Pyrolysis mechanism of magnesium citrate nonahydrate and microstructural evolution during the process

Abstract

The key characteristics of the porous carbon materials and ceramic composites derived from citrates are directly affected by the pyrolysis mechanism of parent citrates and the microstructural revolution during the process. The pyrolysis mechanism of magnesium citrate nonahydrate (MCN) and the microstructural evolution during its pyrolysis were investigated by analysing the C/MgO nanocomposite powders from MCN pyrolyzed in carbon embedded condition and flowing argon atmosphere. The pyrolysis process of MCN was composed of the following stages: (1) MCN dehydrated to magnesium citrate at about 150 °C; (2) magnesium citrate decomposed into itaconic acid magnesium and MgO at about 300 °C; (3) itaconic acid magnesium decomposed into carbon, MgO and CH4 at around 500 °C; (4) CH4 was pyrolyzed and graphene was deposited on MgO. The carbon produced in stage (3) was turbostratic while that derived from the pyrolysis-deposition of CH4 was few-layered-graphene. The MgO nano grains produced in stage (2) precipitated and agglomerated while those derived from itaconic acid magnesium were much smaller in size. In carbon embedded condition, the few-layered-graphene not only deposited on the MgO aggregates surface but also inserted into the MgO nano grain boundaries, which suppressed the growth and sintering of MgO nano grains.