Big Chemical Encyclopedia

Chemical substances, components, reactions, process design ...

Articles Figures Tables About

Microscopy Figure 4-1, , photo

FIGURE 48.4 (a) Model of microdialysis system. Schematicof the mass transfer. (b)The schematic of stacked microdialysis system. The depth and width of PDMS channels are 30 and 1500 pm. The depth and width of SU-8 channels are 15 and 400 pm. (c) Electrodes SU-8 and PDMS channels under brightfield microscopy, (d) Photo of a complete device. (Reproduced from Hsieh, Y.-C. and Zahn, J. D., Biosens. Bioelectron., 22, 2422-2428, 2007. With permission.)... [Pg.1333]

Compound 4 was also found efficient against a completely antibiotic resistant strain of Burkholderia, specifically Burkholderia dolosa, which is resistant to clinical antibiotics in concentrations up to 5mgmL However, B. dolosa was found to be susceptible to 4 at significantly lower concentrations. Transmission electronic microscopy (TEM) photos of B. dolosa obtained after a 1 h treatment of 5 pgmL of 4 showed the powerful antimicrobial properties of the NHC-Ag. Figure 4.1 shows the morphology of the cell before and after treatment, when the cell was annihilated. [Pg.121]

FIGURE 10.10 An experimental system of tip-enhanced CARS microscopy. See the text for detail. ND nentral-density filter, P polarizer, DM dichroic mirror, BE beam expander, BS beam splitter, APD avalanche photo diode. [Pg.254]

Figure 1. Pitch coke 500°C., 75% l.t., optical microscopy by reflection on block from microtome X 900 photomontage (a) polarized light without analyzer (b) optical photos taken between crossed nicols... Figure 1. Pitch coke 500°C., 75% l.t., optical microscopy by reflection on block from microtome X 900 photomontage (a) polarized light without analyzer (b) optical photos taken between crossed nicols...
Figure 5.1.9 PEC solar cell. Bottom scheme of the cell with electron microscopy images of a particular of the Ti02-nanotube array electrode and of the Fe nanoparticles on N-doped carbon nanotubes, used as a photocatalyst for water oxidation and an electrocatalyst for CO2 reduction, respectively. It is also shown that it may be possible to use this cell for the production of H2/O2 in separate compartments by water photoelectrolysis. Top photo of the experimental cell and of the assembly of the photoanode with the Nafion membrane. Adapted from [14, 40, 52],... Figure 5.1.9 PEC solar cell. Bottom scheme of the cell with electron microscopy images of a particular of the Ti02-nanotube array electrode and of the Fe nanoparticles on N-doped carbon nanotubes, used as a photocatalyst for water oxidation and an electrocatalyst for CO2 reduction, respectively. It is also shown that it may be possible to use this cell for the production of H2/O2 in separate compartments by water photoelectrolysis. Top photo of the experimental cell and of the assembly of the photoanode with the Nafion membrane. Adapted from [14, 40, 52],...
Figure 4.26 Motion of isothermal chemical waves at the oscillation mode of the CO oxidation over the top of a platinum needle. The pattern with the atomic resolution is made by field-ion microscopy (FIM), and the photo frames are acquired in the successive several-second intervals [10]. (Courtesy of V. V. Gorodetsky)... Figure 4.26 Motion of isothermal chemical waves at the oscillation mode of the CO oxidation over the top of a platinum needle. The pattern with the atomic resolution is made by field-ion microscopy (FIM), and the photo frames are acquired in the successive several-second intervals [10]. (Courtesy of V. V. Gorodetsky)...
The electron microscopy pictures showed no pattern at compositions for which the light-scattering data were at the low level (Figure 4, right) for compositions with higher scattered intensity the photos indicated the presence of colloidal structures (Figure 4, left). [Pg.213]

Figure 4. The presence of inverse micelles indicated by Figure 3 was confirmed by electron microscopy (top). Where light scattering indicated no inverse micelles, the electron microscopy photo was featureless (bottom,). Figure 4. The presence of inverse micelles indicated by Figure 3 was confirmed by electron microscopy (top). Where light scattering indicated no inverse micelles, the electron microscopy photo was featureless (bottom,).
Figure 17.15 shows a transmission electron microscopy photograph of a cross section of the antireflective/antistatic film (photo intensity 12 mW/cm, substrate temperature 100°C). The Si02 and Sn02 films were prepared on a glass subsfrate and have fhicknesses of 700 A and 1000 A, respectively. These films are very... [Pg.214]

Figure 22. Scanning-microscopy photos of . ) CPG B) CPG which underwent hydrothermal modification at 300" C. Figure 22. Scanning-microscopy photos of . ) CPG B) CPG which underwent hydrothermal modification at 300" C.
FIGURE 245 Electron microscopy of catalyst contamination in PE film. The 125-p.m catalyst particle is buried in an originally 23-p.m thick film, which is oriented perpendicular to the plane of the photo. [Pg.565]

Figure 7 Scanning electron microscopy photo micrograph showing the boundary layer between the GSRI-PNF compound and a hard PMMA baseplate. Note the absence of a polymer domain structure in the PNP compound Photograph courtesy of Gulf South Research Institute (23). Figure 7 Scanning electron microscopy photo micrograph showing the boundary layer between the GSRI-PNF compound and a hard PMMA baseplate. Note the absence of a polymer domain structure in the PNP compound Photograph courtesy of Gulf South Research Institute (23).
In a recent study. Ford and coworkers reported the synthesis of 19 (Scheme 11.5), a luminescent photo-CORM (CO releasing molecule) based on 1, and easily incorporated in celk [67]. In this molecule the presence of the phosphine ligand increases its water solubility and makes the axial CO labile. Thus, upon irradiation, 19 released a CO molecule and was converted in its solvated (aqua) complex 20. Both molecules are strongly limiinescent, but notably their emission bands are centered at different wavelengths (515 and 585 nm, respectively). Consequently, accumulation of 19 in PPC-1 hiunan prostatic carcinoma cells (at a low concentration of incubation of 50 pM) followed by confocal microscopy is first associated with cells colored in blue (associated with the fluorescence of 19), and then release of CO upon irradiation led to green colored cells (associated with the fluorescence of 20) (Figure 11.7). [Pg.381]

Figure 4.6 is courtesy of the Electron Microscopy Society of Malaysia (EMSM), photo by Jefri Samin, http //ibs.upm.edu.my/ aini/micrograph.htm.Theimage was magn if ied 10OOX and is of activated carbon from coconut husk fiber. [Pg.231]

Figure 13 shows an example of an amphiphilic Janus dendrimer library containing 13 molecules (Fig. 13a), the cryo-TEM of the self-assembled monodisperse dendrimersomes (Fig. 13b), and the confocal microscopy photo of a giant... [Pg.190]

As seen in Figure 4.22, the immersion force can be significant between particles whose radii are larger than few nanometers. It has been found to promote the growth of 2D crystals from colloid particles [294-297], viruses, and globular proteins [298-304]. Such 2D crystals have found various applications in nanolithography [305], microcontact printing [306], as nanostructured materials in photo-electrochemical cells [307], in photocatalytic films [308], photo- and electroluminescent semiconductor materials [309], as samples for electron microscopy of proteins and viruses [310], as immunosensors [311], etc. (for reviews see Refs. [37,312]). [Pg.304]

Figure 11.3. Scanning electron microscopy photos of the surface morphology of a PES and PSf hollow fiber membranes and the inner skin layers of the composite membranes, (a) Inner surface of PES membrane (FESEM) (b) Inner surface of PSf membranes (c) skin layer of composite PES membranes (d) skin layer of composite PSf membranes. Coating solutions S-120 at 5 wt%. The pore radius of PES and PSf membranes are lOnm and 26 nm, respectively (He, 2001). Figure 11.3. Scanning electron microscopy photos of the surface morphology of a PES and PSf hollow fiber membranes and the inner skin layers of the composite membranes, (a) Inner surface of PES membrane (FESEM) (b) Inner surface of PSf membranes (c) skin layer of composite PES membranes (d) skin layer of composite PSf membranes. Coating solutions S-120 at 5 wt%. The pore radius of PES and PSf membranes are lOnm and 26 nm, respectively (He, 2001).
See other pages where Microscopy Figure 4-1, , photo is mentioned: [Pg.313]    [Pg.703]    [Pg.540]    [Pg.399]    [Pg.412]    [Pg.105]    [Pg.134]    [Pg.308]    [Pg.336]    [Pg.212]    [Pg.192]    [Pg.148]    [Pg.342]    [Pg.237]    [Pg.294]    [Pg.560]    [Pg.182]    [Pg.591]    [Pg.316]    [Pg.143]    [Pg.365]    [Pg.33]    [Pg.1246]    [Pg.394]    [Pg.69]    [Pg.396]    [Pg.2842]    [Pg.406]    [Pg.133]    [Pg.141]    [Pg.19]    [Pg.554]    [Pg.397]    [Pg.377]   
See also in sourсe #XX -- [ Pg.89 ]



SEARCH



Microscopy photo

© 2024 chempedia.info