Drug (PTX)‐loaded luminescent carbon nanoparticles (LCNs) are passivated with a thermoresponsive polymer (PNIPAM) inside melanoma cells. On page 4691, R. Bhargava, D. Pan, and co‐workers acquire such images using confocal fluorescence techniques. A representative cartoon of the nanoparticles is shown in black, where the white and the green shells represent the anti‐cancer drug (PTX: molecular structure shown) and the PNIPAM coating, respectively. The cells, upon internalizing the particles under physiological conditions, trigger the delivery of drugs contained in them.
Soft-hard interfaces at the surface of nanoparticles determine interaction potentials, including the mechanisms of growth, spatial reactivity, colloidal stability, and nanoparticle functionality [1]. For example, soft molecular ligands are thought to guide growth and symmetry breaking in anisotropic nanoparticles. These ligands can also act as soft templates for site-selective deposition of functional coatings [2][3][4]. Quantitative details regarding the local attachment, distribution, and structure of these softhard interfaces would enable the development of methods for high-yield, monodisperse nanoparticle synthesis for applications ranging from catalysis [5] to drug delivery [6].Conventional techniques to characterize soft-hard interfaces-such as nuclear magnetic resonance, small angle x-ray scattering, and other bulk methods-lack the spatial resolution necessary to probe key details of the soft-hard interface, including how the surface structure and chemistry varies within and between individual particles [1]. Such limitations are critical in studying nanoparticles, where polydispersity is a defining characteristic and where surface energies and interactions vary widely based on local facet, curvature, and composition. While electron microscopy (EM) can in principle address this challenge, an ideal EM approach requires a combination of: low-background substrates, the ability to quantify elemental distributions of small molecules, and the speed and efficiency necessary to probe multiple nanoparticles. Here we report a particle-by-particle analysis of soft-hard interfaces on gold nanorods (AuNRs) using aberration-corrected scanning transmission electron microscopy (STEM) and electron energy loss spectroscopy (EELS) spectrum imaging on graphene substrates.In order to demonstrate the ability of EM methods to probe soft-hard interfaces, we investigate anisotropic mesoporous silica functionalization of AuNRs. Mesoporous silica can be deposited on AuNRs with site selectivity to either the ends or the sides. Such growth is thought to be templated by the anisotropic distribution of capping ligand cetyl trimethylammonium bromide (CTAB) [2, 3]. We spray deposited these mesoporous silica-coated AuNRs onto suspended graphene substrates. Using EELS spectral imaging, we map the presence of carbon, silicon, and oxygen. We are able to directly observe a mesoporous silica frame with carbon containing pores. On end silica-coated AuNRs, we identify the radial orientation of the pores and a 2.5 nm average pore size (Figure 1). The side coated AuNR pores are predominantly oriented parallel to the transverse axis with a 1.6 nm pore size (Figure 2). Furthermore, we observe an increased carbon signal on the surface of the nanoparticles, indicating the presence of a residual CTAB shell directly surrounding the particle (Figure 1d, 2d). Using graphene as a reference for the carbon inelastic scattering cross section, we are able to quantify the CTAB present before and after silica deposition. These results indicate that before deposit...
The ability to characterize and quantify anisotropic distributions of organic molecules at nanoparticle interfaces is a longstanding challenge in the realization and design of functional coatings, monodisperse synthesis, and colloidal assembly [1]. Here, we show that by using electron energy loss spectroscopy (EELS) spectral imaging on graphene substrates in an aberration-corrected scanning transmission electron microscope (STEM), we can directly visualize and quantify molecular distributions on gold nanorods (AuNRs). By contrasting the average distributions of two organic ligands across dozens of nanoparticles, we find that (16-mercaptohexadecyl)trimethylammonium bromide (MTAB) forms a uniform coating, while the distribution of cetyltrimethylammonium bromide (CTAB) his highly anisotropic. On average, CTAB binding density is reduced on the ends of gold nanorods, consistent with the higher reactivity of the nanorod ends reported in the literature [2]. Our results demonstrate the potential of our methods to directly probe local molecular distributions at soft-hard interfaces in order to understand nanoscale variations in the growth and reactivity of colloidal nanocrystals.
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