Planar,
thin-layered chiral plasmonic superstructures with complex
two-dimensional (2D) patterns, namely, double-layered binary stars
(bi-stars) and pinwheels, were realized through DNA programmable 2D
supramolecular self-assembly of gold nanorods (AuNRs). The chirality
of the chiral superstructures was defined by a finite number of AuNR
pairs as enantiomeric motifs, and their sizes (∼240 nm) were
precisely defined by the underlying DNA template. These planar, thin-layered
chiral nanoparticle superstructures exhibited prescribed shapes and
sizes at the dried state on the substrate surface and are characteristic
of giant anisotropy of chiroptical responses, with enhanced g-factors from the axial incident excitation as compared
to the in-plane excitation. This work will inspire possibilities for
the construction of 2D chiral materials, for example, chiral metasurfaces,
for the on-chip manipulation of chiral light-matter interactions via programmable self-assembly of nanoparticles.
A significant challenge exists in obtaining chiral nanostructures that are amenable to both solution-phase selfassembly and solid-phase preservation, which enable the observation of unveiled optical responses impacted by the dynamic or static conformation and the incident excitations. Here, to meet this demand, we employed DNA origami technology to create quasi-planar chiral satellite-core nanoparticle superstructures with an intermediate geometry between the monolayer and the double layer. We disentangled the complex chiral mechanisms, which include planar chirality, 3D chirality, and induced chirality transfer, through combined theoretical studies and thorough experimental measurements of both solution-and solid-phase samples. Two distinct states of optical responses were demonstrated by the dynamic and static conformations, involving a split or nonsplit circular dichroism (CD) line shape. More importantly, our study on chiral nanoparticle superstructures on a substrate featuring both a dominant 2D geometry and a defined 3D represents a great leap toward the realization of colloidal chiral metasurfaces.
Chirality, a fascinating property ubiquitous in nature, plays an important role for living matters. DNA molecules as construction materials can precisely organize metal nanoparticles into chiral geometry at nanoscale. These...
Flexible mechanical sensors based on nanomaterials operate on a deformation-response mechanism, making it challenging to discern different types of mechanical stimuli such as pressure and strain. Therefore, these sensors are susceptible to significant mechanical interference. Here, we introduce a multifunctional flexible sensor capable of discriminating coupled pressure and strain without cross-interference. Our design involves an elastic cantilever fixed on the pillar of the flexible main substrate, creating a three-dimensional (3D) substrate, and two percolative nanoparticle (NP) arrays are deposited on the cantilever and main substrate, respectively, as the sensing materials. The 3D flexible substrate could confine pressure/strain loading exclusively on the cantilever or main substrate, resulting in independent responses of the two nanoparticle arrays with no cross-interference. Benefitting from the quantum transport in nanoparticle arrays, our sensors demonstrate an exceptional sensitivity, enabling discrimination of subtle strains down to 1.34 × 10−4. Furthermore, the suspended cantilever with one movable end can enhance the pressure perception of the NP array, exhibiting a high sensitivity of −0.223 kPa−1 and an ultrahigh resolution of 4.24 Pa. This flexible sensor with multifunctional design will provide inspiration for the development of flexible mechanical sensors and the advancement of decoupling strategies.
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