Carbon steel is the most commonly used material nowadays because of its superior mechanical properties and low cost. Hot rolling is the only way to process a billet steel to steel plate. Under harsh conditions, such as homogenization at 1050 ºC ~ 1280 ºC for 1 ~ 2 h, the steel plate tends to suffer severe oxidation, which not only reduces the utilization efficiency of material, but also impacts on the following deoxidizing process before cold rolling. For low carbon steel, Si and Cr are added as deoxidizing agent and anti-corrosion elements. Cu, on the other hand, is added for the subsequent precipitation of Cu nano particles. However, under high temperature conditions, liquid Cu tends to precipitate at the surface and grain boundaries, which may lead to hot shortness during the hot rolling process. This research studied the effect of Si, Cr and Cu on oxide scale formation during hot rolling. Six as-received hot rolling specimens with different concentrations of Si, Cr and Cu were employed through high temperature oxidation experiment. The hot rolling process begins with reheating process, which is held at 1230 ºC for 2 h, followed by rough rolling, finish rolling, and coiling. The final coiling steel plates were characterized using OM, SEM, EDS, EBSD, EPMA. The high temperature oxidation experiment is conducted at 1150 ºC for 1 min, followed by cooling to room temperature in furnace. The atmosphere of oxidation experiment is kept in Ar to prevent from forming scale during heating and cooling processes. The various steel samples after high temperature oxidation were characterized using OM, SEM/EDS, EBSD, EPMA, and TEM to gain better understanding on the scale microstructure and precipitation mechanism. Experimental results show that Si, Cr, Cu precipitating at the interface tend to reduce the scale thickness. Moreover, Si and Cr react with FeO to form Fayalite and Chromite structure, which strengthens the adhesion between the scale and the steel substrate. For the sample with 0.1 wt% Cu, Cu precipitates at the interface as a continuous layer. For the sample with 0.3 wt% Cu, Cu precipitates not only at the interface but also at the grain boundaries of steel as Cu nano particles. In the presence of Si, Cr and Cu, Cu particles form and disperses into the subscale composed of Fayalite and Chromite. It is thus inferred that during high temperature oxidation, Si and Cr ameliorate hot shortness caused by liquid Cu.