Mahendra Thunga scite author profile

Controlled degradation and transiency of materials is of significant importance in the design and fabrication of degradable and transient biomedical and electronic devices and platforms. Here, the synthesis of programmable biodegradable and transient insulating polymer films is reported, which have sufficient physical and chemical properties to be used as substrates for the construction of transient electronics. The composite structure can be used as a means to control the dissolution and transiency rate of the polymer composite film. Experimental and computational studies demonstrate that the addition of gelatin or sucrose to a PVA polymer matrix can be used as a means to program and either slow or enhance the transiency of the composite. The dissolution of the polymer composites are fitted with inverse exponential functions of different time constants; the lower time constants are an indication of faster transiency of the polymer composite. The addition of gelatin results in larger time constants, whereas the addition of sucrose generally results in smaller time constants.

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Structural interpretations of deformation and fracture behavior of polypropylene/multi-walled carbon nanotube composites

Ganß¹,

Satapathy²,

Thunga³

et al. 2008

Acta Materialia

150

107

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Processing and characterization of low-cost electrospun carbon fibers from organosolv lignin/polyacrylonitrile blends

Ding

Thunga

et al. 2016

Carbon

181

102

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Bio-renewable precursor fibers from lignin/polylactide blends for conversion to carbon fibers

Thunga

Chen

Grewell

et al. 2014

Carbon

150

102

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Lignin, a highly aromatic biopolymer extracted as a coproduct of wood pulping, was investigated as a suitable precursor for carbon fibers. Lignin was chemically modified and blended with poly(lactic acid) (PLA) biopolymer before melt spinning into lignin fibers. The chemical modification of raw lignin involved butyration to form ester functional groups in place of polar hydroxyl (-OH) groups, which enhanced the miscibility of lignin with PLA. Fine fibers were extracted and spooled continuously from lignin/PLA blends with an overall lignin concentration of 75 wt.%. The influence of chemical modification and physical blending of lignin with PLA on the resulting fiber was studied by analyzing the microstructure of the fibers using transmission electron microscopy (TEM) and scanning electron microscopy (SEM). The influence of blend composition on the phase behavior was studied by differential scanning calorimetry (DSC). The effect of composition on the mechanical properties was studied by tensile tests of the lignin/PLA blend fibers. The thermal stability and carbon yield of the blended fibers with different concentrations of lignin were characterized by thermogravimetric analysis (TGA). The microstructure analysis of carbon fibers produced from lignin/PLA blends revealed composition dependent microporous structures inside the fine fibers.

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Mahendra Thunga

Study of Physically Transient Insulating Materials as a Potential Platform for Transient Electronics and Bioelectronics

Structural interpretations of deformation and fracture behavior of polypropylene/multi-walled carbon nanotube composites

Processing and characterization of low-cost electrospun carbon fibers from organosolv lignin/polyacrylonitrile blends

Bio-renewable precursor fibers from lignin/polylactide blends for conversion to carbon fibers

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