I. Introduction

Hard disk drives (HDDs) have been one of the most dominant information storage devices. With continuous increase in areal density, the head media spacing (HMS), containing head overcoat, media overcoat, perfluoropolyether (PFPE) lubricant film, and fly height, is expected to reduce to 6.5 nm for 1 HDDs so that an accurate description and nanoscopic control of the head disk interface (HDI) becomes critical for the HDD performance and reliability [1]. With such stringent space requirements within the HMS, demand for novel techniques to investigate the HDI dynamics increases. Multiscale modeling has recently opened a new paradigm by providing a novel methodology of molecular design criteria and potentially gives several order of magnitude advances in nano-technology. The HDI can be an excellent benchmark for multiscale modeling since the system includes molecular scale thin lubricant film adjacent to the rarified gas flow region between the head and the disk, which can be examined by nano/meso/macro-scopic modeling. In addition, alternative technology like heat assisted magnetic recording (HAMR), requires nano/micro scale heat transfer modeling.