Jill Millstone

Composition is a well-known variable that controls material properties across length scales and has helped lead to a wide range of applications for metal chalcogenides…

The intrinsic properties of metal ion complexes and metal crystal structures work in concert to control the formation, structure, and properties of the resulting nanomaterials…

There is still a need to discover cheap, active catalysts for the hydrogen evolution reaction (HER). This study aims to massively increase the screening rate of catalysts by using parallel computational analysis and a high throughput experimental setup to find active bimetallic catalysts for HER…

Photocatalytic water reduction is a promising alternative to traditional hydrogen production pathways, because it does not rely on fossil fuel feedstocks or electrical power sources and instead requires only visible light and water…

Research in the field of photocatalytic hydrogen evolution, namely through water reduction has seen a resurgence in the last decade as the desire for alternative fuels has expanded…

Photocatalytic water reduction is a promising alternative to traditional hydrogen production pathways, because it does not rely on fossil fuel feedstocks or electrical power sources and instead requires only visible light and water…

One challenge of developing nanoparticle (NP) drug therapeutics is predicting how NP ligand shell properties change NP diffusion coefficients in complex viscoelastic biological materials, such as in mucus membranes…

Photo-driven chemical transformations are ubiquitous across multiple scientific disciplines, from catalysis, to polymer dynamics, to control of gene expression…

From bandgap engineering in shelled semiconductor nanocrystals to supported heterogeneous catalysts, nanoscale inorganic interfaces often determine the emergent properties of the resulting structures…

One challenge of developing nanoparticle (NP) drug therapeutics is predicting how NP ligand shell properties change NP diffusion coefficients in complex viscoelastic biological materials, such as in mucus membranes…

: [COLL] Division of Colloid & Surface Chemistry

Photo-driven chemical transformations are ubiquitous across multiple scientific disciplines, from catalysis, to polymer dynamics, to control of gene expression…

: [COLL] Division of Colloid & Surface Chemistry

From bandgap engineering in shelled semiconductor nanocrystals to supported heterogeneous catalysts, nanoscale inorganic interfaces often determine the emergent properties of the resulting structures…

: [COLL] Division of Colloid & Surface Chemistry

One challenge of developing nanoparticle (NP) drug therapeutics is predicting how NP ligand shell properties change NP diffusion coefficients in complex viscoelastic biological materials, such as in mucus membranes…

: [COLL] Division of Colloid & Surface Chemistry

Photo-driven chemical transformations are ubiquitous across multiple scientific disciplines, from catalysis, to polymer dynamics, to control of gene expression…

: [COLL] Division of Colloid & Surface Chemistry

From bandgap engineering in shelled semiconductor nanocrystals to supported heterogeneous catalysts, nanoscale inorganic interfaces often determine the emergent properties of the resulting structures…

: [COLL] Division of Colloid & Surface Chemistry

One challenge of developing nanoparticle (NP) drug therapeutics is predicting how NP ligand shell properties change NP diffusion coefficients in complex viscoelastic biological materials, such as in mucus membranes…

: [COLL] Division of Colloid & Surface Chemistry

Photo-driven chemical transformations are ubiquitous across multiple scientific disciplines, from catalysis, to polymer dynamics, to control of gene expression…

: [COLL] Division of Colloid & Surface Chemistry

From bandgap engineering in shelled semiconductor nanocrystals to supported heterogeneous catalysts, nanoscale inorganic interfaces often determine the emergent properties of the resulting structures…

: [COLL] Division of Colloid & Surface Chemistry

One challenge of developing nanoparticle (NP) drug therapeutics is predicting how NP ligand shell properties change NP diffusion coefficients in complex viscoelastic biological materials, such as in mucus membranes…

Photo-driven chemical transformations are ubiquitous across multiple scientific disciplines, from catalysis, to polymer dynamics, to control of gene expression…

From bandgap engineering in shelled semiconductor nanocrystals to supported heterogeneous catalysts, nanoscale inorganic interfaces often determine the emergent properties of the resulting structures…

Photocatalytic hydrogen evolution reactions have the potential to sustainably provide the planet with a source of renewable energy…

Metal ligand chemistry impacts nearly every aspect of nanoparticle formation, physical properties, and utility…

DIVISION/COMMITTEE: [COLL] Division of Colloid & Surface Chemistry

DIVISION/COMMITTEE: [COLL] Division of Colloid & Surface Chemistry

The formation of nanoparticles continues to challenge our understanding of what it means to make and form solid materials…

DIVISION/COMMITTEE: [COLL] Division of Colloid & Surface Chemistry

DIVISION/COMMITTEE: [COLL] Division of Colloid & Surface Chemistry

Recently, a wide variety of new nanoparticle compositions have been identified as potential plasmonic materials including earth-abundant metals such as aluminum, highly doped semiconductors, as well as metal pnictides…

Simultaneously controlling both stoichiometry and atom arrangement outcomes in the synthesis of multimetallic nanoparticles (NPs) is often challenging, especially when the desired metal precursors exhibit large differences in their intrinsic reduction kinetics…

Simultaneously controlling both stoichiometry and atom arrangement outcomes in the synthesis of multimetallic nanoparticles (NPs) is often challenging, especially when the desired metal precursors exhibit large differences in their intrinsic reduction kinetics…

The formation of nanoparticles continues to challenge our understanding of what it means to make and form solid materials. Traditional theories describe colloidal nanoparticle formation as a nucleation process, with many works adding nuance to classic nucleation theory and related models…