Graphite is the mostly used anode materials for lithium ion batteries nowadays; however, the commercial batteries made of generally suffer un-satisfactory performance at low temperature because of the low ion conductivity of liquid electrolytes adopting ethylene carbonate (EC) and ethyl methyl carbonate (EMC) with above room temperature melting points as the major ingredients. Propylene carbonate (PC) with a sub-zero melting point is considered as an strong alternative for the liquid electrolytes to achieve better lower temperature performance. However, PC would infiltrate into the natural graphite (NG) particles during cycling, causing exfoliation of NG and collapse of the active particles, eventually structural breakdown of the electrode To address this issue, we develop an artificial solid electrolyte interphase (A-SEI) layer using custom made sulfonated chitosan-graft-polyethylene oxide (OSCS-g-PEO), which could be coated on NG particles via a simple solution coating process. The A-SEI possesses good lithium ion conductivity, high mechanical strengths with certain flexibility, which are demonstrated to effective improve the cycling stability when PC-containing electrolytes are used. With the presence of PC-containing electrolytes, the Li//LE//pristine NG cell exhibits an initial capacity significantly higher than the theoretical capacity of NG, indicating the intercalation of excess lithium ion due to PC infiltration. In contrast, the Li//LE//A-SEI-modified NG cell approaches the theoretical capacity of NG, suggesting the penetration of PC is successfully suppressed. When cycling at 0.5C/0.5C, the former shows noticeable capacity rollover after 160 cycles, while the latter one maintained stable operation beyond 200 cycles. Further microstructure analysis, including SEM and XPS, indicates the A-SEI could effectively hamper undesired SEI thickening and retain the integrity of the NG particles, therefore to extend the lifespan of batteries using PC-rich electrolytes. Moreover, the A-SEI should also suppress lithium dendrite formation demonstrated by the over-lithiation experiments to improve the battery safety. We also evaluate the performance of a Li//LE//A-SEI-modified NG cell at 0°C using PC-containing electrolytes. A 70% capacity retention and over than 99.8% Columbic efficiency is achieved after 200 cycles; while the reference one using PC-free electrolytes shows only 20% capacity retention and less than 97% CE under the same setup with severe polarization after 200 cycles. This observation assure the practicality of the combination of OSCS-g-PEO A-SEI modified NG anode and PC-rich electrolytes for low-temperature operation.