Diffusion dynamics and concentration of toxic materials from quantum dots-based nanotechnologies: an agent-based modeling simulation framework
Authored by Datu Buyung Agusdinata, Mahbod Amouie, Tao Xu
Date Published: 2015
DOI: 10.1007/s11051-014-2844-x
Sponsors:
United States National Science Foundation (NSF)
Platforms:
AnyLogic
Model Documentation:
Other Narrative
Mathematical description
Model Code URLs:
Model code not found
Abstract
Due to their favorable electrical and optical properties, quantum dots
(QDs) nanostructures have found numerous applications including
nanomedicine and photovoltaic cells. However, increased future
production, use, and disposal of engineered QD products also raise
concerns about their potential environmental impacts. The objective of
this work is to establish a modeling framework for predicting the
diffusion dynamics and concentration of toxic materials released from
Trioctylphosphine oxide-capped CdSe. To this end, an agent-based model
simulation with reaction kinetics and Brownian motion dynamics was
developed. Reaction kinetics is used to model the stability of surface
capping agent particularly due to oxidation process. The diffusion of
toxic Cd2+ ions in aquatic environment was simulated using an adapted
Brownian motion algorithm. A calibrated parameter to reflect sensitivity
to reaction rate is proposed. The model output demonstrates the
stochastic spatial distribution of toxic Cd2+ ions under different
values of proxy environmental factor parameters. With the only chemistry
considered was oxidation, the simulation was able to replicate Cd2+ ion
release from Thiol-capped QDs in aerated water. The agent-based method
is the first to be developed in the QDs application domain. It adds both
simplicity of the solubility and rate of release of Cd2+ ions and
complexity of tracking of individual atoms of Cd at the same time.
Tags
environment
Engineered nanoparticles
Nanomaterials