\u3cp\u3eWe describe an optomagnetic cluster experiment to understand and control the interactions between particles over a wide range of time scales. Aggregation is studied by magnetically attracting particles into dimers and by quantifying the number of dimers that become chemically bound within a certain time interval. An optomagnetic readout based on light scattering of rotating clusters is used to measure dimer formation rates. Magnetic field settings, that is, field rotation frequency, field amplitude, and on-and off-Times, have been optimized to independently measure both the magnetically induced dimers and chemically bound dimers. The chemical aggregation rate is quantified in solutions with different pH and ionic strengths. The mea...
Aggregation processes of colloidal particles are of broad scientific and technological relevance. Th...
AbstractIn this paper we present a simple method to quantify aggregates of 200nm magnetic particles....
The rate at which colloidal particles can form biomolecular bonds controls the kinetics of applicati...
We describe an optomagnetic cluster experiment to understand and control the interactions between pa...
We describe an optomagnetic cluster experiment to understand and control the interactions between pa...
We describe an optomagnetic cluster experiment to understand and control the interactions between pa...
We describe an optomagnetic cluster experiment to understand and control the interactions between pa...
We describe an optomagnetic cluster experiment to understand and control the interactions between pa...
\u3cp\u3eBiofunctionalized micro- and nanoparticles are important for a wide range of applications, ...
Biofunctionalized micro- and nanoparticles are important for a wide range of applications, but metho...
Biofunctionalized micro- and nanoparticles are important for a wide range of applications, but metho...
Biofunctionalized micro- and nanoparticles are important for a wide range of applications, but metho...
Biofunctionalized micro- and nanoparticles are important for a wide range of applications, but metho...
Biofunctionalized micro- and nanoparticles are important for a wide range of applications, but metho...
Aggregation processes of colloidal particles are of broad scientific and technological relevance. Th...
Aggregation processes of colloidal particles are of broad scientific and technological relevance. Th...
AbstractIn this paper we present a simple method to quantify aggregates of 200nm magnetic particles....
The rate at which colloidal particles can form biomolecular bonds controls the kinetics of applicati...
We describe an optomagnetic cluster experiment to understand and control the interactions between pa...
We describe an optomagnetic cluster experiment to understand and control the interactions between pa...
We describe an optomagnetic cluster experiment to understand and control the interactions between pa...
We describe an optomagnetic cluster experiment to understand and control the interactions between pa...
We describe an optomagnetic cluster experiment to understand and control the interactions between pa...
\u3cp\u3eBiofunctionalized micro- and nanoparticles are important for a wide range of applications, ...
Biofunctionalized micro- and nanoparticles are important for a wide range of applications, but metho...
Biofunctionalized micro- and nanoparticles are important for a wide range of applications, but metho...
Biofunctionalized micro- and nanoparticles are important for a wide range of applications, but metho...
Biofunctionalized micro- and nanoparticles are important for a wide range of applications, but metho...
Biofunctionalized micro- and nanoparticles are important for a wide range of applications, but metho...
Aggregation processes of colloidal particles are of broad scientific and technological relevance. Th...
Aggregation processes of colloidal particles are of broad scientific and technological relevance. Th...
AbstractIn this paper we present a simple method to quantify aggregates of 200nm magnetic particles....
The rate at which colloidal particles can form biomolecular bonds controls the kinetics of applicati...