Fluorescent DNA-stabilized silver nanoclusters contain both cationic and neutral silver atoms. The absorbance spectra of compositionally pure solutions follow the trend expected for rod-shaped silver clusters, consistent with the polarized emission measured from individual nanoclusters. The data suggest a rod-like assembly of silver atoms, with silver cations mediating attachment to the bases.
DNA-stabilized silver clusters are
remarkable for the selection
of fluorescence color by the sequence of the stabilizing DNA oligomer.
Yet despite a growing number of applications that exploit this property,
no large-scale studies have probed origins of cluster color or whether
certain colors occur more frequently than others. Here we employ a
set of 684 randomly chosen 10-base oligomers to address these questions.
Rather than a flat distribution, we find that specific color bands
dominate. Cluster size data indicate that these “magic colors”
originate from the existence of magic numbers for DNA-stabilized silver
clusters, which differ from those of spheroidal gold clusters stabilized
by small-molecule ligands. Elongated cluster structures, enforced
by multiple base ligands along the DNA, can account for both magic
number sizes and color variation around peak wavelength populations.
Ensembles of nitrogen-vacancy (NV) centres in diamond are a leading platform for practical quantum sensors. Reproducible and scalable fabrication of NV-ensembles with desired properties is crucial, as is an understanding of how those properties influence performance. This work addresses these issues by characterising nitrogen-doped diamond produced by the chemical vapour deposition (CVD) method across a range of synthesis conditions. This is shown to produce material with widely differing absorption characteristics, which is linked to the level of defects other than substitutional nitrogen (NS) and NV. In such material, the achievable concentration of NV− ([NV−]) is found to be influenced by the as-grown properties. At the 10–20 ppm level for [NS], the production of CVD-grown material with strain levels sufficient not to limit achievable device sensitivity is demonstrated and a favourable product of [NV−] and
T
2
*
is obtained. Additionally, reproducible properties over a batch of 23 samples from a single synthesis run are achieved, which appears promising for the scalability efforts underway in this area of research.
The interfacial Dzyaloshinskii-Moriya Interaction (DMI) in ultrathin magnetic thin film heterostructures provides a new approach for controlling spin textures on mesoscopic length scales. Here we investigate the dependence of the interfacial DMI constant on a Pt wedge insertion layer in Ta/CoFeB/Pt(wedge)/MgO thin films by observing the asymmetric spin wave dispersion using Brillouin light scattering. Continuous tuning of by more than a factor of three is realized by inserting less than one monolayer of Pt. The observations provide new insights for designing magnetic thin film heterostructures with tailored for controlling skyrmions and magnetic domain wall chirality and dynamics.
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