Zettl Research Group

Journal Covers

 

 

 

June 2014

We demonstrate that a back-gated graphene device can be used to switch between two different electronic states of adsorbed organic molecules (the LUMO and the LUMO+1). The image shows the experimentally measured local density of states associated with the LUMO (blue-white) and the LUMO+1 (red-white) of a molecular layer on graphene, obtained using scanning tunneling microscopy. Image courtesy of Alexander Riss.

Imaging and Tuning Molecular Levels at the Surface of a Gated Graphene Device
 

March 2011

We report direct mapping of the grains and grain boundaries (GBs) of large-area monolayer polycrystalline graphene sheets, at large (several micrometer) and single-atom length scales. Global grain and GB mapping is performed using electron diffraction in scanning transmission electron microscopy (STEM) or using dark-field imaging in conventional TEM. Additionally, we employ aberration-corrected TEM to extract direct images of the local atomic arrangements of graphene GBs, which reveal the alternating pentagon-heptagon structure along high-angle GBs. Our findings provide a readily adaptable tool for graphene GB studies.

Grain Boundary Mapping in Polycrystalline Graphene
 

March 2009

With a transmission electron aberration–corrected microscope capable of simultaneous atomic spatial resolution and 1-second temporal resolution, we produced movies of the dynamics of carbon atoms at the edge of a hole in a suspended, single atomic layer of graphene. The rearrangement of bonds and beam-induced ejection of carbon atoms are recorded as the hole grows. We investigated the mechanism of edge reconstruction and demonstrated the stability of the “zigzag” edge configuration. This study of an ideal low-dimensional interface, a hole in graphene, exhibits the complex behavior of atoms at a boundary.

Graphene at the Edge: Stability and Dynamics
 

July 2008

Here we demonstrate a means to observe, by conventional TEM, even the smallest atoms and molecules: on a clean single-layer graphene membrane, adsorbates such as atomic hydrogen and carbon can be seen as if they were suspended in free space. We directly image such individual adatoms, along with carbon chains and vacancies, and investigate their dynamics in real time.


Imaging and dynamics of light atoms and molecules on graphene.

Other information, including TEM images of individual atoms, and movies of molecule dynamics, can be found here.

 

July 2008

Here we demonstrate a roomtemperature, carbon-nanotube-based nanomechanical resonator with atomic mass resolution. ... Using this extreme mass sensitivity, we observe atomic mass shot noise, which is analogous to the electronic shot noise measured in many semiconductor experiments. Unlike traditional mass spectrometers, nanomechanical mass spectrometers do not require the potentially destructive ionization of the test sample, are more sensitive to large molecules, and could eventually be incorporated on a chip.

An atomic-resolution nanomechanical mass sensor

 

November 2008

We present a transmission electron microscopy investigation of graphene membranes, crystalline foils with a thickness of only 1 atom. By using aberration-correction in combination with a monochromator, 1-Å resolution is achieved at an acceleration voltage of only 80 kV. ... We observe a highly crystalline lattice along with occasional point defects. The formation and annealing of Stone-Wales defects is observed in situ. Multiple five- and seven-membered rings appear exclusively in combinations that avoid dislocations and disclinations, in contrast to previous observations on highly curved (tube- or fullerene-like) graphene surfaces.

Direct Imaging of Lattice Atoms and Topological Defects in Graphene Membranes
 

July 2007

Gold nanoparticles have been self-assembled at the surface of both amine- and thiol-functionalized boron nitride nanotubes (BNNTs) in solution. ... This approach constitutes a basis for the preparation of highly functionalized BNNTs and their utilization as nanoscale templates for assembly and integration with other nanoscale materials.


Self-Assembly of Gold Nanoparticles at the Surface of Amine- and Thiol-Functionalized Boron Nitride Nanotubes

 

February 2004

Chemistry text cover used the Zettl Lab image of the spiral view of a nanotube. This image was also seen earlier on the cover of a Chemical and Engineering News issue in 1998 (see below).

 

October 2004

Zettl Lab image was used on the cover of an IEEE special issue on Applications of Superconductivity.

 

February 2002

Electron holography performed in situ inside a high resolution transmission electron microscope has been used to determine the magnitude and spatial distribution of the electric field surrounding individual field-emitting carbon nanotubes. The electric field (and hence the associated field emission current) is concentrated precisely at the tips of the nanotubes and not at other nanotube defects such as sidewall imperfections. The electric field magnitude and distribution are stable in time, even in cases where the nanotube field emission current exhibits extensive temporal fluctuations.

Electron Holography of Field-Emitting Carbon Nanotubes

 

February 2001

EYE ON THE FUTURE: NANOTECHNOLOGY

hybrid NEMS

By Paul Sharke, Associate Editor Molecular Motors

Inching—er, nanometering—toward mechanical devices of an atomic scale, two researchers spell out practical considerations for MEs who will one day design them.

Molecular Motors and Na-no Bearings and Engines: That's the way the agenda listed two speeches at ASME's recent nanotechnology workshop in Washington. For engineers in the audience inclined toward the pragmatic, surely these two talks, by Carlo Montemagno and Alex Zettl, would warrant attention. They did.

Feature Article in ME (2001)

 

June 2000

A Zettl Lab image was used on the cover of Physics World in a volume featuring a review of carbon nanotube research.

 

 

June 1998

The Zettl Research Group's image of a nanotube spiral featured on the cover of a Chemical & Engineering News volume highlighting materials to meet tomorrow's challenges. Note: the same image was featured on the cover of a Chemistry text in 2004 (see above).

 

November 1987

A Zettl Lab image featured by the University of California at Berkeley's Alumni News magazine.


 



 

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