3 research outputs found
Colloidal Polymers from Dipolar Assembly of Cobalt-Tipped CdSe@CdS Nanorods
The synthesis of a modular colloidal polymer system based on the dipolar assembly of CdSe@CdS nanorods functionalized with a single cobalt nanoparticle “tip” (CoNP-tip) is reported. These heterostructured nanorods spontaneously self-assembled <i>via</i> magnetic dipolar associations of the cobalt domains. In these assemblies, CdSe@CdS nanorods were carried as densely grafted side chain groups along the dipolar NP chain to form bottlebrush-type colloidal polymers. Nanorod side chains strongly affected the conformation of individual colloidal polymer bottlebrush chains and the morphology of thin films. Dipolar CoNP-tipped nanorods were then used as “colloidal monomers” to form mesoscopic assemblies reminiscent of traditional copolymers possessing segmented and statistical compositions. Investigation of the phase behavior of colloidal polymer blends revealed the formation of mesoscopic phase separated morphologies from segmented colloidal copolymers. These studies demonstrated the ability to control colloidal polymer composition and morphology in a manner observed for classical polymer systems by synthetic control of heterostructured nanorod structure and harnessing interparticle dipolar associations
Directing the Deposition of Ferromagnetic Cobalt onto Pt-Tipped CdSe@CdS Nanorods: Synthetic and Mechanistic Insights
A methodology providing access to dumbbell-tipped, metal–semiconductor and metal oxide–semiconductor heterostructured nanorods has been developed. The synthesis and characterization of CdSe@CdS nanorods incorporating ferromagnetic cobalt nanoinclusions at both nanorod termini (<i>i</i>.<i>e</i>., dumbbell morphology) are presented. The key step in the synthesis of these heterostructured nanorods was the decoration of CdSe@CdS nanorods with platinum nanoparticle tips, which promoted the deposition of metallic CoNPs onto Pt-tipped CdSe@CdS nanorods. Cobalt nanoparticle tips were then selectively oxidized to afford CdSe@CdS nanorods with cobalt oxide domains at both termini. In the case of longer cobalt-tipped nanorods, heterostructured nanorods were observed to self-organize into complex dipolar assemblies, which formed as a consequence of magnetic associations of terminal CoNP tips. Colloidal polymerization of these cobalt-tipped nanorods afforded fused nanorod assemblies from the oxidation of cobalt nanoparticle tips at the ends of nanorods <i>via</i> the nanoscale Kirkendall effect. Wurtzite CdS nanorods survived both the deposition of metallic CoNP tips and conversion into cobalt oxide phases, as confirmed by both XRD and HRTEM analysis. A series of CdSe@CdS nanorods of four different lengths ranging from 40 to 174 nm and comparable diameters (6–7 nm) were prepared and modified with both cobalt and cobalt oxide tips. The total synthesis of these heterostructured nanorods required five steps from commercially available reagents. Key synthetic considerations are discussed, with particular emphasis on reporting isolated yields of all intermediates and products from scale up of intermediate precursors
High Refractive Index Copolymers with Improved Thermomechanical Properties via the Inverse Vulcanization of Sulfur and 1,3,5-Triisopropenylbenzene
The
synthesis of a novel high sulfur content material possessing
improved thermomechanical properties is reported via the inverse vulcanization
of elemental sulfur (S<sub>8</sub>) and 1,3,5-triisopropenylbenzene
(TIB). A key feature of this system was the ability to afford highly
cross-linked, thermosetting materials, where the use of TIB as a comonomer
enabled facile control of the network structure and dramatically improved
the glass transition temperature (relative to our earlier sulfur copolymers)
of polyÂ(sulfur-random-(1,3,5-triisopropenylbenzene)) (polyÂ(S-<i>r</i>-TIB)) materials over a range from <i>T</i> =
68 to 130 °C. This approach allowed for the incorporation of
a high content of sulfur–sulfur (S–S) units in the copolymer
that enabled thermomechanical scission of these dynamic covalent bonds
and thermal reprocessing of the material, which we confirmed via dynamic
rheological characterization. Furthermore, the high sulfur content
also imparted high refractive index (<i>n</i> > 1.75)
and
IR transparency to polyÂ(S-<i>r</i>-TIB) copolymers, which
offered a route to enhanced optical transmitting materials for IR
thermal imaging applications with improved thermomechanical propertie