Abstract Pristine graphene has demonstrated ballistic electron transport at room temperature and nearly transparency optical properties. Nevertheless, the absence of band gap in graphene sets an obstacle for its application in graphene based transistor. Band gap in graphene can be modified by introducing nano-scale defects in it. There exist several promising ways for defect introduction in graphene to date. Among them, scanning probe lithography (SPL) with atomic force microscope (AFM) is a mask-less method for fabricating nano-meter-scale structure in various materials, including graphene. With the same negative bias at the AFM probe tip, nano-meter-scale-defect protrusions or depression could be produced on graphene supported on a substrate. Conventionally, SPL process on graphene results in reaction of decomposed OH- ions and graphene in the water meniscus formed between the tip and sample surface. The protrusion and depression are usually explained in term of incomplete (non-volatile) or complete oxidation (volatile) of carbon atom in graphene, respectively. The scenario above implies that sp3 and vacancy type defects are expected to dominate in protrusion and depression structure, respectively. Recently, Raman spectroscopy has been proved to be an effective tool for probing different defect type in graphene by measuring the ratio of D and D’ intensities (ID/ID’). However, we found that both SPL structures are composed of vacancy defect from ID/ID’. Micro-Photoelectron microscopy (μ-PEM) further reveals weak presence of C-O bonding around the C 1s peak. Instead, strong distortion of C-C bonds and evidence of strain around the SPL patterns are found by both μ-RS and μ-PEM. We conclude that protrusion topography is not result of sp3 partial oxide. Rather, it is probable that room temperature recombination of distorted carbon bond after the ion impact or volatile oxidation by SPL process is the deterministic factor for resultant topography.