Measurements of In-Plane Material Properties with Scanning Probe Microscopy

MRS Bulletin ◽  
2004 ◽  
Vol 29 (7) ◽  
pp. 472-477 ◽  
Author(s):  
Robert W. Carpick ◽  
Mark A. Eriksson
Keyword(s):  
Scanning Probe Microscopy ◽  
Material Properties ◽  
Lateral Displacement ◽  
Atomic Scale ◽  
Scanning Probe ◽  
Structural Anisotropy ◽  
Probe Microscopy ◽  
Parallel Motion ◽  
Intermittent Contact ◽  
Friction Measurements

AbstractScanning probe microscopy (SPM) was originally conceived as a method for measuring atomic-scale surface topography. Over the last two decades, it has blossomed into an array of techniques that can be used to obtain a rich variety of information about nanoscale material properties. With the exception of friction measurements, these techniques have traditionally depended on tip—sample interactions directed normal to the sample's surface. Recently, researchers have explored several effects arising from interactions parallel to surfaces, usually by deliberately applying a modulated lateral displacement. In fact, some parallel motion is ubiquitous to cantilever-based SPM, due to the tilt of the cantilever. Recent studies, performed in contact, noncontact, and intermittent-contact modes, provide new insights into properties such as structural anisotropy, lateral interactions with surface features, nanoscale shear stress and contact mechanics, and in-plane energy dissipation. The understanding gained from interpreting this behavior has consequences for all cantilever-based scanning probe microscopies.

Atomic Scale Imaging: A Hands-On Scanning Probe Microscopy Laboratory for Undergraduates

2003 ◽  
Vol 80 (2) ◽  
pp. 194 ◽  
Author(s):  
Chuan-Jian Zhong ◽  
Li Han ◽  
Mathew M. Maye ◽  
Jin Luo ◽  
Nancy N. Kariuki ◽  
...  
Keyword(s):  
Scanning Probe Microscopy ◽  
Atomic Scale ◽  
Scanning Probe ◽  
Probe Microscopy ◽  
Hands On

Scanning Probe Microscopy Measurements of Friction

MRS Bulletin ◽  
2004 ◽  
Vol 29 (7) ◽  
pp. 478-483 ◽  
Author(s):  
Scott S. Perry
Keyword(s):  
Scanning Probe Microscopy ◽  
Sliding Contact ◽  
Scanning Probe ◽  
Interfacial Friction ◽  
Probe Microscopy ◽  
Frictional Properties ◽  
Single Asperity ◽  
Friction Measurements ◽  
Detection Schemes ◽  
Tribological Contact

AbstractThis article describes the details of scanning probe microscopy measurements of interfacial friction from an experimental perspective. In such studies, the probe tip is taken as a model of a single asperity within a tribological contact, and interfacial forces are measured as a function of the sliding contact of the probe tip with the surface. With appropriate detection schemes, friction and load forces can be monitored simultaneously and used together to describe the frictional properties of the microscopic contact. This article provides a detailed description of the procedures and protocols of friction measurements performed with scanning probe microscopy, the relevant properties of probe tips, and the influence of environment on microscopic friction measurements. In addition, the article provides a brief overview of several categories of friction studies performed with scanning probe microscopy, highlighting the type of materials characterized in these studies as well as the importance and impact of the microscopic measurements.

Scanning Probe Microscopy

2021 ◽  
pp. 745-802
Author(s):  
Kannan M. Krishnan
Keyword(s):  
Scanning Probe Microscopy ◽  
Tunneling Current ◽  
Force Sensor ◽  
Dynamic Imaging ◽  
Scanning Probe ◽  
Constant Current ◽  
Probe Microscopy ◽  
Adsorbed Atoms ◽  
Intermittent Contact ◽  
Local Electronic Structure

Scanning probe microscopy (SPM) scans a fine tip close to a surface and measures the tunneling current (STM) or force (SFM), based on many possible tip-surface interactions. STM provides atomic resolution imaging, or the local electronic structure (spectroscopy) as a function of bias voltage, and is also used to manipulate adsorbed atoms on a clean surface. STM operates in two modes— constant current or height—and requires a conducting specimen. SFM uses a cantilever (force sensor) to measure short range (< 1 nm) chemical, and a variety of long-range (< 100 nm) forces, depending on the tip and the specimen; a conducting specimen is not required. In static mode, the tip height is controlled to maintain a constant force, and measure surface topography. In dynamic mode, changes in the vibrational properties of the cantilever are measured using frequency, amplitude, or phase modulation as feedback to control the tip-surface distance and form the image. Dynamic imaging includes contact and non-contact modes, but intermittent contact or tapping mode is common. SPMs measure properties (optical, acoustic, conductance, electrochemical, capacitance, thermal, magnetic, etc.) using appropriate tips, and find applications in the physical and life sciences. They are also used for nanoscale lithography.

scholarly journals Pure hydrogen low-temperature plasma exposure of HOPG and graphene: Graphane formation?

2012 ◽  
Vol 3 ◽  
pp. 852-859 ◽  
Author(s):  
Baran Eren ◽  
Dorothée Hug ◽  
Laurent Marot ◽  
Rémy Pawlak ◽  
Marcin Kisiel ◽  
...  
Keyword(s):  
Low Temperature ◽  
Scanning Probe Microscopy ◽  
Atomic Scale ◽  
Scanning Probe ◽  
Scanning Tunneling ◽  
Multilayer Graphene ◽  
Pure Hydrogen ◽  
Low Temperature Plasma ◽  
Temperature Plasma ◽  
Probe Microscopy

Single- and multilayer graphene and highly ordered pyrolytic graphite (HOPG) were exposed to a pure hydrogen low-temperature plasma (LTP). Characterizations include various experimental techniques such as photoelectron spectroscopy, Raman spectroscopy and scanning probe microscopy. Our photoemission measurement shows that hydrogen LTP exposed HOPG has a diamond-like valence-band structure, which suggests double-sided hydrogenation. With the scanning tunneling microscopy technique, various atomic-scale charge-density patterns were observed, which may be associated with different C–H conformers. Hydrogen-LTP-exposed graphene on SiO2 has a Raman spectrum in which the D peak to G peak ratio is over 4, associated with hydrogenation on both sides. A very low defect density was observed in the scanning probe microscopy measurements, which enables a reverse transformation to graphene. Hydrogen-LTP-exposed HOPG possesses a high thermal stability, and therefore, this transformation requires annealing at over 1000 °C.

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