1. Field of the Invention
The present invention relates to an ion source for the generation of ion beams for doping wafers in the semiconductor manufacturing of PMOS and NMOS transistor structures to make integrated circuits and more particularly to a universal ion source configured to operate in dual modes, for example, an arc discharge mode and an electron impact mode.
2. Description of the Prior Art
The fabrication of semiconductor devices involves, in part, the formation of transistor structures within a silicon substrate by ion implantation. The ion implantation equipment includes an ion source which creates a stream of ions containing a desired dopant species, a beam line which accelerates and focuses the ion stream into an ion beam having a well-defined energy or velocity, an ion filtration system which selects the ion of interest, since there may be different species of ions present within the ion beam, and a process chamber which houses the silicon substrate upon which the ion beam impinges; the ion beam penetrating a well-defined distance into the substrate. Transistor structures are created by passing the ion beam through a mask formed directly on the substrate surface, the mask being configured so that only discrete portions of the substrate are exposed to the ion beam. Where dopant ions penetrate into the silicon substrate, the substrate's electrical characteristics are locally modified, creating source, drain and gate structures by the introduction of electrical carriers: such as, holes by p-type dopants, such as boron or indium, and electrons by n-type dopants, such as phosphorus or arsenic, for example.
Traditionally, Bernas-type ion sources have been used in ion implantation equipment. Such ion sources are known to break down dopant-bearing feed gases, such as BF3, AsH3 or PH3, for example, into their atomic or monomer constituents, producing the following ions in copious amounts: B+, As+ and P+. Such ion sources are known to produce extracted ion currents of up to 50 mA, enabling up to 20 mA of filtered ion beam at the silicon substrate. Bernas type ion sources are known as hot plasma or arc discharge type sources and typically incorporate an electron emitter, either a naked filament cathode or an indirectly-heated cathode, and an electron repeller, or anticathode, mounted opposed to one another in a so-called “reflex” geometry. This type of source generates a plasma that is confined by a magnetic field.
Recently, cluster implantation sources have been introduced into the equipment market. These ion sources are unlike the Bernas-style sources in that they have been designed to produce “clusters”, or conglomerates of dopant atoms in molecular form, e.g., ions of the form Asn+, Pn+, or BnHm+, where n and m are integers, and 2≦n≦18. Such ionized clusters can be implanted much closer to the surface of the silicon substrate and at higher doses relative to their monomer (n=1) counterparts, and are therefore of great interest for forming ultra-shallow p-n transistor junctions, for example in transistor devices with gate lengths of 65 nm, 45 nm, or 32 nm. These cluster sources preserve the parent molecules of the feed gases and vapors introduced into the ion source. The most successful of these have used electron-impact ionization, and do not produce dense plasmas, but rather generate low ion densities at least 100 times smaller than produced by conventional Bernas sources.
Briefly, the present invention relates to an ion source for providing a range of ion beams consisting of either ionized clusters, such as B2Hx+, B5Hx+, B10Hx+, B18Hx+, P4+ or As4+, or monomer ions, such as Ge+, In+, Sb+, B+, As+, and P+, to enable cluster implants and monomer implants into silicon substrates for the purpose of manufacturing CMOS devices, and to do so with high productivity. This is accomplished by the novel design of an ion source which can operate in two discrete modes: electron impact mode, which efficiently produces ionized clusters, or arc discharge mode, which efficiently produces monomer ions.
Borohydride molecular ions are created by introducing gaseous B2H6, B5H9, B10H14, or B18H22 into the ion source where they are ionized through a “soft” ionization process, such as electron impact ionization, which preserves the number of boron atoms in the parent molecule (the number of hydrogens left attached to the ion may be different from that of the parent). Likewise, As vapor or P vapor can be introduced into the ion source (from a vaporizer which sublimates elemental As or P) to produce an abundance of As4+, As2+, and As+, or P4+, P2+, and P+ ions. The mechanism for producing As and P clusters from elemental vapor will be described in more detail below. Monomer ions are produced by creating an arc discharge within the ion source, producing a dense plasma and breaking down the feed gases BF3, AsH3, PH3, SbF5, InCl3, InF3 and GeF4 into their constituent atoms. This provides high currents of Ge+, In+, Sb+, B+, As+, and P+ ions as required by many semiconductor processes today. The invention, as described in detail below, is disclosed by novel methods of constructing and operating a single or universal ion source which produces these very different ion species, i.e., both clusters and monomers, and switching between its two modes of operation quickly and easily, enabling its efficient use in semiconductor manufacturing.
An object of this invention is to provide a method of manufacturing a semiconductor device, this method being capable of forming ultra-shallow impurity-doped regions of N-type conductivity in a semiconductor substrate by implanting ionized clusters of the form P4+ and As4+.
A further object of this invention is to provide for an ion implantation source and system for manufacturing semiconductor devices, which has been designed to form ultra shallow impurity-doped regions of N-conductivity type in a semiconductor substrate through the use of cluster ions of the form P4+ and As4+.
According to one aspect of this invention, there is provided a method of implanting cluster ions comprising the steps of: providing a supply of molecules each of which contains a plurality of either As or P dopant atoms into an ionization volume, ionizing the molecules into dopant cluster ions, extracting and accelerating the dopant cluster ions with an electric field, selecting the desired cluster ions by mass analysis, and implanting the dopant cluster ions into a semiconductor substrate.
While the implantation of P-type clusters of boron hydrides for semiconductor manufacturing has been demonstrated, no N-type cluster has been documented which produces large ionized clusters in copious amounts. If ions of the form Pn+ and Asn+ with n=4 (or greater) could be produced in currents of at least 1 mA, then ultra-low energy, high dose implants of both N- and P-type conductivity would be enabled. Since both conductivity types are required by CMOS processing, such a discovery would enable clusters to be used for all low energy, high dose implants, resulting in a dramatic increase in productivity, with a concomitant reduction in cost. Not only would cost per wafer decline dramatically, but fewer ion implanters would be required to process them, saving floor space and capital investment.
The preferred method of forming drain extensions for sub-65 nm devices is expected to incorporate a wafer tilt ≧30 deg from the substrate normal, in order to produce enough “under the gate” dopant concentration, without relying on excessive dopant diffusion brought about by aggressive thermal activation techniques. Excellent beam angular definition and low beam angular divergence are also desired for these implants; while high current implanters tend to have large angular acceptances and significant beam non-uniformities, medium current implanters meet these high-tilt and precise angle control requirements. Since medium-current implanters do not deliver high enough currents, their throughput on high-dose implants is too low for production. If ion implanters could produce the required low-energy beams at high dose rates, great economic advantage would be achieved. Since drain extensions are the shallowest of implants, they are also at the lowest energies (about 3 keV As at the 65 nm node, for example); the long, complicated beamlines which typify medium-current implanters cannot produce enough current at low energy to be useful in manufacturing such devices. The use of As4+ and P4+ cluster implantation in medium-current beam lines and other scanned, single-wafer implanters extends the useful process range of these implanters to low energy and to high dose. By using high currents of these clusters, up to a factor of 16 in throughput increase can be realized for low-energy, high dose (≧1014/cm2) implants with effective As and P implant energies as low as 1 keV per atom.
As is generally known, elemental, solids As and P are known to exist in a tetrahedral form (i.e., as white phosphorus, P4, and as yellow arsenic, As). They would therefore seem to be ideal candidates for producing tetramer ions in an ion source. However, while these compounds can be synthesized, they are more reactive, and hence more unstable, than their more common forms, i.e., red P and grey As metals. These latter forms are easily manufactured, stable in air, and inexpensive. Importantly, it turns out that when common red P and grey As are vaporized, they naturally form primarily P4 and As4 clusters in the vapor phase! [see, for example, M. Shen and H. F. Schaefer III, J. Chem. Phys. 101 (3) pp. 2261-2266, 1 Aug. 1994.; Chemistry of the Elements, 2nd Ed., N. N Greenwood and A. Earnshaw, Eds., Butterworth-Heiemann Publishers, Oxford, England, 2001, Chap. 13, p. 55; R. E. Honig and D. A. Kramer, RCA Review 30, p. 285, June 1969.] Electron diffraction studies have confirmed that in the vapor phase the tetrahedral As4 predominates. This tetrahedral phase is delicate, however, and is readily dissociated, for example, by exposure to ultraviolet light or x-rays, and dissociates in plasmas of the type formed by conventional ion sources. Indeed, it is known that As4 quite readily dissociates into 2As2 under energetic light bombardment.
Significant currents of ionized As4 and P4 clusters can be produced by vaporizing solid forms of As and P (either the amorphous or tetrahedral solid phases) and preserving these clusters through ionization in a novel electron-impact ionization source, demonstrating that the clusters survive electron impact.
Although prior art ion sources have used vaporized solid As and P to generate ion beams, the tetramers have not been preserved. The ions produced by these arc discharge sources have consisted of principally monomers and dimers. Since the tetramer forms As4 and P4 are delicate and easily dissociated by the introduction of energy, to preserve them, the source should be free from excessive UV (such as emitted by hot filaments, for example) and most importantly, be ionized by a “soft” ionization technique, such as electron impact. As will be discussed in more detail below, this technique is useful in creating As4+ ions from vaporized elemental arsenic and phosphorus.
The ion source of the present invention introduces gaseous As4 and P4 vapors through a vaporizer, which heats solid feed materials, such as elemental As or P, and conducts the vapor through a vapor conduit into the ionization chamber of the ion source. Once introduced into the ionization chamber of the ion source, the vapor or gas interacts with an electron beam which passes into the ionization volume from an external electron gun, forming ions. The vapor is not exposed to a hot, UV-producing cathode since the electron gun is external to the ionization volume and has no line-of-sight to the vapors. The ions are then extracted from a rectangular aperture in the front of the ionization volume by electrostatic optics, forming an ion beam.
These and other advantages of the present invention will be readily understood with reference to the following specification and attached drawing wherein:
a is a schematic representation of the basic components of the ion source in accordance with the present invention which includes an electron gun, an indirectly-heated cathode, a source liner, a cathode block, a base, an extraction aperture, a source block, and a mounting flange.
b is an exploded view of the ion source of the present invention, illustrating the major subsystems of the ion source
a is an exploded isometric view of the ion source illustrated in
b is an exploded isometric view of the ionization volume liner and the interface or base block showing the plenum and the plenum ports in the interface block.
c is an isometric view of the ionization volume assembly in which the ionization volume is formed from a cathode block, an interface block, and a magnetic yoke assembly, shown with the ionization volume liner removed.
a is an exploded isometric view of a indirectly-heated cathode (IHC) assembly in accordance with one aspect of the present invention.
b is an enlarged exploded view of a portion of the IHC assembly, illustrating the IHC, a filament, a cathode sleeve, and a portion of a cathode plate.
c is an elevational view in cross section of the IHC assembly illustrated in
d is an isometric view of a water-cooled cathode block shown assembled to the IHC assembly illustrated in
e is an elevational view of the assembly illustrated in
f is an isometric view of a magnetic yoke assembly which surrounds the cathode block and ionization volume In accordance with the present invention.
a is an isometric view of an emitter assembly which forms a portion of the external electron gun assembly in accordance with one aspect of the present invention.
b is an isometric view of an electron gun assembly in accordance with the present invention shown with an electrostatic shield assembly removed.
a is an isometric view of a source block in accordance with the present invention
b is similar to
a and 12b are logic flow diagrams illustrating the sequence of steps required to establish each operating mode in succession.
The present invention relates to ion source for providing a range of ion beams consisting of either ionized clusters, such as B2Hx+, B5Hx+, B10Hx+, B18Hx+, P4+ or As4+ or monomer ions, such as Ge+, In+, Sb+, B+, As+, and P+, to enable cluster implants and monomer implants into silicon substrates for the purpose of manufacturing CMOS devices, and to do so with high productivity. The range of ion beams is generated by a universal ion source in accordance with the present invention which is configured to operate in two discrete modes: an electron impact mode, which efficiently produces ionized clusters, and an arc discharge mode, which efficiently produces monomer ions.
The universal ion source in accordance with the present invention is illustrated and described below.
In order to efficiently produce ionized clusters, the ion source of the present invention incorporates the following features:
In order to efficiently produce monomer ions, the ion source of the present invention also incorporates the following features:
Other novel features are provided in the ion source to enable reliability and performance: It is a feature of the invention that the ion source incorporates an in-situ chemical cleaning process, preferably by the controlled introduction of atomic fluorine gas, and the materials used to construct the elements of the ion source are selected from materials resistant to attack by F:
The ionization chamber liner may be fabricated from titanium diboride (TiB2), which is resistant to attack by halogen gases, and possesses good thermal and electrical conductivity, but may also be usefully fabricated of aluminum, graphite or other electrical and thermal conductor which is not readily attacked by flourine;
The arc discharge electron source may be an indirectly-heated cathode, and the portion of which exposed to the cleaning gas may be formed a thick tungsten, tantalum or molybdenum disk, and is therefore much more robust against failure in a halogen environment than a naked filament;
The indirectly-heated cathode assembly is mechanically mounted onto a water-cooled aluminum “cathode block” so that the, limiting its radiative heat load to the ionization chamber and liner (we note that aluminum passivates in a F environment, and is therefore resistant to chemical etch); this enables rapid cool down of the cathode between the time it is de-energized and the onset of an in-situ cleaning cycle, reducing the degree of chemical attack of the refractory metal cathode
The electron gun which is energized during electron-impact ionization (i.e., during cluster beam formation) is remote from the ionization volume, mounted externally and has no line-of-sight to the F gas load during an in-situ clean, and therefore is robust against damage by F etching.
Other novel features are incorporated to improve source performance and reliability:
When operating in electron impact mode, the following conditions are met:
When operating in arc discharge mode, the following conditions are met:
Referring to
The ion source 400 is constructed to provide cluster ions and molecular ions, for example the borohydride ions B18Hx+, B18Hx−, B18Hx+, and B18Hx− or, and alternatively, more conventional ion beams, such as P+, As+, B+, In+, Sb+, Si+, and Ge. The gas and vapor inlet 441 for gaseous feed material to be ionized is connected to a suitable vapor source 445, which may be in close proximity to gas and vapor inlet 441 or may be located in a more remote location, such as in a gas distribution box, located elsewhere within a terminal enclosure.
A terminal enclosure is a metal box, not shown, which encloses the ion beam generating system. It contains required facilities for the ion source, such as pumping systems, power distribution, gas distribution, and controls. When mass analysis is employed for selection of an ion species in the beam, the mass analyzing system may also be located in the terminal enclosure.
In order to extract ions of a well-defined energy, the ion source 400 is held at a high positive voltage (in the more common case where a positively-charged ion beam is generated) with respect to an extraction electrode assembly 405 and a vacuum housing 410 by a high voltage power supply 460. The extraction electrode assembly 405 is disposed close to and aligned with an extraction aperture 504 on an extraction aperture plate which forms a portion of the ionization volume 500. The extraction electrode assembly consists of at least two aperture-containing electrode plates, a so-called suppression electrode 406 closest to the ionization volume 500, and a “ground” electrode 407. The suppression electrode 406 is biased negative with respect to a ground electrode 407 to reject or suppress unwanted electrons which are attracted to the positively-biased ion source 400 when generating positively-charged ion beams. The ground electrode 407, vacuum housing 410, and terminal enclosure (not shown) are all at the so-called terminal potential, which is at earth ground unless it is desirable to float the entire terminal above ground, as is the case for certain implantation systems, for example for medium-current ion implanters. The extraction electrode 405 may be of the novel temperature-controlled metallic design, described below.
In accordance with another aspect of the invention, the ion source 400, illustrated in of
a is a simplified schematic representation of the basic components of the ion source, indicating the electron gun cathode 10, the indirectly-heated cathode (IHC) 20, an ionization volume liner 30, a cathode block 40, a base or interface block 50, extraction aperture plate 60, a source block 70, and a mounting flange 80. The ionization volume liner 30 is preferably made of TiB2 or aluminum, but may be usefully constructed of SiC, B4C, C, or any other suitable electrically conductive material which is not a deleterious contaminant in silicon circuits, and can sustain an operating temperature of between 100 C and 500 C. The cathode block 40 is preferably of aluminum due to its high thermal and electrical conductivity, and resistance to attack by halogen gases. Al also allows for direct water cooling since it is non-porous and non-hydroscopic. Other materials may be used such as refractory metals like tungsten and molybdenum which have good electrical and thermal properties; however they are readily attacked by halogen gases. Another consideration for the cathode block is compatibility with ion bombardment of P+, As+, and other species produced under arc discharge operation. Since the cathode block is unipotential with the IHC cathode 20, it is subject to erosion by ion bombardment of plasma ions. The sputter rates of materials under bombardment by ions of interest therefore must be considered as it will impact useful source life. The base 50, again, is preferably made of aluminum, but can be made of molybdenum or other electrically and thermally conductive materials. Since the source block 70, mounting flange 80, and ion extraction aperture 60 are typically operated at 200 C or below, they can be usefully constructed of aluminum as well The ionization volume liner 30 surrounds an ionization volume 35 and is in light thermal contact with the mounting base 50, which is itself in good thermal contact with the source block 70. Except for a slot through the ionization volume liner 30 and the extraction aperture plate 60 through which ions pass, the ionization volume of the ion source is fully bounded by a cylindrical bore through the ionization volume liner 30 and the top and bottom plates of the cathode block 40. The source block 70 is temperature controlled to up to 200 C, for example. Thus, when the electron gun 10 is active, very little power is transferred to the ionization volume liner 30, the temperature of which is close to that of the source block 70. When the IHC 100 is energized, the ionization volume liner 30 is exposed to hundreds of watts of power and can attain a much higher temperature than the source block 70 (up to 400 C or higher), which is beneficial to limit condensation of gases onto the surface of the ionization volume liner 30.
b is an exploded isometric view of the ion source of the present invention, showing its major subsystems. The ion source includes an ion extraction aperture plate 60, an ionization volume or chamber assembly 90, an IHC assembly 100, an electron gun assembly 110, a source block assembly 120, and a mounting flange assembly 130. The ion source also includes a low-temperature vaporizer (not shown) coupled to a port 135. A vapor conduit 137 is used to transport the vapor into the ionization assembly 90. The ion source also includes dual hot vapor inlet ports 138, a process gas inlet port 139, and an optional reactive gas inlet port 140. In an exemplary, embodiment atomic F may fed to the ionization volume assembly 90 via the reactive gas inlet port 140. Vaporized As, P, or SbO3 into the dual hot vapor inlet ports 138 while B18H22 vapor may be applied to the vapor conduit 137.
a is an exploded isometric view of the ion source in accordance with the present invention, shown with the mounting flange assembly 130, electron gun assembly 110, indirectly heated cathode assembly 100 and the extraction aperture plate 60 removed. The ion source includes a source block 120, a cathode block 40, mounting base or interface block 50, an ionization volume or source liner 30, a liner gasket 115, a base gasket 125, and a cathode block gasket 127. As will be discussed in more detail below and as illustrated in
b is an exploded isometric view of the ionization volume liner 30 and the interface or base block 50, showing the plenum and the plenum ports in the interface block 50. The several gas and vapor inlet ports, namely vapor port 137, reactive gas port 140, process gas port 139, and dual hot vapor ports 141a and 141b, feed into a gas plenum 45, formed in the base or interface block 50. The interface block 50 is provided with one or more through holes 142a and 142b to accommodate mounting conventional fasteners (not shown) to secure the interface block 50 to the source block 120 and thereby establish electrical conductivity between the interface block 50 and the source block 120). The gas plenum 45 may be cavity machined into the interface block 50 and is used to collect any of the gases fed into the plenum 45 and feed them into multiple liner ports 32. The multiple liner ports 32 are configured in a “shower head” design to distribute the gases along different directions into the ionization volume 35 within the ionization volume liner 30. By transporting all of the gases or vapors into the plenum 45, which acts as a ballast volume, which then feeds the gases through a shower head directly into the ionization volume 35, produces a uniform distribution of gas or vapor molecules within the ionization volume 35. Such a configuration results in a more uniform distribution of ions presented to extraction aperture 60, and the subsequent formation of a more spatially uniform ion beam.
c is an isometric view of the ionization volume assembly 90, shown with the ionization volume liner removed. The ionization volume assembly 90 is formed from the cathode block 40, the interface block 50, and the magnetic yoke assembly 150. The magnetic yoke assembly 150 is constructed of magnetic steel and conducts the magnetic flux produced by a pair of permanent magnets 151a and 151b around through ionization volume assembly 90, producing a uniform magnetic field of about 120 Gauss, for example, within the ionization volume 35. During electron impact operation, this permanent field confines the electron beam so that the ions are produced in a well-defined, narrow column adjacent to the ion extraction aperture 60. During arc discharge mode, the same field provides confinement for the plasma column between cathode and the upper plate of the cathode block 40, which serves as an anticathode.
a is an exploded view of the indirectly-heated cathode (IHC) assembly 100. IHC assemblies are generally known in the art. Examples of such IHC assemblies are disclosed in U.S. Pat. Nos. 5,497,006; 5,703,372; and 6,777,686, as well as US Patent Application Publication No. US 2003/0197129 A1, all hereby incorporated by reference. The principles of the present able invention are applicable to all such IHC assemblies. An alternate IHC assembly 100 in for use with the present invention includes an indirectly-heated cathode 160, a cathode sleeve 161, a filament 162, a cathode plate 163, a pair of filament clamps 164a and 164b, a pair of filament leads 165a and 165b, and a pair of insulators 167a and 167b (not shown). The filament 162 emits up to 2 A, for example, of electron current which heats the indirectly-heated cathode 160 to incandescence by electron bombardment. Since the filament 162 is held at a negative potential of up to 1 kV below the cathode potential, up to 2 kW of electron beam heating capacity is available for cathode heating, for example. In practice, heating powers of between 1 kW and 1.5 kW are sufficient, although for very high arc currents (in excess of 2 A of arc) higher power can be required. The cathode 160 is unipotential with the cathode mounting plate 163. The insulators 167a and 167b are required to stand off the filament voltage of up to 1 kV.
Referring now to
The indirectly heated cathode (IHC) 160 may be machined from a single tungsten cylinder. An exemplary IHC 160 may be about 0.375 inch thick, and is robust against both F etch and ion bombardment. As seen in
The IHC 160, sleeve 161, and filament 162 are preferably made of tungsten. The filament leads shown in
d and 5e illustrate the indirectly-heated cathode assembly 100 mounted onto the water-cooled cathode block 40. A pair of water fittings 41a and 41b are used to transport de-ionized water through a vacuum interface. The water circulates through the cathode block 40 and can absorb several kW of power, allowing the cathode block 40 to remain well below 100° C. at all times. The IHC 160 is unipotential with the cathode block 40. As such, no insulation is required between the cathode 160 and cathode block 40, which forms the top and bottom boundary surfaces of the ionization volume 35. This results in a very reliable system, since in prior art IHC sources, the IHC is up to 150V different from its immediate surroundings. This results, in turn, in quite common failures precipitated by the collection of debris between the IHC 160 and the ionization volume surface through which it penetrates. Another benefit of the configuration is that it eliminates the common failure of anticathode erosion since the top plate of cathode block 40 serves as the anticathode since it is at cathode potential. The plasma column is bounded by the ionization volume 35 is defined by the bore through the ionization volume liner 30 and the top and bottom plates of the cathode block 40. This defines a very stable volume to sustain the plasma column during arc discharge operation.
f shows a detail of the magnetic yoke assembly 150 which surrounds the cathode block 40 and the ionization volume 35. The magnetic yoke assembly 150 is constructed of magnetic steel and conducts magnetic flux through an ionization volume or chamber assembly 90, producing a uniform axial magnetic field of about 120 Gauss, for example, within the ionization volume 35. This magnetic yoke assembly 150 is used to generate a magnetic field to confine the plasma generated in the ionization volume 35 during an arc discharge mode of operation. During an electron impact mode of operation, the electron gun assembly 110 is shielded from the magnetic field because of a magnetic shield which is inserted between the yoke assembly 150 and the electron gun, as indicated in
a and 6b illustrate the external electron gun assembly 110. In particular, Such electron gun assemblies are disclosed in detail in U.S. Pat. No. 6,686,595 as well as US Patent Application Publication No. US 2004/0195973 A1, hereby incorporated by reference.
Electrons emitted from a filament 200 in the emitter assembly 210 are extracted by the anode 215 and bent through 90 degrees by the magnetic dipole 220, passing through an aperture 230 in the gun base 240. The electron beam is shielded from the magnetic fields within the ionization volume assembly 90, generated by the magnetic yoke 150, by a magnetic shield 255. The anode 215, gun base 240, and the electrostatic shield assembly 250 are all at anode potential, as high as, for example, 2 kV above the potential of the ionization volume assembly 90, which is held at the potential of the source block 120 during electron impact operation. The filament voltage, for example, is several hundred volts negative; thus, the electron beam is decelerated between the gun base 240 and the ionization volume 35, as described in detail, for example by Horsky in U.S. Pat. No. 6,686,595, hereby incorporated by reference.
A mounting plate 340 is used to couple the dual hot vaporizer assembly 301 to the source block 70.
When switching from the electron impact mode 600 to the arc discharge mode 614, as illustrated in
When switching from the arc discharge 614 to the electron impact mode 600, as illustrated in
Obviously, many modifications and variations of the present invention are possible in light of the above teachings. Thus, it is to be understood that, within the scope of the appended claims, the invention may be practiced otherwise than is specifically described above.
This application is a division of U.S. patent application Ser. No. 11/268,005, filed on Nov. 7, 2005 now abandoned, which is a continuation-in-part of commonly owned U.S. patent application Ser. No. 10/170,512, filed on Jun. 12, 2002, now U.S. Pat. No. 7,107,929, issued on Sep. 19, 2006, which is a continuation of International Patent Application No. PCT/US00/33786, filed on Dec. 13, 2000 which, in turn, claims the benefit of and the priority to U.S. Provisional Patent Application No. 60/170,473, filed on Dec. 13, 1999 and U.S. Provisional Application No. 60/250,080, filed on Nov. 30, 2000.
Number | Name | Date | Kind |
---|---|---|---|
2754422 | Lofgrenetal | Jul 1952 | A |
4017403 | Freeman | Apr 1977 | A |
4135093 | Kim | Jan 1979 | A |
4258266 | Robinson et al. | Mar 1981 | A |
4579144 | Lin et al. | Apr 1986 | A |
4845366 | Hoffman et al. | Jul 1989 | A |
4985657 | Campbell | Jan 1991 | A |
5306921 | Tanaka et al. | Apr 1994 | A |
5306922 | O'Connor | Apr 1994 | A |
5497006 | Sferlazzo et al. | Mar 1996 | A |
5523652 | Sferlazzo et al. | Jun 1996 | A |
5576600 | McCrary et al. | Nov 1996 | A |
5607509 | Schumacher et al. | Mar 1997 | A |
5633506 | Blake | May 1997 | A |
5703372 | Horsky et al. | Dec 1997 | A |
5780862 | Siess | Jul 1998 | A |
5904567 | Yamazaki | May 1999 | A |
5939831 | Fong et al. | Aug 1999 | A |
6046546 | Porter et al. | Apr 2000 | A |
6205948 | Guenzel | Mar 2001 | B1 |
6259091 | Eiden et al. | Jul 2001 | B1 |
6288403 | Horsky et al. | Sep 2001 | B1 |
6358431 | Stirling et al. | Mar 2002 | B1 |
6452338 | Horsky | Sep 2002 | B1 |
6479785 | Fugo et al. | Nov 2002 | B1 |
6686595 | Horsky | Feb 2004 | B2 |
6744214 | Horsky | Jun 2004 | B2 |
6777686 | Olson et al. | Aug 2004 | B2 |
6805779 | Chistyakov | Oct 2004 | B2 |
6975073 | Wakalopulos | Dec 2005 | B2 |
7022999 | Horsky et al. | Apr 2006 | B2 |
7107929 | Horsky et al. | Sep 2006 | B2 |
7112804 | Horsky et al. | Sep 2006 | B2 |
7185602 | Horsky et al. | Mar 2007 | B2 |
20030079688 | Walther et al. | May 2003 | A1 |
20030197129 | Murrell et al. | Oct 2003 | A1 |
20040000647 | Horsky | Jan 2004 | A1 |
20040002202 | Horsky et al. | Jan 2004 | A1 |
20050269520 | Horsky et al. | Dec 2005 | A1 |
20060097193 | Horsky et al. | May 2006 | A1 |
20060097645 | Horsky | May 2006 | A1 |
20080087219 | Horsky | Apr 2008 | A1 |
Number | Date | Country | |
---|---|---|---|
20080087219 A1 | Apr 2008 | US |
Number | Date | Country | |
---|---|---|---|
60170473 | Dec 1999 | US | |
60250080 | Nov 2000 | US |
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Parent | 11268005 | Nov 2005 | US |
Child | 11940136 | US |
Number | Date | Country | |
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Parent | PCT/US00/33786 | Dec 2000 | US |
Child | 10170512 | US |
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Parent | 10170512 | Jun 2002 | US |
Child | 11268005 | US |