Your search keyword '"Evert Dhaene"' showing total 3 results

1. The Trouble with ODE: Polymerization during Nanocrystal Synthesis

Author

Ellie Bennett, Jonas Billet, Evert Dhaene, Isabel Van Driessche, and Jonathan De Roo

Subjects

Materials science, One-pot synthesis, Size-exclusion chromatography, Nanoparticle, Bioengineering, surface chemistry, 02 engineering and technology, CDSE, SURFACE-CHEMISTRY, octadecene, General Materials Science, Solubility, chemistry.chemical_classification, PHOSPHINE-FREE SYNTHESIS, IDENTIFICATION, Quantum dots, Mechanical Engineering, General Chemistry, Polymer, 021001 nanoscience & nanotechnology, Condensed Matter Physics, OCTYLPHOSPHINE OXIDE TOPO, ONE-POT SYNTHESIS, Solvent, Chemistry, SIZE, chemistry, Chemical engineering, Polymerization, Nanocrystal, HIGH-QUALITY, nanoparticles, LIGANDS, 0210 nano-technology

Abstract

1-Octadecene is a widely used solvent for high temperature nanocrystal synthesis (120-320 degrees C). Here, we show that 1-octadecene spontaneously polymerizes under these conditions, and the resulting poly(1-octadecene) has a comparable solubility and size to nanocrystals stabilized by hydrophobic ligands. Typical purification procedures (precipitation/redispersion cycles or size exclusion chromatography) fail to separate the poly(1-octadecene) impurity from the nanocrystal product. To avoid formation of poly(1-octadecene), we replace 1-octadecene with saturated, aliphatic solvents. Alternatively, the nanocrystals' native ligands are exchanged for polar ligands, leading to significant solubility differences between nanocrystals and poly(1-octadecene), therefore allowing isolation of pure nanocrystals, free from polymer impurities. These results will help design superior syntheses and improve nanocrystal purity, an important factor in many applications.

Published

2019

2. The Trouble With 1-Octadecene: Polymerization During Nanocrystal Synthesis

Author

Isabel Van Driessche, Jonathan De Roo, Jonas Billet, Evert Dhaene, and Ellie Bennett

Subjects

chemistry.chemical_classification, Solvent, Materials science, chemistry, Nanocrystal, Polymerization, Chemical engineering, Precipitation (chemistry), Impurity, Size-exclusion chromatography, Polymer, Solubility

Abstract

1-octadecene is a widely used solvent for high temperature nanocrystal synthesis (120 – 320 °C). Here, we show that 1-octadecene spontaneously polymerizes under these conditions and the resulting poly(1-octadecene) has a comparable solubility and size to nanocrystals stabilized by hydrophobic ligands. Typical purification procedures (precipitation/redispersion cycles or size exclusion chromatography) fail to separate the poly(1-octadecene) impurity from the nanocrystal product. To avoid formation of poly(1-octadecene), we replaced 1-octadecene with saturated, aliphatic solvents. Alternatively, the native ligands are exchanged for polar ligands, leading to significant solubility differences between nanocrystals and poly(1-octadecene), therefore allowing isolation of pure nanocrystals, free from polymer impurities. These results will help design superior syntheses and improve nanocrystal purity, an important factor in many applications.

Published

2019

3. The Trouble with 1-Octadecene; Polymerization During Nanocrystal Synthesis

Author

Ellie Bennett, Isabel Van Driessche, Jonas Billet, Evert Dhaene, and Jonathan De Roo

Subjects

chemistry.chemical_classification, Solvent, Materials science, chemistry, Polymerization, Chemical engineering, Nanocrystal, Size-exclusion chromatography, Nanoparticle, Polymer, Solubility, Nanomaterials

Abstract

1-octadecene is a widely used solvent for high temperature nanocrystal synthesis (120 – 320 °C). Here, we show that 1-octadecene spontaneously polymerizes under these conditions and the resulting poly(1-octadecene) has a comparable solubility and size to nanocrystals stabilized by hydrophobic ligands. Typical purification procedures (precipitation/redispersion cycles or size exclusion chromatography) fail to separate the poly(1-octadecene) impurity from the nanocrystal product. To avoid formation of poly(1-octadecene), we replaced 1-octadecene with saturated, aliphatic solvents. Alternatively, the native ligands are exchanged for polar ligands, leading to significant solubility differences between nanocrystals and poly(1-octadecene), therefore allowing isolation of pure nanocrystals, free from polymer impurities. These results will help design superior syntheses and improve nanocrystal purity, an important factor in many applications.

Published

2019