V. Marinov scite author profile

Currently, most carbon aerogels are based on carbon nanotubes (CNTs) or graphene, which are produced through a catalyst‐assisted chemical vapor deposition method. Biomass based organic aerogels and carbon aerogels, featuring low cost, high scalability, and small environmental footprint, represent an important new research direction in (carbon) aerogel development. Cellulose and lignin are the two most abundant natural polymers in the world, and the aerogels based on them are very promising. Classic silicon aerogels and available organic resorcinol–formaldehyde (RF) or lignin–resorcinol–formaldehyde (LRF) aerogels are brittle and fragile; toughening of the aerogels is highly desired to expand their applications. This study reports the first attempt to toughen the intrinsically brittle LRF aerogel and carbon aerogel using bacterial cellulose. The facile process is catalyst‐free and cost‐effective. The toughened carbon aerogels, consisting of blackberry‐like, core–shell structured, and highly graphitized carbon nanofibers, are able to undergo at least 20% reversible compressive deformation. Due to their unique nanostructure and large mesopore population, the carbon materials exhibit an areal capacitance higher than most of the reported values in the literature. This property makes them suitable candidates for flexible solid‐state energy storage devices. Besides energy storage, the conductive interconnected nanoporous structure can also find applications in oil/water separation, catalyst supports, sensors, and so forth.

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52‐4: Laser‐Enabled Extremely‐High Rate Technology for µLED Assembly

Marinov

2018

Symp Digest of Tech Papers

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We developed a complete wafer-to-panel technology for extremely high rate assembly of µLEDs. The process involves transferring the µLEDs directly from the source epi-wafer to a quartz carrier from where they are selectively transferred to the panel using our Laser-Enabled Massively Parallel Transfer method with >100M units/hr. Author KeywordsµLED assembly; massively-parallel transfer; µLED display.

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Laser-assisted ultrathin die packaging: Insights from a process study

Marinov

Swenson

Atanasov

et al. 2013

Microelectronic Engineering

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Noncontact Selective Laser-Assisted Placement of Thinned Semiconductor Dice

Miller

Marinov

Swenson

et al. 2012

IEEE Trans. Compon., Packag. Manufact. Technol.

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Laser-Enabled Advanced Packaging of Ultrathin Bare Dice in Flexible Substrates

Marinov

Swenson

Miller

et al. 2012

IEEE Trans. Compon., Packag. Manufact. Technol.

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V. Marinov

Flexible, Highly Graphitized Carbon Aerogels Based on Bacterial Cellulose/Lignin: Catalyst‐Free Synthesis and its Application in Energy Storage Devices

52‐4: Laser‐Enabled Extremely‐High Rate Technology for µLED Assembly

Laser-assisted ultrathin die packaging: Insights from a process study

Noncontact Selective Laser-Assisted Placement of Thinned Semiconductor Dice

Laser-Enabled Advanced Packaging of Ultrathin Bare Dice in Flexible Substrates

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