摘要
Various semi-interpenetrating polymer network(semi-IPN) hydrogels composed of pore-forming agent polyethylene glycol(PEG), acrylic acid(AA) and acrylamide(AM) were prepared by using free radical polymerization with a two-step method. The chemical structures of the synthesized hydrogels were characterized by FTIR spectroscopy and the morphologies were studied by scanning electron microscopy(SEM) method. The swelling properties, such as the p Hresponsive behavior, salt sensitivity, oscillatory swelling/de-swelling behaviors in different solutions with various p H values and self-oscillating behaviors in bath p H oscillator were investigated in detail. The results revealed that the prepared hydrogels exhibited high p H sensitivity and excellent salt sensitivity when the p H values of the medium changes from 3.0 and 7.0 and well reversible properties by undergoing a number of swelling/de-swelling recycles. In particular, the hydrogels exhibited self-oscillation behavior in a closed system containing Br O3?-SO32?-Fe(CN)64?-H+. This study may create a new possibility as biomaterial for new self-walking actuators and other devices.
Various semi-interpenetrating polymer network(semi-IPN) hydrogels composed of pore-forming agent polyethylene glycol(PEG), acrylic acid(AA) and acrylamide(AM) were prepared by using free radical polymerization with a two-step method. The chemical structures of the synthesized hydrogels were characterized by FTIR spectroscopy and the morphologies were studied by scanning electron microscopy(SEM) method. The swelling properties, such as the p Hresponsive behavior, salt sensitivity, oscillatory swelling/de-swelling behaviors in different solutions with various p H values and self-oscillating behaviors in bath p H oscillator were investigated in detail. The results revealed that the prepared hydrogels exhibited high p H sensitivity and excellent salt sensitivity when the p H values of the medium changes from 3.0 and 7.0 and well reversible properties by undergoing a number of swelling/de-swelling recycles. In particular, the hydrogels exhibited self-oscillation behavior in a closed system containing Br O3?-SO32?-Fe(CN)64?-H+. This study may create a new possibility as biomaterial for new self-walking actuators and other devices.
基金
financially supported by the Basic Project of Science and Research of Colleges and Universities of Gansu Province(No.5001-109)
the Natural Science Foundation of Gansu Province(No.1010 RJZA015)
