Achieving homogeneous plastic deformation in metallic glasses is a long-standing goal yet to be solved in materials science. Here we investigate the effect of ion irradiation on the plastic deformation behavior of ZrC...Achieving homogeneous plastic deformation in metallic glasses is a long-standing goal yet to be solved in materials science. Here we investigate the effect of ion irradiation on the plastic deformation behavior of ZrCu/ZrCuNiAlSi amorphous/amorphous nanolaminates(A/ANLs) via nanoindentation testing. The experimental results indicate a dramatic change in deformation mode from multiple shear banding events to homogeneous compressive deformation before and after ion irradiation on the A/ANLs in the areas underneath the indenter. Ion irradiation-induced changes of both fraction and distribution of free volume inside each constituent layer and interfacial state in the A/ANLs may be responsible for the unusual homogeneous deformation behavior. Our results suggest that the mechanical property of A/ANLs could be modified by tuning both the inner and interfacial structure via ion irradiation.展开更多
Dentin bonding is a dynamic process that involves the penetration of adhesive resin monomers into the extrafibrillar and intrafibrillar demineralized collagen matrix using a wet-bonding technique.However,adhesive resi...Dentin bonding is a dynamic process that involves the penetration of adhesive resin monomers into the extrafibrillar and intrafibrillar demineralized collagen matrix using a wet-bonding technique.However,adhesive resin monomers lack the capacity to infiltrate the intrafibrillar space,and the excess water that is introduced by the wet-bonding technique remains at the bonding interface.This imperfectly bonded interface is inclined to hydrolytic degradation,severely jeopardizing the longevity of bonded clinical restorations.The present study introduces a dentin bonding scheme based on a dry-bonding technique,combined with the use of extrafibrillar demineralization and a collagen-reactive monomer(CRM)-based adhesive(CBA).Selective extrafibrillar demineralization was achieved using 1-wt%high-molecular weight(MW)carboxymethyl chitosan(CMCS)within a clinically acceptable timeframe to create a less aggressive bonding substance for dentin bonding due to its selectively extrafibrillar demineralization capacity.CMCS demineralization decreased the activation of in situ collagenase,improved the shrinking resistance of demineralized collagen,and thus provided stronger and more durable bonding than traditional phosphoric acid etching.The new dentin bonding scheme that contained CMCS and CBA and used a dry-bonding technique achieved an encouraging dentin bonding strength and durability with low technical sensitivity.This bonding scheme can be used to improve the stability of the resin-dentin interface and foster the longevity of bonded clinical restorations.展开更多
基金financial support from the National Natural Science Foundation of China (No. 51471131)the Natural Science Foundation of Shaanxi Province (No. 2019TD-020)+4 种基金National Science Basic Research Plan in shaanxi Province of China (No. 2020JM-41)financial support from the Fundamental Research Funds for the Central Universities (No. 021314380118)the Natural Science Foundation of Jiangsu Province, China (No. BK20180266)financial support from Fundamental Research Funds for the Central UniversitiesNational Science Basic Research Plan in shaanxi Province of China (No. 2020JM-33)。
文摘Achieving homogeneous plastic deformation in metallic glasses is a long-standing goal yet to be solved in materials science. Here we investigate the effect of ion irradiation on the plastic deformation behavior of ZrCu/ZrCuNiAlSi amorphous/amorphous nanolaminates(A/ANLs) via nanoindentation testing. The experimental results indicate a dramatic change in deformation mode from multiple shear banding events to homogeneous compressive deformation before and after ion irradiation on the A/ANLs in the areas underneath the indenter. Ion irradiation-induced changes of both fraction and distribution of free volume inside each constituent layer and interfacial state in the A/ANLs may be responsible for the unusual homogeneous deformation behavior. Our results suggest that the mechanical property of A/ANLs could be modified by tuning both the inner and interfacial structure via ion irradiation.
基金This work was supported by National Natural Science Foundation of China(81720108011,81801009,81460107,81970972 and 82001110)the program for Changjiang Scholars and Innovative Research Team in University(No.IRT13051).
文摘Dentin bonding is a dynamic process that involves the penetration of adhesive resin monomers into the extrafibrillar and intrafibrillar demineralized collagen matrix using a wet-bonding technique.However,adhesive resin monomers lack the capacity to infiltrate the intrafibrillar space,and the excess water that is introduced by the wet-bonding technique remains at the bonding interface.This imperfectly bonded interface is inclined to hydrolytic degradation,severely jeopardizing the longevity of bonded clinical restorations.The present study introduces a dentin bonding scheme based on a dry-bonding technique,combined with the use of extrafibrillar demineralization and a collagen-reactive monomer(CRM)-based adhesive(CBA).Selective extrafibrillar demineralization was achieved using 1-wt%high-molecular weight(MW)carboxymethyl chitosan(CMCS)within a clinically acceptable timeframe to create a less aggressive bonding substance for dentin bonding due to its selectively extrafibrillar demineralization capacity.CMCS demineralization decreased the activation of in situ collagenase,improved the shrinking resistance of demineralized collagen,and thus provided stronger and more durable bonding than traditional phosphoric acid etching.The new dentin bonding scheme that contained CMCS and CBA and used a dry-bonding technique achieved an encouraging dentin bonding strength and durability with low technical sensitivity.This bonding scheme can be used to improve the stability of the resin-dentin interface and foster the longevity of bonded clinical restorations.
