Kelly Malone

Nanoporous Materials Integration Into Advanced Microprocessors

Future microprocessor technologies will require interlayer dielectric (ILD) materials with a dielectric constant (κ-value) less than 2.5. Organosilicate glass (OSG) materials must be nanoporous to meet this demand. However, the introduction of nanopores creates many integration challenges. These challenges include 1) integrating nanoporous films with low mechanical strength into conventional process flows, 2) managing etch profiles, 3) processinduced damage to the nanoporous ILD, and 4) controlling the metal/nanoporous ILD interface. This paper reviews research to maximize mechanical strength by engineering optimal pore structures, controlling trench bottom roughness induced by etching and understanding its relationship to pore size, repairing plasma damage using silylation chemistry, and sealing a nanoporous surface for barrier metal (liner) deposition.

193 lithography and RELACS processing for BEOL lithography

This paper presents data obtained in developing a process using 193 nm lithography and the RELACS contact hole shrink technique. For the line/space levels, process windows showing resist performance using chrome on glass masks are presented. Data showing feature size linearity and the requirements for optical proximity correction (OPC) are presented. Some of the OPC trends observed are discussed and compared to results obtained using 248 nm lithography. Image shortening data also compares the results obtained in 193 and 248 lithography. Etch results for the new 193 resists are given and show the etch resistance of this relatively new class of photoresist materials. For contact hole and via levels, results using 193 lithography and COG masks show the importance of the mask error enhancement factor (MEEF), print bias and resolution. Due to the relative immaturity and performance of contact hole resists for 193 lithography, Clariants RELACS process was investigated with 248 nm resists. In this process contact holes are printed larger than required and then reduced to the desired size by a chemical shrink process. Results obtained with 248 lithography using state of the art resists and phase shift masks are discussed. It was found that 140 nm contact holes with at least 0.5 micrometer depth of focus could be obtained. Cross sections and process windows are shown.