In situ decomposition of Ti<sub>2</sub>AlN promoted interfacial bonding in ZnAl-Ti<sub>2</sub>AlN biocomposites for bone repair

Shuai, Cijun; Xue, Lianfeng; Gao, Chengde; Pan, Hao; Deng, Youwen

doi:10.1088/2053-1591/ab6e32

Cited by 4 publications

(4 citation statements)

References 38 publications

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“…Therefore, the tensile strength increased from 203 of ZA27 to 310 MPa of ZA27-Ti 3 AlC 2 biocermets, and the bending strength of ZA27-Ti 3 AlC 2 biocermets increased by 55% than Ti 3 AlC 2 . Similarly, our recently study reported Zn-based biocermet with strong interface bonding ascribed to the in situ reaction between the Zn alloys and Ti 2 AlN [167]. Qia et al [168] fabricated Ti 3 SiC 2 and TiC reinforced Al 2 O 3 -based cermets by the in situ reaction between ceramics reinforcement and Ti matrix.…”

Section: In Situ Reactionsupporting

confidence: 60%

Advances in biocermets for bone implant applications

et al. 2020

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As two promising biomaterials for bone implants, biomedical metals have favorable mechanical properties and good machinability but lack of bioactivity; while bioceramics are known for good biocompatibility or even bioactivity but limited by their high brittleness. Biocermets, a kind of composites composing of bioceramics and biomedical metals, have been developed as an effective solution by combining their complementary advantages. This paper focused on the recently studied biocermets for bone implant applications. Concretely, biocermets were divided into ceramic-based biocermets and metal-based biocermets according to the phase percentages. Their characteristics were systematically summarized, and the fabrication methods for biocermets were reviewed and compared. Emphases were put on the interactions between bioceramics and biomedical metals, as well as the performance improvement mechanisms. More importantly, the main methods for the interfacial reinforcing were summarized, and the corresponding interfacial reinforcing mechanisms were discussed. In addition, the in vitro and in vivo biological performances of biocermets were also reviewed. Finally, future research directions were proposed on the advancement in component design, interfacial reinforcing and forming mechanisms for the fabrication of high-performance biocermets.

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Section: In Situ Reactionsupporting

confidence: 60%

Advances in biocermets for bone implant applications

et al. 2020

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“…In this matter, using the selective laser melting technique, a study found that this process resulted in diffusion of the Al atoms in Ti 2 AlN out of the lattice so that the Al atoms could bond with the matrix forming Zn 7 Al. 99 Also, due to atom diffusion, Ti atoms separated from the Ti 2 AlN. The resulting Zn 7 Al-Ti 2 AlN composite had besides the main Zn enrich phase, Al enrich phase, and Ti 2 AlN phase, two new phases of TiN and Al 0.64 Ti 0.36 which were present at the interface and contributed to improved load transfer.…”

Section: General Overviewmentioning

confidence: 99%

“…The resulting Zn 7 Al-Ti 2 AlN composite had besides the main Zn enrich phase, Al enrich phase, and Ti 2 AlN phase, two new phases of TiN and Al 0.64 Ti 0.36 which were present at the interface and contributed to improved load transfer. 99 A disadvantage of in-situ processing of MMCs is that dispersed materials are limited to only those that are thermodynamically stable in a particular matrix. Also, the size and shape of particles are determined by the kinetics of the process during the nucleation and growth activities.…”

Section: General Overviewmentioning

confidence: 99%

“…The in situ decomposition reaction can be used to obtain strong interfacial bonding. In this matter, using the selective laser melting technique, a study found that this process resulted in diffusion of the Al atoms in Ti 2 AlN out of the lattice so that the Al atoms could bond with the matrix forming Zn 7 Al 99 . Also, due to atom diffusion, Ti atoms separated from the Ti 2 AlN.…”

Section: Production Routes For Mmcsmentioning

confidence: 99%

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Advanced production routes for metal matrix composites

Mussatto

Ahad

Mousavian

et al. 2020

Engineering Reports

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The use of metal matrix composites (MMCs) in a variety of products is significantly increasing with time due to the fact that their properties can be tailored and designed to suit specific applications. However, the future usage of MMC products is very much dependent on their beneficial aspects and hence it is critical to ensure in a robust repeatable manner the superior physical property advantages compared to conventional unreinforced monolithic metal counterparts. Although numerous routes are available for production of MMC products, each of them has their own advantages and disadvantages. This article provides an overview of advanced production routes for MMCs. The discussion also highlights challenges and presents a future prospectus for MMCs. Powder metallurgy and casting routes are still extensively used for production of MMCs. Aluminum alloys are today the most commonly used matrix materials in MMC products.Carbides (eg, SiC, TiC, and B 4 C), carbon allotropes (eg, CNTs and graphene), and alumina (Al 2 O 3) are currently the most used reinforcement materials. Nevertheless, the use of nano and of hybrid reinforcements are seeing increased usage in niche applications. Additive manufacturing (AM) is discussed as a novel production route for MMC products. This process represents a promising method for the production of MMC products.

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Low cytotoxicity, antibacterial property, and curcumin delivery performance of toughness-enhanced electrospun composite membranes based on poly(lactic acid) and MAX phase (Ti3AlC2)

Krasian,

Punyodom,

Molloy

et al. 2024

International Journal of Biological Macromolecules

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In situ decomposition of Ti₂AlN promoted interfacial bonding in ZnAl-Ti₂AlN biocomposites for bone repair

Cited by 4 publications

References 38 publications

Advances in biocermets for bone implant applications

Advances in biocermets for bone implant applications

Advanced production routes for metal matrix composites

Low cytotoxicity, antibacterial property, and curcumin delivery performance of toughness-enhanced electrospun composite membranes based on poly(lactic acid) and MAX phase (Ti3AlC2)

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In situ decomposition of Ti2AlN promoted interfacial bonding in ZnAl-Ti2AlN biocomposites for bone repair

Cited by 4 publications

References 38 publications

Advances in biocermets for bone implant applications

Advances in biocermets for bone implant applications

Advanced production routes for metal matrix composites

Low cytotoxicity, antibacterial property, and curcumin delivery performance of toughness-enhanced electrospun composite membranes based on poly(lactic acid) and MAX phase (Ti3AlC2)

Contact Info

Product

Resources

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In situ decomposition of Ti₂AlN promoted interfacial bonding in ZnAl-Ti₂AlN biocomposites for bone repair