Abstract
Incorporating nanoparticles into devices for a wide range of applications often requires the formation of thick films, which is particularly necessary for improving magnetic power storage, microwave properties, and sensor performance. One approach to assembling nanoparticles into films is the use of electrophoretic deposition (EPD). This work seeks to develop methods to increase film thickness and stability in EPD by increasing film-substrate interactions via functionalizing conductive substrates with various chelating agents. Here, we deposited iron oxide nanoparticles onto conductive substrates functionalized with three chelating agents with different functional moieties and differing chelating strengths. We show that increasing chelating strength can increase film-substrate interactions, resulting in thicker films when compared to traditional EPD. Results will also be presented on how the chelating strength relates to film formation as a function of deposition conditions. Yield for EPD is influenced by deposition conditions including applied electric field, particle concentration, and deposition time. This work shows that the functionalization of substrates with chelating agents that coordinate strongly with nanoparticles (phosphonic acid and dopamine) overcome parameters that traditionally hinder the deposition of thicker and more stable films, such as applied electric field and high particle concentration. We show that functionalizing substrates with chelating agents is a promising method to fabricate thick, stable films of nanoparticles deposited via EPD over a larger processing space by increasing film-substrate interactions.
Highlights
For applications that utilize films of nanoparticles, there is often a need to develop methods to fabricate films that are both thick and stable
Peaks attributed to inverse spinel crystal structure at 2θ 30.1, 35.8, 53.4, 57.1, and 62.9° confirmed the presence of inverse spinel iron oxide, which was expected from this synthesis (Supplementary Figure S1A)
A method to fabricate thick, stable films of nanoparticles has been developed for use in electrophoretic deposition (EPD) by increasing film-substrate interactions
Summary
For applications that utilize films of nanoparticles, there is often a need to develop methods to fabricate films that are both thick and stable. The use of dispersing agents can introduce additional considerations of chemical compatibility between the additive and solvent and nonideal behavior in solution, while particular deposition parameters can introduce unfavorable particle-substrate interactions and non-ideal particle behavior in solution. These approaches can limit the maximum achievable yield (Yum et al, 2003; Besra and Liu, 2007; Khalili et al, 2016; Liu et al, 2016; Dhiflaoui et al, 2017)
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