The thesis includes two parts. Part Ⅰ is the application of phosphate group of dental materials. Part Ⅱ is the application of phosphate group of the adsorbents. In part Ⅰ, One of the major components of the tooth is the phosphate group. Consequently, the derivatives of phosphate groups are used in the resin composites and bonding systems to increase the bond strength in modern density. However, there are several problems in the dental materials such as the shrinkage and unpolymerized monomer in the polymerization process. In order to improve dental restoration to achieve better aesthetic outcomes, fiber posts have been used more frequently. However, the loss of adhesion or detachment of fiber posts from root canals is usually happened.in this thesis, a novel resin cement and bonding agents were developed to increase the bond strength between the bonding agent and collagen. 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. Besides, the hydrogen bond is detected by XPS between bonding agents and dentin. The phosphoric acid groups which is in the bonding agent produce a large amount of hydrogen bonds at the interface with the amino acid groups which is in the collagen to enhance the adhesive strength of the dentin adhesive. According the results,the mechanism of migration between dentin adhesives and collagen is proposed on the adhesive interface. In part Ⅱ, the pollutions of metal ions are harmful to health of creatures. In generally speaking, the adsorption has been used as a suitable and economic water treatment process to remove metal ions. However, high adsorption capacity of adsorbents for rare earth metal ions is not easy to find. In order to improve the adsorption capacity, a nanocomposite adsorbent was synthesized by graphite oxide and phosphate group(GO-Zr-P). The results showed the GO-Zr-P nanocomposite also shown a wide range of pH for Eu+3, La+3 and Ce+3. The adsorption capacity was influenced by the pH value. The maximum adsorption capacity of Eu+3 was 242.42 mg/g at pH 7 and the maximum adsorption capacity of La+3 and Ce+3 at pH 5 were 174.2 mg/g and 156.9 mg/g, respectively. The special property of GO-Zr-P nanocomposite had potential application in industrial wastewater treatment.