13. 2004, pp. 2256-2258.
Jaroszynski et al., “Radiation Sources Based on Laser-Plasma Interactions”, Phil. Trans. R. Soc. vol. 364,2006, pp. 689-710.
Jauregui et al., “High-power Fibre Lasers”, Nature Photonics, vol. 7, 2013, pp. 861-867.
Jeng et al., “Theoretical Investigation of Laser-Sustained Argon Plasmas,” J. Appl. Phys., vol. 60, No. 7, Oct. 1, 1986, pp. 2272-2279.
Jinno et al., “Luminance and efficacy improvement of low-pressure xenon pulsed fluorescent lamps by using an auxiliary external electrode”, J. Phys. D: Appl. Phys., vol. 40, 2007, pp. 3889-3895.
Jinno et al., “The Afterglow Characteristics of Xenon Pulsed Plasma for Mercury-Free Fluorescent Lamps”, Czech. J. Phys., vol. 50, 2000, pp. 433-436.
Johnson, “Ultraviolet Emission Spectra of High-Pressure Rare Gases”, 1970, Journal of the Optical Society of America,, vol. 60, No. 12, pp. 1669-1674.
Joshi et al., “Laser-Induced Breakdown Spectroscopy for In-Cylinder Equivalence Ratio Measurements in Laser-Ignited Natural Gas Engines”, Applied Spectroscopy, vol. 63, No. 5, 2009, pp. 549-554.
Kaku et al., “Vacuum Ultraviolet Spectroscopic System Using a Laser-Produced Plasma”, Journal of Applied Physics. vol. 42, 2003, pp. 3458-3462.
Kaku et al., “Vacuum Ultraviolet Transmission Spectroscopic System using a Laser-Produced Plasma”, The Japan Society of Applied Physics, vol. 42, No. 6R, pp. 149-152.
Keefer et al., “Experimental Study of a Stationary Laser-Sustained Air Plasma,” Journal of Applied Physics, vol. 46, No. 3, Mar. 1975, pp. 1080-1083.
Keefer et al., “Power Absorption Laser Sustained Argon Plasmas”, AIAA Journal, vol. 24, No. 10, 1986, pp. 1663-1669.
Keefer , “Laser-Sustained Plasmas”, 1989, pp. 169-206.
Kennedy et al., “A Review of the Use of High Power Diode Lasers in Surface Hardening, Journal of Materials Processing Technology”, vol. 155-156, 2004, pp. 1855-1860.
Keyser et al. “Studies of High-Repetition-Rate Laser Plasma EUV Sources from Droplet Targets”, Applied Physics A, vol. 77. 2003, pp. 217-221.
Kim et al., “Development of an In Situ Raman Spectroscopic System for Surface Oxide Films on Metals and Alloys in High Temperature Water, Nuclear Engineering and Design”, vol. 235, 2005, pp. 1029-1040.
Kindel et al., Measurement of Excited States Density and the VUV-Radiation in the Pulsed Xenon Medium Pressure Discharge, Contrib. Plasma Phys., vol. 36, 1996, pp. 711-721.
Kirk et al., “Methods and Systems for Providing Illumination of a Specimen for Inspection” Provisonal U.S. Appl. No. 60/806,204, filed Jun. 29, 2006, 48 pages.
Kirk et al., “Methods and Systems for Providing Illumination of a Specimen for Inspection”, Provisional U.S. Appl. No. 60/759,846, filed Jan. 17, 2006, 18 pages.
Kirk et al., “Methods and Systems for Providing Illumination of a Specimen for Inspection”, Provisional U.S. Appl. No. 60/772,425, filed Feb. 9, 2006, 20 pages.
Klein, “Measurements of Spectral Emission and Absorption of a High Pressure Xenon Arc in the Stationary and the Flashed Modes”, 1968, pp. 677-685.
Klocke et al., “Investigation into the Use of High Power Diode Lasers for Hardening and Thermal Conduction Welding of Metals”, SPIE, vol. 3097, 1997, pp. 592-598.
Knyazev, “Photoresonance Plasma Production by Excimer Lasers as a Technique for Anode-plasma Formation”, Nucl. Instr. and Meth. in Phys. Res. A, vol. 415, 1998, pp. 525-532.
Kolb et al., “Low Optical Loss Synthetic Quartz”, Mat. Res. Bull. Vol. 7, 1972, pp. 397-406.
Kondow et al., “Temperature Dependence of Lasing Wavelength in a GaInNAs Laser Diode”, IEEE Photonics Technology Letters, vol. 12, No. 7, 2000, pp. 777-779.
Kopecek et al., “Laser Ignition of Methane-Air Mixtures at High Pressures and Diagnostics”, Journal of Engineering for Gas Turbines and Power, vol. 127, 2005, pp. 213-219.
Kopecek et al., “Laser-Induced Ignition of Methane-Air Mixtures at Pressures up to 4 MPa”, Laser Physics, vol. 13, No. 11, 2003, pp. 1365-1369.
Korn et al., “Ultrashort 1-kHz Laser Plasma Hard X-ray Source”, Optics Letters, vol. 27, No. 10, 2002, pp. 866-868.
Kozlov et al., “Radiative Losses by Argon Plasma and the Emissive Model of a Continuous Optical Discharge”, Soy. Phys. JETP, vol. 39, No. 3, Sep. 1974, pp. 463-468.
Kozlov et al., “Sustained Optical Discharges in Molecular Gases,” Sov. Phys. Tech. Phys. vol. 49, No. 11, Nov. 1979, pp. 1283-1287.
Kranzusch et al., “Spatial Characterization of Extreme Ultraviolet Plasmas Generated by Laser Excitation of Xenon Gas Targets”, Review of Scientific Instruments, vol. 74, No. 2, 2003, pp. 969-974.
Krushelnick et al., “Plasma Channel Formation and Guiding during High Intensity Short Pulse Laser Plasma Experiments”, Physical Review Letters, vol. 78, No. 21, 1997, pp. 4047-4050.
Ku et al., “Decay of Krypton 1(s)(2) and 1(s)(3) Excited Species in the Late Afterglow”, Physical Review A, vol. 8, No. 6, 1973, pp. 3123-3130.
Kubiak et al., “Scale-up of a Cluster Jet Laser Plasma Source for Extreme Ultraviolet Lithography”, SPIE, vol. 3676, 1999, pp. 669-678.
Kuhn, “Laser Engineering”, 1998, pp. 303-343, 365-377, 384-440.
Kurkov et al., “CW Medium-Power Fiber Lasers for Near IR Range”, Proceedings of SPIE, vol. 5449, 2004, pp. 62-69.
Lackner et al.. “The Optical Spark Plug: Window-related Issues”, Institute of Chemical Engineering, Vienna University of Technology, 2005, pp. 1-6.
Lange et al., “Tunable Diode Laser Absorption Spectroscopy for Plasmas at Elevated Pressures”, Proceedings of SPIE Vo. 4460, 2002, pp. 177-187.
Laufer et al., “Effect of Temperature on the Vacuum Ultraviolet Transmittance of Lithium Fluoride, Calcium Fluoride, Barium Fluoride, and Sapphire”, Journal of the Optical Society of America, vol. 55, No. 1, 1965, pp. 64-66.
Laufer , “Introduction to Optics and Lasers in Engineering”, 1996, pp. 449-454.
Legall et al., “Spatial and Spectral Characterization of a Laser Produced Plasma Source for Extreme Ultraviolet Metrology”, Review of Scientific Instruments, vol. 75, No. 11, 2004, pp. 4981-4988.
Lenses and Curved Mirrors, University of Delaware, Imaging (last visited Dec. 19, 2015),pp. 24-29.
Leonov et al., “Mechanisms of Resonant Laser Ionization”, JETP, vol. 8, No. 4, 1997, pp. 703-715.
Lewis et al., “Measurements of CW Photoionization for the Use in Stable High Pressure Tea Laser Discharge”,IEEE Nuclear and Plasma Sciences Society, 1975, pp. 14-45.
Li et al., “Density measurements of a high-density pulsed gas jet for laser-plasma interaction studies”, Meas. Sci. Technol., vol. 5, 1994, pp. 1197-1201.
Li, “The Advances and Characteristics of High-Power Diode Laser Materials Processing”, Optics and Lasers in Engineering, vol. 34, 2000, pp. 231-253.
Liao et al., “An efficient Ni Kα X-ray Source Driven by a High Energy Fiber CPA System”, Center for Ultrafast Optical Science, 2007, pp. CP1-4-THU.
Liao et al., “Generation of Hard X-rays Using an Ultrafast Fiber Laser System”, Optics Express, vol. 15, No. 21, 2007, pp. 13942-13948.
Light Hammer, 10 Mark II UV Lamp System, Heraeus Noblelight America LLC, 2015, pp. 1-20.
Light Hammer, 6 UV Lamp System Parts Listing, Heraeus Noblelight America LLC, 2015, pp. 1-22.
Lo et al., “Resonance-Enhanced LIBS”, Department of Physics, 2002, pp. 15-17.
Lowe et al., “Developments in Light Sources and Detectors for Atomic Absorption Spectroscopy”, Spectrochimica Acta Part B., vol. 54, 1999, pp. 2031-2039.
Lui et al., “Resonance-Enhanced Laser-Induced Plasma Spectroscopy: Time-Resolved Studies and Ambient Gas Effects”, Department of Physics, 2002, pp. 19-21.
Luo et al., “Sapphire (0 0 0 1) Surface Modifications Induced by Long-Pulse 1054 nm Laser Irradiation”, Applied Surface Science, vol. 253, 2007, pp. 9457-9466.
Macdowell et al., “Reduction imaging with soft x rays for projection lithography”, Review of Scientific Instruments, vol. 63, No. 1, 1992, pp. 737-740.
Maclean et al., “Direct Diode Laser Pumping of a Ti:Sapphire Laser”, Institute of Photonics, SUPA, 2009, pp. 1-3.
Magner et al., “Self-Compression of Ultrashort Pulses through Ionization-Induced Spatiotemporal Reshaping”, Physical Review Letter, vol. 93, No. 17, 2004, pp. 173902-1-173902-4.
Mahmoud et al., “Ion Formation in Laser-Irradiated Cesium Vapor”, Journal of Quantitative Spectroscopy & Radiative Transfer, vol. 102. 2006, pp. 241-250.
Malik et al., “Spectroscopic Measurements on Xenon Plasma in a Hollow Cathode”, 2000, J. Phys, D; Appl. Phys., vol. 33, pp. 2037-2048.
Malka et al., “Channel Formation in Long Laser Pulse Interaction with a Helium Gas Jet”, Physical Review Letters, vol. 79, No. 16, 1997, pp. 2979-2982.
Mandel'Shtam et al., “Investigation of the Spark Discharge Produced in Air by Focusing Laser Radiation II”, Soviet Physics JETP, vol. 22, No. 1, 1966, pp. 91-96.
May, “Infrared Optogalvanic Effects in Xenon”, Optics Communications, vol. 64, No. 1, 1987, pp. 36-40.
Mazumder et al., “Spectroscopic Studies of Plasma During CW Laser Gas Heating in Flowing Argon”, J. Appl. Phys., vol. 62, No. 12, 1987, pp. 4712-4718.
Measures et al., “Fast and Efficient Plasma Heating Through Superelastic Laser Energy Conversion”, J. Appl. Phys., vol. 51, No. 7, 1980, pp. 3622-3628.
Measures et al., “Laser interaction based on resonance saturation (LIBORS): an altemative to inverse bremsstrahlung for coupling laser energy into a plasma”, 1979, Applied Optics, vol. 18, No. 11, pp. 1824-1827.
Measures et al., “Tablaser: Trace (Element) Analyzer Based on Laser Ablation and Selectively Excited Radiation”, Applied Optics, vol. 18, No. 3, 1979, pp. 281-286 (1979).
Measures, “Electron Density and Temperature Elevation of a Potassium Seeded Plasma by Laser Resonance Pumping”,J. Quant. Spectrose. Radial. Transfer. vol. 10, 1970, pp. 107-125.
Mercury Vapor Light Source, Model OS-9286A.
Michel et al., “Analysis of Laser-Induced Breakdown Spectroscopy Spectra: The Case for Extreme Value Statistics”, Spectrochimica Acta Part B. vol. 62, 2007, pp. 1370-1378.
Michel et al., “Laser-Induced Breakdown Spectroscopy of Bulk Aqueous Solutions at Oceanic Pressures: Evaluation of Key Measurement Parameters”, Applied Optics, vol. 46, No. 13, 2007, pp. 2507-2515.
Milian et al., “Dynamic Compensation of Chromatic Aberration in a Programmable Diffractive Lens”, Optical Express, vol. 14, No. 20. 2006, pp. 9103-9112.
Millard et al., “Diode Laser Absorption Measurements of Metastable Helium in Glow Discharges”, Plasma Sources Sci. Technol., vol. 7, 1998, pp. 288-394.
Mills et al., “Argon-Hydrogen-Strontium Discharge Light Source”, IEEE Transactions on Plasma Science, vol. 30, No. 2, 2002, pp. 639-652.
Mills et al., “Excessively Bright Hydrogen-Strontium Discharge Light Source Due to Energy Resonance of Strontium with Hydrogen”, J. Plasma Physics, vol. 69, Part 2, 2003, pp. 131-158.
Mizoguchi et al., “Development of Light Source for Lithography at Present and for the Future”, vol. 59, No. 166, 2013, pp. 1-7.
Mizoguchi et al., Development of CO2 Laser Produced Xe Plasma EUV Light Source for Microlithography, Proc. of SPIE, vol. 6151, 2006, pp. 61510S-1.
Related Publications (1)
Number Date Country
20240297035 A1 Sep 2024 US
Continuations (3)
Number Date Country
Parent 18465022 Sep 2023 US
Child 18663177 US
Parent 18161282 Jan 2023 US
Child 18465022 US
Parent 17328433 May 2021 US
Child 18161282 US