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Beilstein J. Nanotechnol. 2019, 10, 2039–2061, doi:10.3762/bjnano.10.200
Figure 1: One of the polymorphs of the microporous ETS-10 consisting of TiO6 octahedra and SiO4 tetrahedra sh...
Figure 2: X-ray diffractograms of the as-synthesized ETS-10 material (Na,K-ETS-10, top) and of the reference ...
Figure 3: SEM micrographs of selected crystals representing different types of phases formed during the synth...
Figure 4: Nitrogen adsorption (solid circles) and desorption (open circles) isotherms of the as-synthesized N...
Figure 5: Hg intrusion data of the as-synthesized Na,K-ETS-10 material.
Figure 6: TEM micrographs for the Na,K-ETS-10 material obtained with different magnifications demonstrating a...
Figure 7: (A) XRD data of post-synthetically treated titanosilicates. The calculated crystallinity decreased ...
Figure 8: SEM micrographs of the titanosilicates treated with H2O2 for 30, 45 and 60 min (P-ETS-10/30, P-ETS-...
Figure 9: (A) Nitrogen adsorption and desorption isotherms of titanosilicates treated with H2O2 for 30 min (l...
Figure 10: TEM images of the selected crystals of P-ETS-10/60 and C-P-ETS 10/60 demonstrating the presence of ...
Figure 11: Differential thermal analysis of the Na,K-ETS-10 (red), P-ETS-10/60 (blue) and C-P-ETS-10/60 (green...
Figure 12: Temperature-programmed desorption of NH3 (A) and CO2 (B) in Na,K-ETS-10 (red), P-ETS-10/60 (blue) a...
Figure 13: The HPDEC (A) and CP (B) 29Si MAS NMR spectra obtained for Na,K-ETS-10 (red), P-ETS-10/60 (blue) an...
Figure 14: The EPR spectra measured with Na,K-ETS-10 (red), P-ETS-10/60 (blue) and C-P-ETS-10/60 (green) at 70...
Figure 15: Variable temperature HP 129Xe NMR spectra acquired on Na,K-ETS-10 (A, red), P-ETS-10/60 (B, blue) a...
Figure 16: 1H PFG NMR diffusion attenuation curves of bulk triolein (dashed line) and triolein in oversaturate...
Figure 17: Schematic representation of the diffusion modes denoted as 1, 2 and 3 in the Figure 16 as observed by PFG NM...
Figure 18: Conversion of triolein over CaO- (A) and ETS-10-based (B) catalysts at 403 K measured for different...
Beilstein J. Nanotechnol. 2017, 8, 1427–1445, doi:10.3762/bjnano.8.143
Figure 1: Spin dependent processes in organic solar cells. (Right) The steps from light absorption (a) toward...
Figure 2: Vector model of the spin states of a radical pair. Here the red and blue arrows show the spin vecto...
Figure 3: Schematic representation of the energy levels of a radical pair. The spacing between the S and T0 l...
Figure 4: Schematic representation of singlet−triplet transitions in a radical pair. Top: S−T0 transitions oc...
Figure 5: Formation of MFEs upon recombination of SCRPs. In this example the (R1R2) molecule goes to the sing...
Figure 6: Re-encounters of radicals. In liquids, particles usually move by means of diffusion. In this situat...
Figure 7: Calculated time-resolved MFE traces as obtained by monitoring recombination fluorescence, resulting...
Figure 8: MARY curve, i.e., magnetic field dependence of the reaction yield for a singlet-born radical pair. ...
Figure 9: Principle of the RYDMR method. Top: reaction scheme – interconversion mixes the S and T0 of a radic...
Figure 10: Top: Populations of the electronic spin state of an SCRP – when the radical pair is singlet-born in...
Figure 11: Scheme of CIDNP formation by spin sorting at high magnetic fields. Top: EPR spectra of the two radi...
Figure 12: Scheme of triplet-state OEP and ONP formation. In anisotropic molecules, the ISC process S1→T1 has ...