Sentence examples for hollow gap from inspiring English sources
During the formation of metal nanoparticles, a hollow gap 1 nm in size between metal nanoparticles may be produced by adopting DNA-assisted metal deposition techniques, as shown in the high-resolution transmission electron microscopy (HRTEM) image presented in Fig. 3e.
The SERS intensity increases by two orders of magnitude compared to metal nanoparticles without hollow gaps, as shown in Fig. 3f, due to plasmonic coupling between the metal core and the metal shell (Fig. 3g).
Going upstream in order they are: Beartrap Hollow, First Gap, Second Gap, Third Gap, and Fourth Gap.
As Fig. 9c shows, the samples obtained at 180 °C show a hollow and gapped spherical morphology.
The enlarged SEM image in Fig. 1b shows that the sphere-like nanoparticles are of a hollow and gapped microstructure.
To confirm the hollow and gapped spherical morphology, we observed the as-obtained BaTiO3 sample using a TEM microscope, and the typical results are shown in Fig. 2.
Contemporarily unlogged buffers and mature forest contained higher densities of trees with hollows than gap release and shelterwood creation areas, potentially providing more alternate bat roosts.
The high-magnification TEM image in Fig. 2b definitely shows that the BaTiO3 particles are of a hollow and gapped spherical morphology with an apparent diameter of ~100 nm.
A simple dynamic hydrothermal process has been developed to synthesize hollow and gapped BaTiO3 nanospheres with uniform size (93 ± 19 nm) at 180 °C for 10 20 h in aqueous solutions with [NaOH] = 1.0 mol/L and R Ba/Ti = 1.2.
In this study we injected the SAP, loaded with cytokines, into electrospun nanofiber channels, then showing that by engineering SAP-based matrices into neuroprosthetics it is possible to replace large hollow tissue gaps in the chronically injured spinal cord.
The dynamic hydrothermal process developed here provides an efficient method to obtain highly dispersed BaTiO3 nanospheres with gapped hollow structures, and the gapped hollow BaTiO3 nanospheres are expected to offer unique performance in dialectical applications.
