Patent Number: 044779216
Section: description

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT Generally, the illustrated embodiment of an apparatus 10 for use in X-ray lithographic systems for the manufacture of LS1 and VLS1 circuits, or for X-ray lithography research, comprises a high intensity, soft X-ray lithography source tube 12 and a processing chamber 14 mounted in operative associated therewith. Soft X-ray radiation 16, generated in the well-shielded tube 12, is permitted to escape therefrom only through a window 18, preferably formed of beryllium. The beryllium window 18 separates, in an airtight manner, the X-ray lithography source tube 12 from the processing chamber 14. The X-ray radiation 16 escaping the tube 12 through the window 18 is designed to operate on a work, such as a wafer 20, deposited on a work support 22, with the radiation 16 passing through a suitable mask 24, as known. See U.S. Pat. Nos. 3,742,229 and 3,742,230, mentioned above and assigned to M.I.T. See also U.S. Pat. No. 4,215,192, Buckley, "X-ray Lithography Apparatus and Method of Use," granted July 29, 1980. Preferably, the processing chamber 14 is evacuated and/or filled with an inert gas, such as for example helium, lest the soft X-ray radiation 16 becomes attenuated in air. Soft X-rays are of poorer penetrating power when compared to traditional X-rays. A source of vacuum 26 is shown provided adjacent the processing chamber 14 for evacuating both the chamber 14 and the tube 12, the latter via a suitable hose 28. Inert gas, such as helium, is shown admitted to the chamber 14 via a tube 30 and exiting therefrom via a port 32. The X-ray lithography source tube 12 essentially comprises an electron beam source 34 and a watercooled target 36. Preferably, the electron beam source 34 is a barium impregnated tungsten ring provided with a shield grid 38 and an extraction grid 40. A beam focus tube 42 is positioned concentrically within the electron beam source 34 so as to limit the range of the electron beam spot size on the target 36. Further adjustment in the electron beam spot size on the target 36 is made by varying the voltage applied to the beam focus tube 42. A high-voltage feedthrough 44 provides the power for operating the electron beam source 34, the grids 38 and 40, and the beam focus tube 42. The water cooled target 36 preferably is shaped as an inverted cone, and is multi-layered, as will be more fully described below and with particular reference to FIG. 2. The target 36 is concentrically mounted, and axially displaced from the ring-shaped electron beam source 34, within a suitable jacket assembly 46. Preferably, the jacket assembly 46 is removably secured within the X-ray lithography source tube 12 so as to facilitate the inspection, and exchange if need be, of the target 36. A water inlet-outlet tube assembly 48 is concentrically, and removably, mounted within the jacket assembly 46. Tube assembly 48 is provided to direct a high velocity water flow at the target 36 during the operation of the X-ray lithography apparatus 10. As mentioned and known, an electron beam from the ring-shaped electron beam source 34 is designed to strike the target 36. See the article by J. S. Gaines and R. A. Hansen, quoted above. The impact of the electrons on the target 36 causes some X-ray emission therefrom just because of the sudden deceleration of the electrons when they collide with free electrons in the target material. This bremsstrahlung (meaning "braking radiation" in German) is not as intense, however, as is the X-ray emission emanating directly from the atoms of the target 36 material. This latter X-ray emission occurs when an electron in one of the innermost orbits of the target atom is literally "knocked out" of the target atom by a high energy electron emanating from the electron beam source 34. An electron from the next lowest orbit of the target atom immediately takes the place of the knocked-out missing electron. This change of orbit by the electron in the target atom causes energy to be released from the target 36 as electromagnetic radiation of a particular wavelength, also referred to as line emission. For the inner electrons of atoms with a high atomic number, this radiation is at X-ray wavelength. The X-ray wavelength region is generally divided between a short X-ray radiation band (about 0.5 to about two Angstroms wavelengths) and a soft X-ray radiation band (about two Angstroms to about 100 Angstroms wavelength). In general, shorter wavelength X-rays are less easily absorbed and are, therefore, more penetrating than soft X-rays. Each metal target 36 element possesses a characteristic X-ray spectrum. This characteristic X-ray spectrum may be in the K-region, as for instance a target 36 formed of aluminum, producing K-line radiation; or it may be in the M-region, as for instance a target 36 formed of tungsten, producing M-line radiation; or it may be in the L-region, as for instance a target 36 formed of palladium, producing L-line radiation. A designer of X-ray lithography apparatus is faced, among others, with various hurdles in his quest to come up with an apparatus that has high stability, long lifetime and is relatively maintenance free. With specific respect to designing a target anode, the designer knows that the target must be capable of sustained high intensity operation. This suggests the selection and use of a relatively high-melting-point material. However, the designer also knows that the choice of the target anode material is dictated, for the most part, by its characteristic X-ray emission wavelength, which differs from one target material to the next. This is so since the selected characteristic X-ray emission wavelength for the target anode must also be compatible with the mask 24 and the resist materials used in the X-ray lithographic system. See the above-quoted article by Maldonado et al. The designer also strives to obtain as short an exposure time, and thus to achieve a longer life for the target anode, as he can for the particular resist material used in his X-ray lithographic system. See the above-quoted U.S. Pat. No. 4,215,192 to Buckley. Prompted by these and other design considerations, we have discovered that the multi-layered composite target cone 36 provides the most-desired attributes in terms of high stability, long lifetime, low maintenance and expected short exposure time to the X-ray lithographic apparatus 10 of the invention. A longitudinal section of the multi-layered composite target cone 36 is shown on an enlarged scale in FIG. 2. The composite target cone 36 comprises at least an X-ray generating layer 50 and a water-interface layer 52. The X-ray generating layer 50 preferably is about five micrometers thick and is formed of a member of the class consisting of platinum, silver, palladium, rhodium, molybdenum, tungsten, silicon, aluminum and copper. The methodology of selecting the specific member of this class for the layer 50 will be more fully discussed below. The water-interface layer 52 of the composite target cone 36 is the layer in contact with the cooling water. Here, good thermal contact with the cooling water and high thermal conductivity to the cooling water are of paramount consideration. We consider that best results overall are achieved by selecting for the bulk of the water-interface layer 52, a layer of high thermal conductivity material 54, which preferably is about fourteen mil thick and preferably is formed of copper or silver. Furthermore, this layer of high thermal conductivity material 54 preferably is covered at the water contacting surface by a thin layer 56 of high corrosion resistance, such as a palladium layer of about several micrometers thickness. This thin layer 56 of high corrosion resistance serves to protect the layer 54 of high thermal conductivity from the nucleate boiling effect of the high velocity turbulent cooling water flowing along the backside of the composite target cone 36. We have also found it advantageous to have a further thin layer 58 of a high-melting-point material, such as for instance a 0.2 micrometer thick layer of tantalum, covering the layer 54 of high thermal conductivity material and facing the X-ray generating layer 50. This layer 58 of high-melting-point material serves to protect the layer 54 of high thermal conductivity material from the adverse effects of the very high working temperatures to which the composite target cone 36 gets exposed on the electron beam side. The composite target cone 36, constructed as above described, does not suffer from interdiffusion between the layers and exhibits no cracking problems despite prolonged use. Table 1 provides some calculated performance data, based on experimental work, for the different target elements used as an X-ray generating layer 50 in the composite target cone 36 of the X-ray lithography apparatus 10 of the invention. The electron beam source 34 was a barium-impregnated tungsten ring designed to develop a 10 KW electron beam on the target 36, the X-ray window 18 a one mil thick disk of 3/4" diameter, the X-ray beam 16 take-off angle was 12.5.degree., the X-ray lithography source tube 12 was evacuated to a pressure of 1.times.10.sup.-7 torr, the composite target cone 36 cooled by water at an input water pressure of about 160 psi @ 4 gal/min, and the applied power was: acceleration=20 KV @ 500 mA, cathode filament=20 V @ 10 amp, extractor grid=1 KV @ 30 mA, and the focus tube=3 KV @ 5 mA. Column four of Table 1 shows the radiant intensity, I, from each target element when forming the X-ray generating layer 50 of the composite target cone 36. The radiant intensity, I, is stated in milliwatts per steradian. Column five of Table 1 shows, for each target element forming the X-ray generating layer 50, the expected exposure time, T.sub.E, for PMMA resist. It is to be understood that these exposure times vary considerably for resists faster than PMMA. For example, when using PBS resist and aluminum, palladium or rhodium as the target element forming the X-ray generating layer 50 of the composite target cone 36, exposure times under two minutes have been achieved. The exposure time, T.sub.E, equals Q.sub.A /(.PHI..sub.S .alpha.), WHERE Q.sub.A is 575 J/CM.sup.3, and .PHI..sub.S is the radiant flux density (irradiance) of the resist surface, measured in microwatts per square centimeter, and .alpha. is the absorption coefficient of the resist in cm.sup.-1. TABLE 1 __________________________________________________________________________ X-RAY LITHOGRAPHY TARGET ELEMENT COMPARISON CHARACTERISTIC RADIANT EMISSION THERMAL INTENSITY, I EXPOSURE TARGET WAVELENGTH CONDUCTIVITY MW/SR TIME, T.sub.E ELEMENT .ANG. W/CM/.degree.C. @ 10 KW MIN __________________________________________________________________________ PT(L) 1.31 0.697 229 3233 AG(L) 4.15 4.18 161 222 PD(L) 4.37 0.705 152 211 RH(L) 4.60 0.879 148 196 MO(L) 5.41 1.45 111 200 W(M) 6.98 1.99 19.6 416 SI(K) 7.13 0.216 182 41 AL(K) 8.34 2.15 116 46 CU(L) 13.36 4.59 12 287 __________________________________________________________________________ The use of the composite target cone 36 permits, as mentioned, the ready exchange of one target element for another when working with different resist and mask materials. Thus it has been shown and discribed an X-ray lithography apparatus 10, featuring a composite target cone 36 in an X-ray lithography source tube 12 of the apparatus 10, which apparatus satisfies the objects and advantages set forth above. Since certain changes may be made in the present disclosure without departing from the scope of the present invention, it is intended that all matter described in the foregoing specification or shown in the accompanying drawings, be interpreted in an illustrative and not in a limiting sense.