Gerardo Morell scite author profile

Graphene has been the subject of intense research in recent years due to its unique electrical, optical and mechanical properties. Furthermore, it is expected that quantum dots of graphene would make their way into devices due to their structure and composition which unify graphene and quantum dots properties. Graphene quantum dots (GQDs) are planar nano flakes with a few atomic layers thick and with a higher surface-to-volume ratio than spherical carbon dots (CDs) of the same size. We have developed a pulsed laser synthesis (PLS) method for the synthesis of GQDs that are soluble in water, measure 2–6 nm across, and are about 1–3 layers thick. They show strong intrinsic fluorescence in the visible region. The source of fluorescence can be attributed to various factors, such as: quantum confinement, zigzag edge structure, and surface defects. Confocal microscopy images of bacteria exposed to GQDs show their suitability as biomarkers and nano-probes in high contrast bioimaging.

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Advance in Novel Boron Nitride Nanosheets to Nanoelectronic Device Applications

Sajjad

Morell

Feng

2013

ACS Appl. Mater. Interfaces

114

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We report low-temperature synthesis of large-scale boron nitride nanosheets (BNNSs) and their applications for high-performance Schottky diode and gas sensor. Ten minutes of synthesis with a short-pulse-laser-produced plasma deposition technique yields a large amount of highly flat, transparent BNNSs. A basic reason for using short-pulse plasma beams is to avoid nanosheet thermal ablation or have low heat generated. Consequently, it greatly reduces the stress and yield large, flat BNNSs. The average size of obtained BNNS is around 10 μm and thickness is around 1.7 nm. Carbon element has been used for doping BNNSs and achieving BNNSs-based Schottky diode and gas sensing device. Typical current versus voltage characteristics of diode are examined. The breakdown reverse voltage is around -70 V. This probably indicates that the breakdown electric field of BNNSs-based diode is up to 1 × 10(8) V/cm. Sensing behavior of BNNSs-based gas sensor toward methane diluted with dry air is also characterized. The response time and recovery time are around 3 and 5 s at the operating temperature of 150 °C. Relatively, the sensor has poor sensitivity to oxygen gas.

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Synergistic antibacterial activity of PEGylated silver–graphene quantum dots nanocomposites

Habiba

Bracho-Rincon

González-Feliciano

et al. 2015

Applied Materials Today

144

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Room temperature gas sensor based on tin dioxide-carbon nanotubes composite films

Mendoza

Hernández

Makarov

et al. 2014

Sensors and Actuators B: Chemical

119

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Gerardo Morell

Luminescent graphene quantum dots fabricated by pulsed laser synthesis

Advance in Novel Boron Nitride Nanosheets to Nanoelectronic Device Applications

Synergistic antibacterial activity of PEGylated silver–graphene quantum dots nanocomposites

Room temperature gas sensor based on tin dioxide-carbon nanotubes composite films

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