8 article(s) from Hinaut, Antoine
Figure 1: (a) Scheme of the high-vacuum electrospray deposition device. Typical working pressures of the diff...
Figure 2: C60 on a Au(111) surface. (a) After TE and (b) After HV-ESD. (c) Zoom on an island after HV-ESD. (d...
Figure 3: C60 on a KBr(001) surface. (a) After TE, (b) after low-coverage HV-ESD, and (c) after high-coverage...
Figure 4: C60 on a NiO(001) surface. (a) Large scale topography nc-AFM image after TE; inset: zoom on an isla...
Figure 1: Reconstructed KBr on the Ir(111) surface. (a) Large-scale KBr island with irregular shape (A1 = 5 n...
Figure 2: (a) Atomic resolution of a corrugated KBr line structure (A2 = 300 pm, Δf2 = −125 Hz, γ = −1.02 pN·...
Figure 3: DFT simulation of a monolayer KBr on Ir(111). (a) Optimization of a reconstructed KBr layer on Ir(1...
Figure 4: Cubic KBr on the GR/Ir(111) surface. (a) Two different KBr structures have been discovered on GR/Ir...
Figure 1: (a) Principle of n- and p-type DSSCs showing opposite charge transfer directions. (b) Structures of...
Figure 2: The surface of NiO(001). (a) Large-scale topographic image of the NiO(001) crystal showing clean te...
Figure 3: (a) Large-scale topographic image showing that Cu-TCPP molecules form islands on the surface of NiO...
Figure 4: (a) Large-scale topographic image showing that C343 molecules form islands on the surface of NiO(00...
Figure 5: (a, b) CPD measurements of Cu-TCCP and C343 islands on the NiO(001) substrate, respectively (scan p...
Figure 1: Structure of 4,4′-di(4-carboxyphenyl)-6,6′-dimethyl-2,2′-bipyridine. The trans-conformation of DCPD...
Figure 2: From large-scale imaging to atomic resolution on NiO(001). (a) Large scale topographic image of the...
Figure 3: Single DCPDMbpy molecules on NiO(001). (a) Topographic image of NiO(001) covered with DCPDMbpy afte...
Figure 4: Windmill-shaped cluster on NiO(001). (a) Topographic image of DCPDMbpy forming molecular clusters o...
Figure 5: Islands of DCPDMbpy on NiO(001). (a, b) simultaneous topographic and CPD measurements of the molecu...
Figure 1: Adsorption of ZnPc molecules on the TiO2(011)-(2×1) surface. From left to right: empty state STM im...
Figure 2: Geometrical characterization of 0.9 ML of ZnPc molecules on the TiO2(011)-(2×1) surface. (a) Illust...
Figure 3: Geometrical characterization of 1.3 ML of ZnPc molecules on a TiO2(011)-(2×1) surface after deposit...
Figure 4: The tentative structural model of the first (b) and the second (c) phases of the molecular chain ar...
Figure 5: 250 × 250 nm empty state STM images of ZnPc (a) and CuPc (b) structures formed on top of the ZnTPP ...
Figure 6: 50 × 50 nm empty state STM images of ZnPc (a) and CuPc (b) structures formed on top of the ZnTPP we...
Figure 7: TiO2(011)-(2×1) reconstructed surface. (a) 9 × 9 nm empty state STM image; scanning parameters: I =...
Figure 8: Chemical structure of the molecules used in the study (from left to right): Zn(II)meso-tetraphenylp...
Figure 1: The discussed molecular species (a) PTCDA, (b) metal-free phthalocyanine (H2Pc), in which the centr...
Figure 2: Empty-state STM images of the densely packed molecular structures. (a) and (b): the closed layer PT...
Figure 3: The adsorption geometries of CuPc molecules on the TiO2(011) substrate (coverage: 0.06 ML): (a) a s...
Figure 4: STM images of 2H-TPP and NiTPP molecules on the TiO2(110)-(1 × 1) surface. (a) and (b) 2H-TPP molec...
Figure 5: A linear π–π-stacked structure formed by COOH-ZnTPP molecules on a TiO2(011)-(2 × 1) surface – see ...
Figure 1: Scheme of the commercial ESI setup [33] (1 to 5) connected to the UHV chamber (7), i.e., sample prepara...
Figure 2: a) Topography image of the KBr(001) surface after the application of UHV-ESI with a mixture of tolu...
Figure 3: a) Chemical structure of the used triply fused diporphyrin molecule derivative prepared according t...
Figure 4: Topography image (400 × 400 nm2) of diporphyrins on KBr(001) after 1 h of annealing at 350 K. Diffe...
Figure 5: a) Topography image of a diporphyrin island on KBr(001). b) Corresponding dissipation image. c) Isl...
Figure 6: Topography image (40 × 40 nm2) of the KBr(001) surface with a low coverage of diporphyrin molecules...
Figure 7: a) High resolution topography image of a single diporphyrin on KBr(001) at room temperature. b) Sam...
Figure 1: (a) Molecular scheme and (b) structure of HCPTP optimized in vacuum.
Figure 2: Constant-frequency-shift image of the KBr surface after the deposition of a small amount of molecul...
Figure 3: Upper image: topography and lower image: Kelvin map of a KBr terrace with a higher coverage. Imagin...
Figure 4: Images of a sample annealed at 150 °C after the deposition of the molecules at room temperature. (a...
Figure 5: (a) and (b) are the profiles that correspond to the blue and green lines drawn in Figure 4a; (c) is the prof...
Figure 6: (a) Topographic and (b) Kelvin map of a high molecular coverage annealed to 150 °C; (c) and (d) are...
Figure 7: High resolution topographic images of an MLh domain. A = 2 nm. (a) Δf = −35 Hz, (b) Δf = −50 Hz. Th...
Figure 8: High resolution (a) topographic and (b) Kelvin image of an MLv domain. A = 2 nm, Δf = −20 Hz. The a...
Figure 9: Lowest-energy adsorbed conformation of HCPTP adsorbed on KBr(001). (a) Top and (b) side view. K+ io...
Figure 10: Tentative model of the MLh layer.