Babak Jahani scite author profile

Babak Jahani

2Publications

20Citation Statements Received

171Citation Statements Given

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104

167

Affiliations

North Dakota State University

Publications

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UV-Curable Cellulose Nanofiber-Reinforced Soy Protein Resins for 3D Printing and Conventional Molding

Mohawk

Jahani

et al. 2020

ACS Appl. Polym. Mater.

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Plastic wastes pose a serious threat to the environment and there has been strong interest in developing soy protein isolate (SPI)-based plastics to reduce the use of traditional petroleum-based ones. However, the use of SPI plastics has been hindered due to their inferior mechanical properties and poor water resistance compared with traditional plastics. In this work, SPI plastics with significantly improved mechanical properties and water resistance were developed using UV-curable SPI resin and UVcurable cellulose nanofibers. Three UV-curable materials, i.e., methacrylated SPI (MSPI), methacrylated cellulose nanofibrils (MCNF), and methacrylated cellulose nanocrystals (MCNC), were produced through methacrylation of SPI, CNF, and CNC, respectively. Methacrylation of the materials and UV curing of the resins were confirmed using Fourier-transform infrared spectroscopy. Uniform dispersion of CNC, CNF, MCNC, or MCNF in the resin was confirmed by scanning electron microscopy and X-ray diffraction. The tensile properties and water resistance of the resins were found to improve with increasing curing time and degree of methacrylation. The incorporation of CNC, CNF, MCNC, and MCNF further improved the mechanical and water resistance performance of the resins, with the MCNF leading to the largest improvement. UV curing and the cellulose nanofibers evidently worked synergistically to improve the properties of the resins. This study demonstrated a method and formulations to produce the SPI plastics with exceptional properties. Furthermore, the potential of this resin in 3D printing and conventional plastic molding was demonstrated.

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Effect of volume fraction of reinforcement phase on mechanical behavior of ultra-high-temperature composite consisting of iron matrix and TiB₂ particulates

Jahani

Jazi

Azarmi

et al. 2017

Journal of Composite Materials

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Recently, ultra-high-temperature ceramics have received abundance attention due to growing demand of new materials for extreme service conditions. In this study, titanium diboride particles as an ultra-high-temperature ceramic material have been used to reinforce iron matrix to fabricate a metal matrix composite. Iron–titanium diboride composite samples with different volume fractions of titanium diboride fabricated using powder metallurgy route. Physical, microstructural and mechanical properties of metal matrix composite were studied. The results indicated that addition of titanium diboride only up to 20 vol% increased mechanical properties of the processed composite. Microstructure-based finite element analysis could verify the experimental results.

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Babak Jahani

UV-Curable Cellulose Nanofiber-Reinforced Soy Protein Resins for 3D Printing and Conventional Molding

Effect of volume fraction of reinforcement phase on mechanical behavior of ultra-high-temperature composite consisting of iron matrix and TiB₂ particulates

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Babak Jahani

UV-Curable Cellulose Nanofiber-Reinforced Soy Protein Resins for 3D Printing and Conventional Molding

Effect of volume fraction of reinforcement phase on mechanical behavior of ultra-high-temperature composite consisting of iron matrix and TiB2 particulates

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Product

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Effect of volume fraction of reinforcement phase on mechanical behavior of ultra-high-temperature composite consisting of iron matrix and TiB₂ particulates