Ramakrishnan Vaidyanathan1, Charlotte Kwok2, and Edmund G. Seebauer1. (1) University of Illinois, Department of Chemical Engineering, 600 S. Mathews, Urbana, IL 61802, (2) Chemical Engineering, University of Illinois, Department of Chemical Engineering, 600 S. Mathews, Urbana, IL 61802
Forming extremely shallow pn junctions with very low electrical resistance is becoming a large stumbling block to the continued scaling of microelectronic device performance according to Moore's Law. We have developed a technology based on surface chemistry that holds great promise for simultaneously reducing junction depth and increasing activation for dopants implanted into silicon. The approach uses the surface as a large controllable “sink” that removes Si interstitials selectively over dopant interstitials. We have discovered a new way to employ adsorption at the surface for this task: adjusting the intrinsic loss rate of interstitials to the surface. We control the interstitial loss rate to the surface by saturating dangling bonds using adsorbed nitrogen (introduced as ammonia) before implantation or the subsequent annealing step. To demonstrate such effects, we have measured SIMS profiles of arsenic and boron implanted into Si. The annealed profiles with an atomically clean surface show little diffusional spreading from the as-implanted profile, while the profiles with adsorbed N change much more. For arsenic, the proportion of electrically active dopant (as measured by sheet resistance) is indeed highest for the clean surface.