Intercalated graphite materials allow studying reactions occurring in confined chemical conditions. In this work, we investigate the sulfuric acid intercalated graphite exfoliation process using a simple technique based on the continuous-wave (CW) infrared (IR) laser irradiation of graphite flakes. Using Kissinger and Ozawa methods, the activation energy of H2SO4-intercalated graphite was determined to be less than 100 kJ mol(-1). The laser-assisted reaction process was found to be characterized by a threshold temperature of about 140 degrees C followed by a fast rate of heating. The large amount of volatilized hot gases caused a violent expansion of the graphite flake. Morphological changes undergone by irradiated graphite flakes have been analyzed using a combination of thermal and visible imaging techniques, which allowed for the quantitative determination of temporal evolution of the thermal field during the heating stage and expansion of the flake.
Laser-Induced Thermal Expansion of H2SO4-Intercalated Graphite Lattice
Carotenuto Gianfranco;Longo Angela;Nicolais Luigi;De Nicola Sergio;Pugliese Eugenio;Ciofini Marco;Locatelli Massimiliano;Lapucci Antonio;Meucci Riccardo
2015
Abstract
Intercalated graphite materials allow studying reactions occurring in confined chemical conditions. In this work, we investigate the sulfuric acid intercalated graphite exfoliation process using a simple technique based on the continuous-wave (CW) infrared (IR) laser irradiation of graphite flakes. Using Kissinger and Ozawa methods, the activation energy of H2SO4-intercalated graphite was determined to be less than 100 kJ mol(-1). The laser-assisted reaction process was found to be characterized by a threshold temperature of about 140 degrees C followed by a fast rate of heating. The large amount of volatilized hot gases caused a violent expansion of the graphite flake. Morphological changes undergone by irradiated graphite flakes have been analyzed using a combination of thermal and visible imaging techniques, which allowed for the quantitative determination of temporal evolution of the thermal field during the heating stage and expansion of the flake.I documenti in IRIS sono protetti da copyright e tutti i diritti sono riservati, salvo diversa indicazione.
