An
understanding of how complex nanoscale morphologies emerge
from synthesis would offer powerful strategies to construct soft materials
with designed structures and functions. However, these kinds
of morphologies have proven difficult to characterize, and therefore
manipulate, because they are three-dimensional (3D), nanoscopic, and
often highly irregular. Here, we studied polyamide (PA) membranes
used in wastewater reclamation as a prime example of this challenge.
Using electron tomography and quantitative morphometry, we reconstructed
the nanoscale morphology of 3D crumples and voids in PA membranes
for the first time. Various parameters governing film transport properties,
such as surface-to-volume ratio and mass-per-area, were measured directly
from the reconstructed membrane structure. In addition, we extracted
information inaccessible by other means. For example, 3D reconstruction
shows that membrane nanostructures are formed from PA layers 15–20
nm thick folding into 3D crumples which envelope up to 30% void by
volume. Mapping local curvature and thickness in 3D quantitatively
groups these crumples into three classes, “domes”, “dimples”,
and “clusters”, each being a distinct type of microenvironment.
Elemental mapping of metal ion adsorption across the film demonstrates
that these previously missed parameters are relevant to membrane performance.
This imaging–morphometry platform can be applicable to other
nanoscale soft materials and potentially suggests engineering strategies
based directly on synthesis–morphology–function relationships.
The use of analytical spectroscopies during scanning/transmission electron microscope (S/TEM) investigations of micro- and nano-scale structures has become a routine technique in the arsenal of tools available to today's materials researchers. Essential to implementation and successful application of spectroscopy to characterization is the integration of numerous technologies, which include electron optics, specimen holders, and associated detectors. While this combination has been achieved in many instrument configurations, the integration of X-ray energy-dispersive spectroscopy and in situ liquid environmental cells in the S/TEM has to date been elusive. In this work we present the successful incorporation/modifications to a system that achieves this functionality for analytical electron microscopy.
A new design of in situ liquid cells is demonstrated, providing the first nanometer resolution elemental mapping of nanostructures in solution. The technique has been applied to investigate dynamic liquid-phase synthesis of core-shell nanostructures and to simultaneously image the compositional distribution for multiple elements within the resulting materials.
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