For the purpose of ameliorating the temperature resistance of nanopolymer particles, a kind of hyper-crosslinked polymer, named Zr-AM/NVP/AMPS [main monomer acrylamide (AM), functional monomers N-vinylpyrrolidone (NVP), and 2-acrylamide-2-methylpropanesulfonic acid (AMPS)] with size varying from 100 to 170 nm and special doublecross-linked architectures, were prepared through inverse emulsion copolymerization of organic cross-linking agent N, Nmethylene bis acrylamide (MBA), and metal cross-linking agent zirconium acetate (Zr) as a cross-linking system, ammonium persulfate (KPS) as the initiator for the first time. The surface morphology, pore structure, particle size distribution, crosslinking architecture and element distribution of nanoparticles were fully characterized with several means including SEM, TEM, LPSA, BET, FT-IR, 13 CNMR, elemental analysis, and long-term thermal stability. The SEM, TEM, LPSA, and BET experimental results indicate that the nanopolymer particle exhibits regular spherical shape and smooth surface, has mesopores ranging from 4.9−7.1 nm with a typical diameter centered (BJH pore size distribution) at ∼5.7 nm. FT-IR, 13 CNMR, and elemental analysis experimental results indicate that the monodisperse mesoporous networks nanopolymer particles were crosslinked by AM, AMPS, NVP, MBA, and Zr. Compared to the ordinary AM/NVP/AMPS nanoparticles, significantly enhanced high-temperature thermal stability was found under 150 °C. A core displacement experiment showed how the nanopolymer particles could effectively plug the porous media for water control and oil recovery improvement even after aging at 150 °C for three months. Oil recovery is increased by 13% on the basis of water flooding. Zr-AM/NVP/AMPS nanoparticles with doublecross-linked architectures can be a great help for petroleum engineers to better apply this deep profile control and flooding technology.
