RESUMEN
Stöber silica particles are used in a diverse range of applications. Despite their widespread industrial and scientific uses, information on the internal structure of the particles is non-trivial to obtain and is not often reported. In this work we have used spin-echo small angle neutron scattering (SESANS) in conjunction with ultra small angle X-ray scattering (USAXS) and pycnometry to study an aqueous dispersion of Stöber particles. Our results are in agreement with models which propose that Stöber particles have a porous core, with a significant fraction of the pores inaccessible to solvent. For samples prepared from the same master sample in a range of H2O : D2O ratio solutions we were able to model the SESANS results for the solution series assuming monodisperse, smooth surfaced spheres of radius 83 nm with an internal open pore volume fraction of 32% and a closed pore fraction of 10%. Our results are consistent with USAXS measurements. The protocol developed and discussed here shows that the SESANS technique is a powerful way to investigate particles much larger than those studied using conventional small angle scattering methods.
RESUMEN
We present a new instrument for spin echo small angle neutron scattering (SESANS) developed at the Low Energy Neutron Source at Indiana University. A description of the various instrument components is given along with the performance of these components. At the heart of the instrument are a series of resistive coils to encode the neutron trajectory into the neutron polarisation. These are shown to work well over a broad range of neutron wavelengths. Neutron polarisation analysis is accomplished using a continuously operating neutron spin filter polarised by Rb spin-exchange optical pumping of (3)He. We describe the performance of the analyser along with a study of the (3)He polarisation stability and its implications for SESANS measurements. Scattering from silica Stöber particles is investigated and agrees with samples run on similar instruments.
RESUMEN
Poly(N-isopropylacrylamide)s with imidazole endgroups were used to separate a histidine-tagged protein fragment directly from a crude cell lysate. The polymers display a lower critical solution temperature that can be tuned to occur at a range of subambient temperatures. UV-visible spectra indicated differences in the binding in aqueous media of Cu(II) and Ni(II) to the imidazole endgroups. These changes in the UV-visible spectra were reflected in the solution/aggregation behavior of the polymers as studied by dynamic light scattering. The addition of Cu(II) disaggregated the polymers, and the polymer coil swelled. On the other hand, when Ni(II) was added the polymers remained aggregated in aqueous media. The polymers were used to purify residues 230-534 of the histidine-tagged breast cancer susceptibility protein his6-BRCA1. Cu(II) was found to be better suited to the formation of useful polymer-metal ion-protein complexes that display cloud points, since Ni(II)/polymer mixtures generated very little purified protein. The polymers were synthesized using a previously reported variation of the reversible addition-fragmentation chain termination (RAFT) methodology, using the chain transfer agent 3H-imidazole-4-carbodithioic acid 4-vinyl benzyl ester with N-isopropylacrylamide (NIPAM).