Patent Number: 06295332&
Section: claims

1. A method of improving x-ray lithography in the sub 100 nm range to create high quality semiconductor devices, for use in the manufacturing of commercial and military semiconductor devices used in phased array radar, missile seeking devices, direct broadcast satellite television receivers, wide band wireless systems, global positioning satellite receivers and cellular telephones, and other equipment said method comprising the steps of: providing for the use and development of horizontal beams from a synchrotron or point source of x-ray beams;  preparing of submicrometer, transverse horizontal and vertical stepper stages and frames;  providing a stepper base frame for the proper housing and mating of the x-ray beam;  minimizing the effects of temperature and airflow control by means of an environmental chamber;  transporting, handling and prealigning wafers and other similar items for tight process control;  improving the control and sensing of positional accuracy through the use of differential variable reluctance transducers;  controlling the continuous gap and all six degrees of freedom of the wafer being treated with a multiple variable stage control;  incorporating alignment systems using unambiguous targets to provide data to align one level to the next;  using beam transport, shaping or shaping devices to include x-ray point sources;  using an inline collimator or concentrator for collimating or concentrating the x-ray beams; and  imaging the mask pattern at the precise moment for optimum effectiveness.  said using and developing of horizontal beams from a synchrotron or point source of x-ray beams step comprises the use of a beamline in parallel with the z axis.  said preparing of submicrometer, transverse horizontal and vertical stepper stages and frames step comprises providing a light weight, honeycomb structure;  said preparing of submicrometer, transverse horizontal and vertical stepper stages and frames step further comprises providing a air or gaseous bearing;  said preparing of submicrometer, transverse horizontal and vertical stepper stages and frames step further comprises providing vacuum clamping and mating surfaces;  said preparing of submicrometer, transverse horizontal and vertical stepper stages and frames step further comprises providing active weight compensation;  said preparing of submicrometer, transverse horizontal and vertical stepper stages and frames step further comprises linear actuators; and  said preparing of submicrometer, transverse horizontal and vertical stepper stages and frames step further comprises a fine alignment flexure stage of transverse horizontal and vertical nanometer stages.  said providing a light weight, honeycomb structure step comprises the use of at least one composite material.  said providing a stepper base frame for the proper housing and mating of the x-ray beam step comprises providing beam alignment and vibration insulation techniques when connecting the stationary x-ray synchrotron or point source.  said minimizing the effects of temperature and airflow control by means of an environmental chamber step comprises controlling the temperature and humidity; and  said minimizing the effects of temperature and airflow control by means of an environmental chamber step further comprises minimizing particle molecular contamination.  said transporting handling and prealigning wafers and other similar items for tight process control step comprises using a cluster like environment in the coating, pre-baking, aligning and exposing, post baking and quality control processes.  said improving the control and sensing of positional accuracy through the use of differential variable reluctance transducers step comprises providing positional feedback of the six degrees of freedom alignment stage.  said controlling the continuous gap and all six degrees of freedom of the wafer being treated with a multiple variable stage control step comprises using a device having a cross coupled gantry design.  said incorporating alignment systems using unambiguous targets to provide data to align one level to the next level step comprises using multiple bright field optical microscopes in order to provide x, y and z, magnification and rotational data; and  said incorporating alignment systems using unambiguous targets to provide data to align one level to the next level step further comprises using an additional imaging broad band interferometer alignment system for providing precise alignment of wafer levels and gap controls during x-ray exposure and imaging. 2. A method of improving x-ray lithography in the sub 100 nm range to create high quality semiconductor devices, according to claim 1, wherein: 3. A method of improving x-ray lithography in the sub 100 nm range to create high quality semiconductor devices, according to claim 1, wherein: 4. A method of improving x-ray lithography in the sub 100 nm range to create high quality semiconductor devices, according to claim 3, wherein: 5. A method of improving x-ray lithography in the sub 100 nm range to create high quality semiconductor devices, according to claim 1, wherein: 6. A method of improving x-ray lithography in the sub 100 nm range to create high quality semiconductor devices, according to claim 1, wherein: 7. A method of improving x-ray lithography in the sub 100 nm range to create high quality semiconductor devices, according to claim 1, wherein: 8. A method of improving x-ray lithography in the sub 100 nm range to create high quality semiconductor devices, according to claim 1, wherein: 9. A method of improving x-ray lithography in the sub 100 nm range to create high quality semiconductor devices, according to claim 1, wherein; 10. A method of improving x-ray lithography in the sub 100 nm range to create high quality semiconductor devices, according to claim 1, wherein: