Papers by Author: Lothar Pfitzner

Abstract: The effectiveness of a FOUP (Front Opening Unified Pod) conditioning test bench was tested with respect to the reduction of outgassing materials from FOUP materials and cleanroom compatibility. The equipment uses vacuum and heat to reduce volatile organic compounds from construction material and wafers. Five different analysis methods were used to asses the performance of the equipment with respect to organic, ionic and metal contamination. The experiments showed that the use of heat and vacuum has a positive effect on the organic contamination from FOUPs, and that the equipment is suitable for semiconductor applications in cleanroom environments.

Abstract: Reference samples were produced for development, benchmarking and comparison of analytical techniques based on mass spectroscopy as TD-GCMS and TOF-SIMS and x-ray analysis as TXRF-NEXAFS. Organic contaminants representing plasticizers, disinfectants and flame retardants were chosen. The contaminants were selected with respect to reliable detection using the above analytical techniques. The stability of the reference samples produced with dethylphtalate, triclosane, and tetrabrombisphenol A on silicon stripes or wafers with a diameter of 200 mm was found to be approx. 10 days. The comparison of the techniques showed that the mass spectroscopy methods allowed reliable qualification of organic surface contamination. TD-GCMS quantifies and identifies the volatile organic compounds whereas TXRF quantifies the carbon contamination, especially the non-volatile, on sample surfaces.

Abstract: As a result of shrinking dimensions and technology nodes, nanoelectronics manufacturing and handling processes demand growing requirements to the cleanliness of the air inside cleanrooms and microenvironments. Besides the limitation of particle contamination, the limitation of airborne molecular contamination (AMC) is necessary to ensure yield and quality of nanoelectronics production lines.

Abstract: The continuous dimensional reduction drives the development of metrology, analysis and characterization for nano and micro electronics. An enormous worldwide R&D effort focuses on the understanding and controlling materials properties and dimensions at atomic level. Crucial for groundbreaking new developments is the availability of appropriate analytical infrastructures providing techniques with information depths well adapted to the nanoscaled objects of interest. This requires widely accessible, independent complementary metrology, analytical techniques, and characterization. For example new materials and the demand of improved detection sensitivities for contaminants provide huge challenges for the capabilities of current analysis equipment and expertise. At the same time, the availability of complementary competences is crucial for advancement of analytical methodologies through cross-comparison, round-robin, and benchmarking of results. This paper describes the formation of an independent analytical infrastructure within Europe having the expertise and competence to solve metrology problems for development of nanotechnologies. Furthermore, a strategy is shown to establish independently operating ‘Golden Laboratories’ for complementary and reliable metrology, analysis, and characterization adapted to the requirements of industrial partners.