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, 399–411, doi:10.3762/bjnano.10.39
Figure 1: The organic and inorganic molecules used as precursors in the current study.
Figure 2: The growth rate of the QCM systems as function of (a) length of TTIP pulse, (b) TTIP purge, (c) org...
Figure 3: Evaluation of mass increase during growth by QCM using TTIP and thymine (at 225 °C), uracil (at 225...
Figure 4: Film growth as a function of deposition temperature for TTIP and thymine (black squares), adenine (...
Figure 5: (a) Refractive index at 632.8 nm as measured by spectroscopic ellipsometry and (b) film density as ...
Figure 6: Contact angle between water and films made of TTIP and (a) thymine (b) uracil and (c) adenine.
Figure 7: Evaluation of the mass increase during growth measured by QCM using TTIP and thymine (at 225 °C) (t...
Figure 8: Surface topography as measured by AFM for films deposited using TTIP and (a-1) thymine (at 250 °C, ...
Figure 9: SEM images of (a) the Ti-uracil film deposited (at 225 °C, 19 nm) and (b) the Ti-thymine (at 250 °C...
Figure 10: θ–2θ X-ray diffractogram for the Ti-thymine film deposited at 250 °C (black line), Ti-uracil deposi...
Figure 11: Carbon 1s for films based on adenine, thymine and uracil.
Figure 12: Titanium 2p peak for a hybrid film based on thymine. The binding energy is corrected by calibrating...
Figure 13: Nitrogen 1s peak for film based on thymine. The binding energy is corrected by calibrating towards ...
Figure 14: Carbon 1s peak for film based on thymine after water treatment. The binding energy is corrected by ...
Figure 15: FTIR spectra of powder form and hybrid films of TTIP and (a) thymine (225 °C, 114 nm) (b) uracil (2...