4 research outputs found
Steric Hindrance Induces crosslike Self-Assembly of Gold Nanodumbbells
In the formation of colloidal molecules, directional
interactions
are crucial for controlling the spatial distribution of the building
blocks. Anisotropic nanoparticles facilitate directional clustering
via steric constraints imposed by each specific shape, thereby restricting
assembly along certain directions. We show in this Letter that the
combination of patchiness (attraction) and shape (steric hindrance)
allows assembling gold nanodumbbell building blocks into crosslike
dimers with well-controlled interparticle distance and relative orientation.
Steric hindrance between interacting dumbbell-like particles opens
up a new synthetic approach toward low-symmetry plasmonic clusters,
which may significantly contribute to understand complex plasmonic
phenomena
Seedless Synthesis of Single Crystalline Au Nanoparticles with Unusual Shapes and Tunable LSPR in the near-IR
The plasmonic properties of metal nanoparticles have
acquired great
importance because of their potential applications in very diverse
fields. Metal nanoparticles with localized surface plasmon resonances
(LSPR) in the near-infrared (NIR, 750ā1300 nm) are of particular
interest because tissues, blood, and water display low absorption
in this spectral range, thus facilitating biomedical applications.
Cetyltrimethylammonium chloride (CTAC) was used to induce the seedless
formation of highly anisotropic, twisted single crystalline Au nanoparticles
in a single step. The LSPR of the obtained particles can be tuned
from 600 nm up to 1400 nm by simply changing the reaction temperature
or the reagents concentrations. The tunability of the LSPR is closely
associated with significant changes in the final particle morphology,
which was studied by advanced electron microscopy techniques (3D Tomography
and HAADF-STEM). Kinetic experiments were carried out to establish
the growth mechanism, suggesting that slow kinetics together with
the complexation of the gold salt precursor to CTAC are key factors
favoring the formation of these anisotropic particles
Seedless Synthesis of Single Crystalline Au Nanoparticles with Unusual Shapes and Tunable LSPR in the near-IR
The plasmonic properties of metal nanoparticles have
acquired great
importance because of their potential applications in very diverse
fields. Metal nanoparticles with localized surface plasmon resonances
(LSPR) in the near-infrared (NIR, 750ā1300 nm) are of particular
interest because tissues, blood, and water display low absorption
in this spectral range, thus facilitating biomedical applications.
Cetyltrimethylammonium chloride (CTAC) was used to induce the seedless
formation of highly anisotropic, twisted single crystalline Au nanoparticles
in a single step. The LSPR of the obtained particles can be tuned
from 600 nm up to 1400 nm by simply changing the reaction temperature
or the reagents concentrations. The tunability of the LSPR is closely
associated with significant changes in the final particle morphology,
which was studied by advanced electron microscopy techniques (3D Tomography
and HAADF-STEM). Kinetic experiments were carried out to establish
the growth mechanism, suggesting that slow kinetics together with
the complexation of the gold salt precursor to CTAC are key factors
favoring the formation of these anisotropic particles
Seedless Synthesis of Single Crystalline Au Nanoparticles with Unusual Shapes and Tunable LSPR in the near-IR
The plasmonic properties of metal nanoparticles have
acquired great
importance because of their potential applications in very diverse
fields. Metal nanoparticles with localized surface plasmon resonances
(LSPR) in the near-infrared (NIR, 750ā1300 nm) are of particular
interest because tissues, blood, and water display low absorption
in this spectral range, thus facilitating biomedical applications.
Cetyltrimethylammonium chloride (CTAC) was used to induce the seedless
formation of highly anisotropic, twisted single crystalline Au nanoparticles
in a single step. The LSPR of the obtained particles can be tuned
from 600 nm up to 1400 nm by simply changing the reaction temperature
or the reagents concentrations. The tunability of the LSPR is closely
associated with significant changes in the final particle morphology,
which was studied by advanced electron microscopy techniques (3D Tomography
and HAADF-STEM). Kinetic experiments were carried out to establish
the growth mechanism, suggesting that slow kinetics together with
the complexation of the gold salt precursor to CTAC are key factors
favoring the formation of these anisotropic particles