Fiber posts have been used more frequently in dental restoration to achieve better aesthetic outcomes. However, the loss of adhesion or detachment of fiber posts from root canals is the primary cause of failure; therefore, the purpose of this study is to formulate a novel type of resin cement that improves the bonding strength of fiber posts at the dentin-cement interface. 　　Three concentrations (30, 35, and 40 wt%) of bis[2-(methacryloyloxy)-ethyl] phosphate (2MP) were prepared as key dentin bonding agent components and isobornyl acrylate (IBOA) and ethylhexylacrylate (EHA) were used as key components to fabricate the resin cement. The specimens were tested after cementation 24 hours and storage in distilled water at 37℃for 5 months to observe long term stability by evaluating the bond strength. The adhesive strength of these fabricated cements to coronal and root canal dentin were tested using a microtensile bond test, push-out bond test, and fracture toughness test, and to make comparisons with 4 commercially available resin cements (NX3, Variolink II, RelyX Unicem, and Panavia F 2.0). In addition, the shelf life of bonding agent was tested by infrared spectroscopy (ATR-FTIR) and microtensile test. Furthermore, we propose a model which explores the underlying mechanism of high bond strength between bonding agent and collagen using depth profiling of X-ray photoelectron spectroscopy (XPS). The interface of the adhesive and dentin was observed under transmission electron microscope (TEM). 　　The results of the bond strength tests show that 30%-2MP, 35%-2MP, and 40%-2MP with IBOA and EHA produce greater or similar adhesion to dentin compared with the 4 commercial resin cements. The shelf life test indicates that inhibitors can prevent spontaneous initiation and promote shelf life. The results of XPS show, when bonding agent was cast on the dentin, the phosphate in the bonding agent can migrate to collagen side and produce more hydrogen-bond to increase bond strength. TEM revealed the morphology of dentin- adhesive interface, with a 5-6 μm-thick hybrid layer. 　　Within the results of this study, the adhesion to the coronal and root canal dentin can be improved significantly by the addition of key components (2MP, IBOA, and EHA) to resin cements. These components exhibit the potential for the development of a novel type of resin cement.