Platinum nanodot formation by atomic point contact with a scanning tunneling microscope platinum tip

1998 ◽  
Vol 73 (23) ◽  
pp. 3360-3362 ◽  
Author(s):  
D. H. Huang ◽  
T. Nakayama ◽  
M. Aono
Keyword(s):  
Scanning Tunneling Microscope ◽  
Point Contact ◽  
Scanning Tunneling ◽  
Tunneling Microscope

Movement of scattering centers in a point contact induced by a scanning tunneling microscope

1994 ◽  
Vol 194-196 ◽  
pp. 991-992
Author(s):  
S.E. Kubatkin ◽  
H. Olin ◽  
P. Davidsson ◽  
A.V. Danilov ◽  
T. Claeson
Keyword(s):  
Scanning Tunneling Microscope ◽  
Point Contact ◽  
Scanning Tunneling ◽  
Tunneling Microscope ◽  
Scattering Centers

Thermoelectric Measurements of Ni Nanojunctions

2013 ◽  
Vol 1490 ◽  
pp. 139-144 ◽  
Author(s):  
See Kei Lee ◽  
Ryo Yamada ◽  
Hirokazu Tada
Keyword(s):  
Scanning Tunneling Microscope ◽  
Point Contact ◽  
Histogram Analysis ◽  
Scanning Tunneling ◽  
Transport Channel ◽  
Tunneling Microscope ◽  
Channel Distribution ◽  
Thermoelectric Measurements ◽  
Thermoelectric Voltage ◽  
Voltage Peak

ABSTRACTWe investigated the thermoelectric voltage (TEV) of atomic contacts of nickel (Ni) by using a scanning tunneling microscope. The TEV of nanoscale junctions show fluctuation in stepwise manner. Histogram analysis of TEV observed in the Ni point contact with the conductance of 1.2 G0 (G0 = 2e2/h is the quantum of charge conductance) revealed multiple voltage peaks at larger and smaller values observed at conductance of 2.5 G0, which showed a single sharp voltage peak. Fluctuation observed in our results suggest that there is transition of the transport channel distribution caused by the thermal motion of Ni atoms.

scholarly journals Atomic-scale spin sensing with a single molecule at the apex of a scanning tunneling microscope

Science ◽  
2019 ◽  
Vol 366 (6465) ◽  
pp. 623-627 ◽  
Author(s):  
B. Verlhac ◽  
N. Bachellier ◽  
L. Garnier ◽  
M. Ormaza ◽  
P. Abufager ◽  
...  
Keyword(s):  
Single Molecule ◽  
Scanning Tunneling Microscope ◽  
Point Contact ◽  
Copper Surface ◽  
Atomic Scale ◽  
Spin Excitation ◽  
Scanning Tunneling ◽  
Detection Scheme ◽  
Tunneling Microscope ◽  
Spin Excitations

Recent advances in scanning probe techniques rely on the chemical functionalization of the probe-tip termination by a single molecule. The success of this approach opens the prospect of introducing spin sensitivity through functionalization by a magnetic molecule. We used a nickelocene-terminated tip (Nc-tip), which offered the possibility of producing spin excitations on the tip apex of a scanning tunneling microscope (STM). When the Nc-tip was 100 picometers away from point contact with a surface-supported object, magnetic effects could be probed through changes in the spin excitation spectrum of nickelocene. We used this detection scheme to simultaneously determine the exchange field and the spin polarization of iron atoms and cobalt films on a copper surface with atomic-scale resolution.

scholarly journals Transport Properties of Cu Point Contact between Scanning Tunneling Microscope Tip and Surface

Shinku ◽  
2004 ◽  
Vol 47 (6) ◽  
pp. 467-469 ◽  
Author(s):  
Hiroshi NAKANISHI ◽  
Tomoya KISHI ◽  
Hideaki KASAI ◽  
Fumio KOMORI
Keyword(s):  
Transport Properties ◽  
Scanning Tunneling Microscope ◽  
Point Contact ◽  
Scanning Tunneling ◽  
Tunneling Microscope

Scanning tunneling microscopy of E. coli RNA polymerase deposited onto an Au substrate by an electrochemical process

1991 ◽  
Vol 49 ◽  
pp. 378-379
Author(s):  
Rebecca W. Keller ◽  
Carlos Bustamante ◽  
David Bear
Keyword(s):  
Scanning Tunneling Microscope ◽  
Biological Sample ◽  
Substrate Surface ◽  
Electrochemical Process ◽  
Atomic Resolution ◽  
Scanning Tunneling ◽  
Tunneling Microscopy ◽  
Tunneling Microscope ◽  
E Coli ◽  
Preparation Techniques

Under ideal conditions, the Scanning Tunneling Microscope (STM) can create atomic resolution images of different kinds of samples. The STM can also be operated in a variety of non-vacuum environments. Because of its potentially high resolution and flexibility of operation, it is now being applied to image biological systems. Several groups have communicated the imaging of double and single stranded DNA.However, reproducibility is still the main problem with most STM results on biological samples. One source of irreproducibility is unreliable sample preparation techniques. Traditional deposition methods used in electron microscopy, such as glow discharge and spreading techniques, do not appear to work with STM. It seems that these techniques do not fix the biological sample strongly enough to the substrate surface. There is now evidence that there are strong forces between the STM tip and the sample and, unless the sample is strongly bound to the surface, it can be swept aside by the tip.

STM of freeze-fracture replicas: Problems and promises

1993 ◽  
Vol 51 ◽  
pp. 68-69
Author(s):  
J. T. Woodward ◽  
J. A. N. Zasadzinski
Keyword(s):  
Scanning Tunneling Microscope ◽  
Organic Materials ◽  
Freeze Fracture ◽  
Atomic Resolution ◽  
Scanning Tunneling ◽  
Tunneling Microscope ◽  
Molecular Scale ◽  
Organic Surfaces ◽  
Metal Layers ◽  
Conductive Surfaces

The Scanning Tunneling Microscope (STM) offers exciting new ways of imaging surfaces of biological or organic materials with resolution to the sub-molecular scale. Rigid, conductive surfaces can readily be imaged with the STM with atomic resolution. Unfortunately, organic surfaces are neither sufficiently conductive or rigid enough to be examined directly with the STM. At present, nonconductive surfaces can be examined in two ways: 1) Using the AFM, which measures the deflection of a weak spring as it is dragged across the surface, or 2) coating or replicating non-conductive surfaces with metal layers so as to make them conductive, then imaging with the STM. However, we have found that the conventional freeze-fracture technique, while extremely useful for imaging bulk organic materials with STM, must be modified considerably for optimal use in the STM.

The atomic-force microscope and its future in biology

1993 ◽  
Vol 51 ◽  
pp. 704-705
Author(s):  
Jean-Paul Revel
Keyword(s):  
Silicon Nitride ◽  
Laser Beam ◽  
Atomic Force Microscope ◽  
Scanning Tunneling Microscope ◽  
Point Of View ◽  
Scanning Tunneling ◽  
Close Relative ◽  
Tunneling Microscope ◽  
Atomic Force ◽  
Sharp Point

The last few years have been marked by a series of remarkable developments in microscopy. Perhaps the most amazing of these is the growth of microscopies which use devices where the place of the lens has been taken by probes, which record information about the sample and display it in a spatial from the point of view of the context. From the point of view of the biologist one of the most promising of these microscopies without lenses is the scanned force microscope, aka atomic force microscope.This instrument was invented by Binnig, Quate and Gerber and is a close relative of the scanning tunneling microscope. Today's AFMs consist of a cantilever which bears a sharp point at its end. Often this is a silicon nitride pyramid, but there are many variations, the object of which is to make the tip sharper. A laser beam is directed at the back of the cantilever and is reflected into a split, or quadrant photodiode.

FIELD ION MICROSCOPE AND ATOM-PROBE STUDIES OF SCANNING TUNNELING MICROSCOPE TIPS

1988 ◽  
Vol 49 (C6) ◽  
pp. C6-55-C6-59 ◽  
Author(s):  
O. NISHIKAWA ◽  
K. HATTORI ◽  
F. KATSUKI ◽  
M. TOMITORI
Keyword(s):  
Scanning Tunneling Microscope ◽  
Atom Probe ◽  
Scanning Tunneling ◽  
Tunneling Microscope ◽  
Field Ion Microscope
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