A better understanding of how production pathway affects the final product is required in order to produce targeted syntheses, but many of the classical ex situ techniques used for studying nanoparticle growth are unsuitable as stand-alone methods for identifying and characterizing growth mechanisms. Using a combination of high resolution transmission electron microscopy (TEM), cryogenic TEM, and fluid cell scanning electron microscopy, we monitor europium oxalate growth over the range of nanometers to tens of micrometers and identify potential crystal growth pathways. We also compare the effects of stirring during crystal growth as an example of how changing processing conditions changes growth mechanisms.
Revised: August 23, 2019 |
Published: May 28, 2018
Citation
Soltis J.A., W.C. Isley, M.A. Conroy, S.M. Kathmann, E.C. Buck, and G.J. Lumetta. 2018.In situ microscopy across scales for the characterization of crystal growth mechanisms: The case of europium oxalate.CrystEngComm 20, no. 20:2822-2833.PNNL-SA-125991.doi:10.1039/c7ce01450c