Atomic force microscopy imaging

Wilson D L, Kump K S, Eppell S J and Marchant R E 1995 Morphological restoration of atomic force microscopy images Langmuir 265... 

Raza H, Pang C L, Haycock S A and Thornton G 1999 Non-contact atomic force microscopy imaging of 7102(100) surfaces Appl. Surf. Sc/. 140 271... 

Figure 3. Atomic force microscopy image of an etched fiber bundle (a) before and (b) after microspheres were distributed into the array. Reprinted with permission from ref. 5 Copyright 1998 American Chemical Society.

Demanet CM, Sankar KV. Atomic force microscopy images of a pollen grain A preliminary study. S Afr JBot 1996 62 221—223. 

Cover Illustration Atomic force microscopy image of molybdenum oxide particles on flat, silicon dioxide substrate, which serves as a model system for a supported catalyst. The area shown corresponds to one square micrometer the maximum difference in height is approximately 10 nanometer. The superimposed curve is the secondary ion mass spectrum of the model catalyst, showing the caracteristic isotopic patterns of single molybdenum ions and of molybdenum oxide cluster ions. 

Figure 4.21 Atomic force microscopy images showing the morphology of coloured Si02-PMM A hybrid coatings with molar ratio formulation of 1 0.5 1.0 TEOS-TMSPM MMA, with different concentrations and types of colour (a) no colour (b) 0.17 wt% of blue colour (c) 0.83 wt% of green colour. The values of the r.m.s. average roughness measured for the three films was 0.47, 0.65 and 0.45 nm, respectively. (Reproduced from ref. 21, with permission.)...

Figure 2. Atomic force microscopy images showing the surface of a rhesus monkey erythrocyte membrane. Damage, such as formation of humps on the peripheral surface and pits in other parts, results from the interaction with virions of the canine parvovirus, (a) edge of erythrocyte (b) pits on membrane surface. (Source http //www.ntmdt.ru/ publications/download/211.pdf, Reproduced with permission from Dr Boris N. Zaitser)...

Fig. 12.9 Graphene-oxide-based mesoporous silica (GM-silica) sheets, (a) Fabrication process for GM-silica sheets, (b), (c) Typical SEM and (d), (e) TEM images reveal the flat GM-silica sheets with sizes from 200 nm to several micrometers having a mesoporous structure, (f) Representative atomic force microscopy image and (g) corresponding thickness analysis taken around the white line in (f) reveal a uniform thickness of 28 nm for GM-silica sheets. Reprinted with permission from [90]. Copyright 2010, John Wiley 8i Sons, Inc.

FIGURE 7.1 Atomic force microscopy image of prednisolone-loaded Compritol nanoparticles produced by cold homogenization. Imaging was performed by using the noncontact mode. The formulation is composed of 5% Compritol, 1% prednisolone, 2.5% poloxamer 188, and 92.5% water. (From zur Miihlen, A. and Mehnert, W., Pharmazie, 53, 552-55, 1998. With permission.)... 

Dubes, A., et al.. Scanning electron microscopy and atomic force microscopy imaging of solid lipid nanoparticles derived from amphiphihc cyclodextrins. Eur. J. Pharm. Biopharm., 55, 279-82, 2003. 

Figure 14.7 (Left) Molecular model of several self-complementary peptides and (right) atomic force microscopy images of nanohber scaffolds formed by RADA16-I. Reprinted from Zhao and Zhang (2006). Copyright 2006 RSC Publishing.

Fig. 6 (a) Scanning electron and (b) atomic force microscopy images of copper phthalocyanine Langmuir-Blodgett monolayer FETs. (c) Hole field-effect mobility as a function of the copper phthalocyanine channel length... 

Fig. 2.55 (a) Atomic force microscopy image (constant force mode) of islands at the surface of a PS PUMA diblock (M = 82 kg mol1) copolymer film (Maaloum et al. 1992). The height of the islands is 310A. (b) Section of one domain with a diameter of Afim. (c) Assumed structure at the domain edge. 

Figure 10.5 High resolution Atomic Force Microscopy image of plasmid DNA adsorbed on a cationic bilayer (DPTAP) coating a freshly cleaved mica surface. The highly packed DNA chains are clearly visible. The measured width of DNA is 2nm, close to the diameter of B-DNA (Adapted fromMou etal., 1995 Fang and Yang, 1997).

High resolution Atomic Force Microscopy image of plasmid DNA adsorbed on a cationic 178 bilayer (DPTAP) coating a freshly cleaved mica surface. The highly packed DNA chains... 

Hahm J, Sibener SJ (2001) Time-resolved atomic force microscopy imaging studies of asymmetric PS-b-PMMA ultrathin films dislocation and disclination transformations, defect mobility, and evolution of nanoscale morphology. J Chem Phys 114(10) 4730-4740... 

Fig. 7 Atomic force microscopy image illustrating defect structures in wrinkled surfaces prepared by plasma treatment of stretched PDMS and subsequent relaxation...

FIGURE 7.16. The peptide KFEs (of sequence FKFEFKFE) self-assembles in aqueous solution into left-handed helical ribbons, (a) Atomic force microscopy image (500 nm x 500 nm) of a peptide solution deposited over mica 8 min after preparation, (b) Same sample, 4 days after preparation (1 pm x 1 pm). 

Wilson, D.L., K.S. Kump, S.J. Eppell, and R.E. Marchant. 1995. Morphological restoration of atomic-force microscopy images. Langmuir 11 265-272. 

Fig. 6 Typical atomic force microscopy images showing the effect of chemical reagents on BC fibers, a-d the same as in Fig. 5 - bacterial cell. Reprinted with permission from [37]...

See color plate) Atomic force microscopy images and drug release kinetics of the paclitaxel-poly(styrene-i>isobutylene-i>styrene) polymer combination. Abbreviations PTx, paclitaxel SIBS, poly(styrene-b-isobutylene-b-slyrene). 

Figure 8.1 Nanofibers from p6P on muscovite mica, (a) Fluorescence microscopy image, (b) Atomic force microscopy image height scale 70 nm. p6P clusters are visible between the fibers, (c) Needles consist of lying molecules with the (1-1-1) plane facing the substrate the long needle axis (arrow) is parallel to the grooved mica direction. Dr. Frank Balzer is thanked for providing the images.

Figure 8.7 Nano walking sticks of MOCNP4 (a) fluorescence microscopy image (100 x 100pm2), and (b, c) atomic force microscopy images (b) 42 x 42 pm2, height scale 260nm, (c) 5 x 5pm2, height scale llOnm. Ts = 380K, film thickness 8nm.

Figure 8.9 Atomic force microscopy images of nanostructures from the symmetrically substituted p4Ps NHP4, NMeP4, and CNP4. Height scales 150nm, 250nm, lOOnm, respectively. Cross-sections (width x height) show the respective dimensions.

Figure 10 Atomic force microscopy image of a fibril microarray. The pattern was created by charge-writing using atomic force microscopy. The scale bar is 10 pm in length. Reprinted with permission from Mesquida et al. (2006) (copyright 2006 American Chemical Society).

Figure 11 Atomic Force Microscopy image of aligned PTAA coated insulin fibrils that have been transferred to a glass surface after molecular combing directly onto the surface of a PDMS stamp. The lines have been added to illustrate gaps within the PDMS stamp. The scale bar is 2 mm in length (Herland, Bjdrk et at, 2007). Copyright Wiley-VCH Verlag GmbH Co. KGaA. Reproduced with permission.

Sriamornsak P, Thirawong N, Nunthanid J, Puttipipatkhachorn S, Thongborisute J, Takeu-chi H (2008) Atomic force microscopy imaging of novel self-assembling pectin-liposome nanocomplexes. Carbohydr Polym 71 (2) 324—329 Takeuchi H, Yamamoto H, Niwa T, Hino T, Kawashima Y (1994) Mucoadhesion of polymer-coated liposomes to rat intestine in vitro. Chem Pharm Bull 42(9) 1954-1956 Takeuchi H, Yamamoto H, Niwa K, Hino T, Kawashima Y (1996) Enteral absorption of insulin in rats from mucoadhesive chitosan-coated liposomes. Pharm Res 13 896-901 Takeuchi H, Kojima H, Yamamoto H, Kawashima Y (2000) Polymer coating of liposomes with a modified polyvinyl alcohol and their systemic circulation and RES uptake in rats. J Control Rel 68(2) 195-205... 

Shaw JE, Epand RE, Sinnathamby K, Li Z, Bittman R, Epand RM, Yip CM. Tracking peptide-membrane interactions insights from in situ coupled confocal-atomic force microscopy imaging of NAP-22 peptide insertion and assembly. J. Struct. Biol. 2006 155 458-469. 

Fig. 3.15 Atomic force microscopy images of poly(oxy methylene) with molecular resolution (a) raw data (b) image obtained from Fourier reconstruction. The arrow indicates the polymer chain direction (image size 7x7 nm2 Reproduced with permission from [38]). Copyright 1992. American Chemical Society, (c) AFM height image and (d) corresponding autocorrelation-filtered image acquired on POM crystals obtained by solid state polymerization [39]. Reproduced with permission from [39]. Copyright 1994. The Royal Society of Chemistry...

Fig. 7 Atomic force microscopy image and the cross section of the residual impression made at 3mN. (Li, X. Zhang, L. Gao, H. Micro/ nanomechanical characterization of a single decagonal AlCoNi quasicrystal. J. Phys. D Appl. Phys. 2004,37, 753-757).

---