Controlled Preparation of Nanoparticle Gradient Materials by Diffusion

Spinnrock, Andreas; Martens, C. M.; Enders, Florian; Boldt, Klaus; Cölfen, Helmut

doi:10.3390/nano9070988

Cited by 8 publications

(6 citation statements)

References 39 publications

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“…This approach was also proven to be versatile, as the gradient superstructures can be applicable to nanoparticles of different sizes, shapes and materials. More interestingly, nanoparticle gradient materials can also be fabricated in an AUC band-forming cell, by the diffusion process at a very low angular velocity in an AUC synthetic boundary experiment [ 101 ], as shown in Figure 7 C. In this experiment, the nanoparticles were overlayed onto a solution column of molten gelatin at around 40 °C at a low angular velocity. Afterwards, the nanoparticle layer continued to diffuse into the solvent column, which can be detected by AUC in real-time.…”

Section: Ordering Of Nanoparticles In Analytical (Ultra)centrifugamentioning

confidence: 99%

Ultracentrifugation Techniques for the Ordering of Nanoparticles

Cölfen

2021

Nanomaterials

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A centrifugal field can provide an external force for the ordering of nanoparticles. Especially with the knowledge from in-situ characterization by analytical (ultra)centrifugation, nanoparticle ordering can be rationally realized in preparative (ultra)centrifugation. This review summarizes the work back to the 1990s, where intuitive use of centrifugation was achieved for the fabrication of colloidal crystals to the very recent work where analytical (ultra)centrifugation is employed to tailor-make concentration gradients for advanced materials. This review is divided into three main parts. In the introduction part, the history of ordering microbeads in gravity is discussed and with the size of particles reduced to nanometers, a centrifugal field is necessary. In the next part, the research on the ordering of nanoparticles in analytical and preparative centrifugation in recent decades is described. In the last part, the applications of the functional materials, fabricated from centrifugation-induced nanoparticle superstructures are briefly discussed.

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Section: Ordering Of Nanoparticles In Analytical (Ultra)centrifugamentioning

confidence: 99%

Ultracentrifugation Techniques for the Ordering of Nanoparticles

Cölfen

2021

Nanomaterials

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“…We developed a quantitative model with this understanding of shell formation via GRR by modifying the equations of diffusion 41 to include terms for the enthalpy of mixing. For the case without mixing terms, the governing equation for systems with spherical symmetry is…”

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confidence: 99%

“…We developed a quantitative model with this understanding of shell formation via GRR by modifying the equations of diffusion to include terms for the enthalpy of mixing. For the case without mixing terms, the governing equation for systems with spherical symmetry is C ( r , t ) is the dimensionless concentration or mole fraction for either Cu or Ag as a function of the reaction time t , and the distance from the center of the NC, r .…”

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Self-Limiting Shell Formation in Cu@Ag Core–Shell Nanocrystals during Galvanic Replacement

Kamat

Yan

Osowiecki

et al. 2020

J. Phys. Chem. Lett.

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The understanding of synthetic pathways of bimetallic nanocrystals remains limited due to the complex energy landscapes and dynamics involved. In this work, we investigate the formation of self-limiting Cu@Ag core–shell nanoparticles starting from Cu nanocrystals followed by galvanic replacement with Ag ions. Bulk quantification with atomic emission spectroscopy and spatially resolved elemental mapping with electron microscopy reveal distinct nucleation regimes that produce nanoparticles with a tunable Ag shell thickness, but only up to a certain limiting thickness. We develop a quantitative transport model that explains this observed self-limiting structure as arising from the balance between entropy-driven interdiffusion and a positive mixing enthalpy. The proposed model depends only on the intrinsic physical properties of the system such as diffusivity and mixing energy and directly yields a high level of agreement with the elemental mapping profiles without requiring additional fit parameters.

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“…The low standard deviations with which nanoparticles can be produced, reduces the spread of geometric variables of features obtained on the gradient. Nanoparticle density gradients have been reported to be obtained using diffusion-limited transport through polymer melts [30], electrostatic self-assembly of negatively charged nanoparticles to positively charged molecular gradients [2,17,31], or via kinetic control over nanoparticle deposition by dip-coating processes [22,23]. Control over kinetic processes provides more flexibility in determining the geometric attributes, viz.…”

Section: Introductionmentioning

confidence: 99%

Rational route to fabrication of uni-dimensional surface gradients presenting stochastic and periodic arrangement of nanoparticles

Malekzad

Beggiato

Hegemann

et al. 2022

Applied Surface Science

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Nanostructure gradients exhibiting graded variation in a nanostructure geometric variable carry high promise as tool for parallel and high-throughput optimization of a range of on-chip devices and functional interfaces. The capabilities to fabricate nanostructure gradients, with desired size and slope, while preserving scalability and operational flexibility is however limited. In this direction, we demonstrate a simple and flexible approach to prepare nanostructure gradients, subjecting a functionalized chip for the adsorption of nanoparticles or ions from aqueous media, with varying durations of exposure along the length of the chip. The configuration is similar to dip-coating, however, with the solution front moving relative to a stationary substrate. The flow rate, dimension of the chamber, and the functional layers are shown as simple handles to achieve the desired gradient morphology. Gradients with stochastic as well as periodic organization of nanoparticle assemblies are demonstrated through the choice of different functional layers underneath the nanoparticle layer, viz. aminosilane monolayers, cross-linked plasma polymer and copolymer templates. The approach paves way to rationally designed gradients, benefitting from the significant flexibility in the choice of operational conditions, without specific constraints on the size of the substrates that can be used.

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Controlled Preparation of Nanoparticle Gradient Materials by Diffusion

Cited by 8 publications

References 39 publications

Ultracentrifugation Techniques for the Ordering of Nanoparticles

Ultracentrifugation Techniques for the Ordering of Nanoparticles

Self-Limiting Shell Formation in Cu@Ag Core–Shell Nanocrystals during Galvanic Replacement

Rational route to fabrication of uni-dimensional surface gradients presenting stochastic and periodic arrangement of nanoparticles

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