Cryo-electron microscopy is an essential tool for high-resolution structural studies of biological systems. This method relies on the use of phase contrast imaging at high defocus to improve information transfer at low spatial frequencies at the expense of higher spatial frequencies. Here we demonstrate that electron ptychography can recover the phase of the specimen with continuous information transfer across a wide range of the spatial frequency spectrum, with improved transfer at lower spatial frequencies, and as such is more efficient for phase recovery than conventional phase contrast imaging. We further show that the method can be used to study frozen-hydrated specimens of rotavirus double-layered particles and HIV-1 virus-like particles under low-dose conditions (5.7 e/Å 2) and heterogeneous objects in an Adenovirus-infected cell over large fields of view (1.14 × 1.14 μm), thus making it suitable for studies of many biologically important structures.
Three dimensional scaffolded DNA origami with inorganic nanoparticles has been used to create tailored multidimensional nanostructures. However, the image contrast of DNA is poorer than those of the heavy nanoparticles in conventional transmission electron microscopy at high defocus so that the biological and non-biological components in 3D scaffolds cannot be simultaneously resolved using tomography of samples in a native state. We demonstrate the use of electron ptychography to recover high contrast phase information from all components in a DNA origami scaffold without staining. We further quantitatively evaluate the enhancement of contrast in comparison with conventional transmission electron microscopy. In addition, We show that for ptychography post-reconstruction focusing simplifies the workflow and reduces electron dose and beam damage.
Despite stunning progress in single-atom catalysis (SAC),
it remains
a grand challenge to yield a high loading of single atoms (SAs) anchored
on substrates. Herein, we report a one-step laser-planting strategy
to craft SAs of interest under an atmospheric temperature and pressure
on various substrates including carbon, metals, and oxides. Laser
pulses render concurrent creation of defects on the substrate and
decomposition of precursors into monolithic metal SAs, which are immobilized
on the as-produced defects via electronic interactions. Laser planting
enables a high defect density, leading to a record-high loading of
SAs of 41.8 wt %. Our strategy can also synthesize high-entropy SAs
(HESAs) with the coexistence of multiple metal SAs, regardless of
their distinct characteristics. An integrated experimental and theoretical
study reveals that superior catalytic activity can be achieved when
the distribution of metal atom content in HESAs resembles the distribution
of their catalytic performance in a volcano plot of electrocatalysis.
The noble-metal mass activity for a hydrogen evolution reaction within
HESAs is 11-fold over that of commercial Pt/C. The laser-planting
strategy is robust, opening up a simple and general route to attaining
an array of low-cost, high-density SAs on diverse substrates under
ambient conditions for electrochemical energy conversion.
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