This search combines search strings from the content search (i.e. "Full Text", "Author", "Title", "Abstract", or "Keywords") with "Article Type" and "Publication Date Range" using the AND operator.
Beilstein J. Nanotechnol. 2021, 12, 462–472, doi:10.3762/bjnano.12.37
Scheme 1: Schematic illustration of the synthesis and photothermal of the Au@Pt NRs.
Figure 1: TEM images of (a) AuNRs, (b) Au@Pt−Ag+, and (c) Au@Pt+Ag+. (d) Absorption spectra of AuNRs (black),...
Figure 2: (a) Absorption spectra of AuNRs and of Au@Pt NRs synthesized with different concentrations of Ag+. ...
Figure 3: Absorption spectra of AuNRs and of different Au@Pt NRs synthesized in (a) absence and (c) presence ...
Figure 4: (a) Absorption spectra of AuNRs and of Au@Pt NRs prepared under optimal conditions. (b) TEM image o...
Figure 5: (a) Temperature elevation curves of deionized water (black), AuNRs solution (OD = 0.5, red) and Au@...
Figure 6: Heating and cooling curves of (a) AuNRs and (c) Au@Pt NRs under 808 nm laser irradiation. Linear fi...
Figure 7: Temperature change curve of (a) Au@Pt NPs solution and (b) AuNRs solution during four on/off cycles...
Beilstein J. Nanotechnol. 2019, 10, 1423–1433, doi:10.3762/bjnano.10.140
Figure 1: (a) XRD patterns of pure WO3 and Mn3O4/WO3 composites, and (b) the magnified region of the (402) pe...
Figure 2: SEM images of (a) WO3, (b) 1 atom %, (c) 3 atom % and (d) 5 atom % Mn3O4/WO3 composites.
Figure 3: (a) TEM image and (b,c) HRTEM image of 5 atom % Mn3O4/WO3 composites.
Figure 4: N2 adsorption–desorption isotherms of pure WO3 and Mn3O4/WO3 composites.
Figure 5: (a) XPS survey spectrum of 5 atom % Mn3O4/WO3 composites. High-resolution XPS scan: (b) W 4f region...
Figure 6: Response of WO3 and Mn3O4/WO3 composite based gas sensors to 10 ppm H2S, 100 ppm NH3 and 100 ppm CO...
Figure 7: Response of WO3 and Mn3O4/WO3 composites to H2S, NH3 and CO at (a) 90 °C, (b) 150 °C and (c) 210 °C...
Figure 8: Dynamic response/recovery curves of 3 atom % Mn3O4/WO3 composite based gas sensors toward (a) H2S a...
Figure 9: (a, c, e) Response trends with respect to concentration and (b, d, f) corresponding log(S − 1) vs l...
Figure 10: Gas selectivity analysis of 3 atom % Mn3O4/WO3 composites at (a) 90 °C, (b) 150 °C and (c) 210 °C.
Figure 11: Stability of the 3 atom % Mn3O4/WO3 composite based gas sensor.
Figure 12: The gas sensing schematic models of WO3 (a,b) and Mn3O4/WO3 composites (c,d) in air and in CO.
Beilstein J. Nanotechnol. 2014, 5, 717–725, doi:10.3762/bjnano.5.84
Figure 1: (a) A perfect GNR with 3% B-dopant. (b) A perfect GNR with 1.5% B- and 1.5% N-dopant. (c) Velocity ...
Figure 2: (a) Variation in time of the external energy obtained from a perfect GNR. (b) The corresponding fre...
Figure 3: Variation of history of the external energy over time for a perfect GNR with B-dopant densities of ...
Figure 4: Variation of the external energy over time for a perfect GNR with B- and N-dopants. The total densi...
Figure 5: (a) Variation of the external energy over time obtained for a pristine GNR with two vacancies. The ...
Figure 6: Variation of the external energy over time for a defective GNR (two vacancies) with B-dopant. The d...
Figure 7: Variation of the external energy over time for the defective GNR (two vacancies) with both B- and N...
Figure 8: (a) Time history of the external energy obtained from pristine defective GNR with four vacancies. T...
Figure 9: Variation over time of the external energy of the defective GNR with four vacancies and B-dopant de...
Figure 10: Variation over time of the external energy for the defective GNR (four vacancies) with both B- and ...
Figure 11: Results of the defective GNR (four vacancies) with 1.20% B- and 1.20% N-dopant. (a) Variation over ...
Figure 12: (a) Comparisons of the relative natural frequency among all studied samples. (b) Comparisons of the...