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. 2019, 10, 894–900, doi:10.3762/bjnano.10.90
Figure 1: Schematic illustration of the experimental set-up to produce directed mesocrystals. A nanocrystal d...
Figure 2: SEM and TEM images of mesocrystals produced without (a) and with (b) external magnetic field. The m...
Figure 3: TEM images of two directed mesocrystals and their corresponding ED and FFT patterns. The large yell...
Figure 4: Comparison of a “self-assembled mesocrystal” and two “directed mesocrystals” with a projected p4mm ...
Beilstein J. Nanotechnol. 2016, 7, 351–363, doi:10.3762/bjnano.7.32
Figure 1: A) In the top-view the toroidal, the homohexameric structure of the Hcp1_cys3 mutant of Hcp1 shows ...
Figure 2: A) UV–vis spectra of Au NPs containing 2 equiv Hcp1_cys3 with 0 and 6 mM NaCl concentration. B) Det...
Figure 3: A) Overview of time-resolved UV–vis spectra during the self-assembly reaction of the Hcp1_cys3-func...
Figure 4: Cryo-TEM results by taking samples during the self-assembly reaction of the Hcp1_cys3-functionalize...
Figure 5: The interparticle distance of Au NPs was determined by calculation and by measuring the distances b...
Figure 6: Raman spectra of pure Hcp1_cys3, Au NPs with 2 equiv Hcp1_cys3 in 6 mM NaCl and Au Hcp1_cys3 networ...
Figure 7: A) UV–vis spectra of a 4-nitrophenol solution at different reaction times after the addition of the...
Figure 8: A) and B) SEM image and EDX analysis of Fe3O4 Hcp1_cys3 fiber-like structure after lyophilization. ...
Figure 9: A) Overview HRTEM image of magnetite NPs in the Fe3O4 Hcp1_cys3 fiber. B) HRTEM image from (A) over...
Figure 10: A) and B) Hysteresis curves at 300 K and 2 K, respectively. C) ZFC curves of the fibers and pure NP...
Figure 11: A) TEM and B) SEM images of CoFe2O4 Hcp1_cys3 sample after lyophilization. Chains of NPs and fiber-...
Beilstein J. Nanotechnol. 2015, 6, 134–148, doi:10.3762/bjnano.6.13
Figure 1: Magnetite formation inside a gelatin gel matrix (grey) that is placed inside the chitin scaffold of...
Figure 2: SANS macroscopic cross-section dΣ/dΩ versus scattering vector Q for a 1 mm thick piece of nacre in ...
Figure 3: Light microscopy image of thin cuts of embedded and Coomassie stained samples. a) Demineralized nac...
Figure 4: SEM micrographs of a) and b) fracture surfaces of artificial nacre and c) fracture surface of origi...
Figure 5: TEM micrographs of a) artificial nacre after one reaction cycle and b) after four reaction cycles, ...
Figure 6: SANS and VSANS scattering patterns of magnetite in gelatin–chitin composite and of ferrogel in a mi...
Figure 7: Magnetic properties of the synthesized hybrid materials. a) Magnetization curves of a representativ...
Figure 8: Degree of sample swelling plotted as a function of the swelling time at 23 °C for different samples...
Figure 9: Representative structure of a triple helical (Gly–Hyp–Pro)n peptide [44] of 100 Å length with two assoc...
Figure 10: Illustration of a β-chitin model [45] consisting of three poly-(1,4)-D-glucose chains of nine monomers ...
Figure 11: a) Representative structure for the coordination of FeIII(OH)3 by chitin. The ferric ion (light blu...
Figure 12: Force vs deformation characteristic of pure gelatin and gelatin with ferromagnetic particles. Intro...
Figure 13: Force vs deformation characteristics of the chitin scaffold and the final composite. Introduction o...