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1 ies of these processes have been revealed by scanning probe microscopy.
2 on the switching of individual domains using scanning probe microscopy.
3 n nanoelectromechanical systems, sensing and scanning probe microscopy.
4  the rare outer membrane proteins visible by scanning probe microscopy.
5 irus (CPMV), were compared by AC capacitance scanning probe microscopy.
6 carbon nanotubes have been used as probes in scanning probe microscopy.
7 ing, histologic analysis, and multifrequency scanning probe microscopy.
8 s, which cannot be matched using electron or scanning-probe microscopy.
9  ion conductance microscopy (SICM) and other scanning probe microscopies.
10 single molecules investigated by optical and scanning probe microscopies.
11  Cu(110) surface at 5 K, which is studied by scanning probe microscopy and density functional theory
12 of interest for many applications, including scanning probe microscopy and electron-stimulated patter
13  of functionalized force imaging, enabled by scanning probe microscopy and molecular force spectrosco
14                                        Using scanning probe microscopy and nano-dynamic mechanical an
15    The cell lysate content was measured with scanning probe microscopy and spectrophotometry.
16 ions, and illustrate the synergetic power of scanning probe microscopy and theoretical computation te
17                                   Studied by scanning probe microscopy and transmission electron micr
18 y combining the benefits of widely available scanning probe microscopy and vibrational microspectrome
19 r-field optical microscopy and spectroscopy, scanning probe microscopy, and cathodoluminescence in th
20 embled monolayers of GNRs can be observed by scanning probe microscopy, and non-contact time-resolved
21 , enabled by recent advances in electron and scanning probe microscopy, are discussed.
22 ace-based environment and the utilisation of scanning probe microscopies as a primary characterisatio
23         Here, we report a massively parallel scanning probe microscopy-based approach that can genera
24           Dip-pen nanolithography (DPN) is a scanning probe microscopy-based nanofabrication techniqu
25 omplements more widely used fluorescence and scanning probe microscopies by combining large-area meas
26 troscopy with the high spatial resolution of scanning probe microscopies by utilizing plasmonic nanos
27                                              Scanning probe microscopy can now be used to map the pro
28                         Using multifrequency scanning probe microscopy, collagen elastic modulus was
29                                              Scanning probe microscopy confirms that this modified co
30 ipulation capability already demonstrated by scanning probe microscopy could be combined with a nanot
31                                              Scanning probe microscopy facilitates high-resolution no
32                                              Scanning probe microscopy has become a powerful tool to
33                                              Scanning probe microscopy has emerged as a primary tool
34 r, recent advances in lithographies based on scanning probe microscopy have made use of transparent t
35                               Development of scanning-probe microscopies in the 1990s led to atomic-r
36                                  Advances in scanning probe microscopy now provide the tools to visua
37 ulation of individual atoms and molecules by scanning probe microscopy offers the ability of controll
38 hanism is corroborated with a combination of scanning probe microscopy, Raman spectroscopy, and densi
39                                              Scanning-probe-microscopy results demonstrate the existe
40                                              Scanning probe microscopies (SPM) and cantilever-based s
41                                  Advances in scanning probe microscopies (SPM) have allowed the mecha
42 f thiolates on Au by using shear force-based scanning probe microscopy (SPM) combined with current-vo
43 or arylates on Au by using shear force-based scanning probe microscopy (SPM) combined with current-vo
44         In this article, a brief overview of scanning probe microscopy (SPM) methods addressing nanos
45 trated a new comprehensive method to combine scanning probe microscopy (SPM) nanolithography and modi
46       This review gives an overview of using Scanning Probe Microscopy (SPM), in particular Scanning
47 nce microscopy (SICM) is a nanopipette-based scanning probe microscopy technique that utilizes the io
48 ates the implementation of voltage-modulated scanning probe microscopy techniques such as Kelvin prob
49 many years, researchers have been developing scanning probe microscopy techniques to improve imaging
50 lectrochemical strain microscopy, the biased scanning probe microscopy tip acts as a moving, electroc
51  in dimension to the effective diameter of a scanning probe microscopy tip.
52 gations into the performance of nanotubes as scanning probe microscopy tips have focused on topograph
53 have occurred recently in the application of scanning probe microscopy to biology.
54 ity and are paired with molecular-resolution scanning probe microscopy to elucidate the structure of
55                                     By using scanning probe microscopy, we show that the fast ion-con
56     Tip-enhanced Raman spectroscopy combines scanning probe microscopy with plasmon-enhanced Raman sc
57 bines the atomic-scale imaging capability of scanning probe microscopy with the single-molecule chemi

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