Abstract
The imaging of non-conducting materials by scanning electron microscopy (SEM) is most often performed after depositing few nanometers thick conductive layers on the samples. It is shown in this work, that even a 5 nm thick sputtered gold layer can dramatically alter the morphology and the surface structure of many different types of aerogels. Silica, polyimide, polyamide, calcium-alginate and cellulose aerogels were imaged in their pristine forms and after gold sputtering utilizing low voltage scanning electron microscopy (LVSEM) in order to reduce charging effects. The morphological features seen in the SEM images of the pristine samples are in excellent agreement with the structural parameters of the aerogels measured by nitrogen adsorption-desorption porosimetry. In contrast, the morphologies of the sputter coated samples are significantly distorted and feature nanostructured gold. These findings point out that extra care should be taken in order to ensure that gold sputtering does not cause morphological artifacts. Otherwise, the application of low voltage scanning electron microscopy even yields high resolution images of pristine non-conducting aerogels.
Highlights
IntroductionAerogels obtained by sol-gel and dissolution-coagulation techniques and final supercritical drying are solid functional materials of extremely high porosities and low densities
Aerogels obtained by sol-gel and dissolution-coagulation techniques and final supercritical drying are solid functional materials of extremely high porosities and low densities.These properties are utilized in a wide range of applications including advanced thermal insulation, catalysis, manufacture of electrode materials, high-capacity adsorbents, drug delivery and tissue engineering [1,2]
We systematically evaluate the performance of scanning electron microscopy (SEM) applied to image the nanostructures of several different types of non-conducting aerogels
Summary
Aerogels obtained by sol-gel and dissolution-coagulation techniques and final supercritical drying are solid functional materials of extremely high porosities and low densities. These properties are utilized in a wide range of applications including advanced thermal insulation, catalysis, manufacture of electrode materials, high-capacity adsorbents, drug delivery and tissue engineering [1,2]. Structural elements, including variations in the geometry of the network forming entities down to the nanoscale, can be differentiated These differences in fine structure are related to the chemical composition of the source material(s) and the conditions of gel syntheses [13,14,15,16]
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
