Abstract: An aluminum borate whisker reinforced and toughened non-metallic matrix composite is provided, which specifically includes a non-metallic material reinforced and toughened with aluminum borate whiskers. The composite exhibits a higher bending strength and fracture toughness and a higher wear resistance. A method for preparing the composite is also provided. The method includes mixing the aluminum borate whiskers and the non-metallic material to form a mixture; and sintering the mixture by a vacuum hot press method, or molding the mixture.

Abstract: Disclosed is a multi-model predictive control method for a Pichia pastoris fermentation process, including: dividing prior data into m training sample clusters by using a fuzzy C-means algorithm (FCM); obtaining, for each sample cluster, a corresponding prediction model by using a least squares support vector machine (LSSVM) and an improved particle swarm optimization method (IPSO); then, designing a corresponding predictive controller; and finally, calculating a deviation between an output of an object and an output of each sub-prediction model at each sampling time to establish a multi-model fusion predictive controller. According to the method, the adaptive ability of the model is improved and an actual state of a nonlinear system is described more accurately.

Abstract: An aluminum borate whisker reinforced and toughened non-metallic matrix composite is provided, which specifically includes a non-metallic material reinforced and toughened with aluminum borate whiskers. The composite exhibits a higher bending strength and fracture toughness and a higher wear resistance. A method for preparing the composite is also provided. The method includes mixing the aluminum borate whiskers and the non-metallic material to form a mixture; and sintering the mixture by a vacuum hot press method, or molding the mixture.

Abstract: An implant device includes a polymer tube including an enclosed inner space, and a mixture of a hydrogel and a plurality of nanoparticles within the enclosed inner space. Each of the plurality of nanoparticles includes a shell, payload within the shell, and one or more photothermal agents on a surface of the shell. A wall of the polymer tube includes one or more layers of nanoporous polymer sheets including a plurality of pores. The dimension of the nanoparticles is greater than the dimension of the pores, and the dimension of the payload is smaller than the dimension of the pores.

Abstract: An implant device includes a polymer tube including an enclosed inner space, and a mixture of a hydrogel and a plurality of nanoparticles within the enclosed inner space. Each of the plurality of nanoparticles includes a shell, payload within the shell, and one or more photothermal agents on a surface of the shell. A wall of the polymer tube includes one or more layers of nanoporous polymer sheets including a plurality of pores. The dimension of the nanoparticles is greater than the dimension of the pores, and the dimension of the payload is smaller than the dimension of the pores.