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Ag Giessibl1 Phd Position Lt1

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Publikation Nr. 98

Analysis of Airborne Contamination on Transition Metal Dichalcogenides with Atomic Force Microscopy Revealing That Sulfur Is the Preferred Chalcogen Atom for Devices Made in Ambient Conditions

K. Pürckhauer, D. Kirpal, A. J. Weymouth and Franz J. Giessibl

ACS Appl. Nano Mater (2019)

Publikation Nr. 97

In-situ characterization of O-terminated Cu tips for high-resolution atomic force microscopy

A. Liebig, Franz J. Giessibl

Appl. Phys. Lett. 114, 143103 (2019)

Publikation Nr. 96

The qPlus sensor, a powerful core for the atomic force microscope

Franz J. Giessibl

Review of Scientific Instruments 90, 011101 (2019)

Publikation Nr. 95

Interatomic force laws that evade dynamic measurement

John E. Sader, Barry D. Hughes, Ferdinand Huber, Franz J. Giessibl

Nat. Nanotech. 13, 1088 (2018)

Publikation Nr. 94

Lateral manipulation of single iron adatoms by means of combined atomic force and scanning tunneling microscopy using CO-terminated tips

Julian Berwanger, Ferdinand Huber, Fabian Stilp, and Franz J. Giessibl

Phys. Rev. B 98, 195409 (2018)

Julian Berwanger gewinnt Poster-Preis auf NC-AFM 2018 in Porvoo (Finnland)

2018 Nc-afm Posteraward Klein

Publikation Nr. 93

Advances in AFM: Seeing Atoms in Ambient Conditions

Alfred J. Weymouth, Daniel Wastl, Franz J. Giessibl

e-JSSNT, 16, 351 (2018)

Heinrich Rohrer Medaille für Dr. Jay Weymouth

Medal Jay Gross

Heinrich Rohrer Medaille


Hanauerhuette Vor Huette Gro _

Publikation Nr. 88

Low noise current preamplifier for qPlus sensor deflection signal detection in atomic force microscopy at room and low temperatures

Ferdinand Huber and Franz J. Giessibl

Rev. Sci. Instrum., 88, 073702 (2017)

Publikation Nr. 87

Non-contact lateral force microscopy

Alfred J. Weymouth

J. Phys.: Condens. Matter, 29, 323001 (2017)

Giessibl-group Alumni Treffen

Habilitationsvortrag von Jay Weymouth

Titel: "Investigating electrostatics and short-range interactions with atomic force microscopy"

Feynman-Preis für Prof. Dr. Franz J. Gießibl

Pressemitteilung UR


Korbinian Pürckhauer erhält 2. Poster-Preis beim 2. German-French Summer School on NC-AFM in Osnabrück                           

Poster Korbi Klein

Daniel Meuer gewinnt 3. Poster-Preis auf NC-AFM 2016 in Nottingham                      

Poster Dani Klein

30 Jahre Nobelpreis für Binnig & Rohrer, Focus Collection


Interview mit IOP über 30 Jahre AFM


We congratulate Gerd Binnig, Christoph Gerber and Calvin Quate on winning the 2016 Kavli Prize for Nanoscience


Publikation Nr. 84

Influence of atomic tip structure on the intensity of inelastic tunneling spectroscopy data analyzed by combined scanning tunneling spectroscopy, force microscopy, and density functional theory

Norio Okabayashi, Alexander Gustafsson, Angelo Peronio, Magnus Paulsson, Toyoko Arai, and Franz J. Giessibl

Fig01 151106 Klein

Phys. Rev. B, 93, 165415 (2016)

Prof. Dr. Franz J. Gießibl erhält Rudolf-Jaeckel-Preis von der Deutschen Vakuumgesellschaft

Preisverleihung 17.jpeg

Publikation Nr. 83

Intramolecular Force Contrast and Dynamic Current-Distance Measurements at Room Temperature

F. Huber, S. Matencio, A. J. Weymouth, C. Ocal, E. Barrena, and F. J. Giessibl


Phys. Rev. Lett, 115, 066101 (2015)

Verteidigung von Matthias Emmrich

Titel: "Subatomare Auflösung auf Adatomen und kraftfeldabhängige laterale Manipulation mit einem eigenentwickelten Tieftemperatur-Rasterkraftmikroskop"

Dsc 1389 Klein

Gerhard Ertl Award

Foto Jay Klein

Dr. Jay Weymoth ist mit dem Gerhard Ertl Young Investigator Award 2015 geehrt worden. Der Preis wird seit 2010 vom Fachverband Oberflächenphysik der Deutschen Physikalischen Gesellschaft (DPG) an herausragende Nachwuchsforscherinnen und -forscher verliehen. Er ist nach Prof. Dr. Gerhard Ertl (Fritz-Haber-Institut Berlin) benannt, dem Chemie-Nobelpreisträger von 2007.

Publikation Nr. 79

Subatomic resolution force microscopy reveals internal structure and adsorption sites of small iron clusters

Matthias Emmrich, Ferdinand Huber, Florian Pielmeier, Joachim Welker, Thomas Hofmann, Maximilian Schneiderbauer, Daniel Meuer, Svitlana Polesya, Sergiy Mankovsky, Diemo Ködderitzsch, Hubert Ebert, Franz J. Giessibl

Fe Cluster Klein

Science, DOI: 10.1126/science.aaa5329 (2015)

Publikation Nr. 77

Influence of matrix and filler fraction on biofilm formation
on the surface of experimental resin-based composites

Andrei Ionescu, Eugenio Brambilla, Daniel S. Wastl, Franz J. Giessibl, Gloria Cazzaniga, Sibylle Schneider-Feyrer, Sebastian Hahnel

Zahnproben2014hydrophobes Klein

J Mater Sci: Mater Med, DOI 10.1007/s10856-014-5372-4 (2015)

Verteidigung von Maximilian Schneiderbauer

Titel: "Aufbau eines Tieftemperatur-Ultrahochvakuum-Rasterkraftmikroskops und Messung elektrischer Multipolkräfte im Piconewton-Bereich"

Verteidigung Max 1

Verteidigung von Florian Pielmeier

Titel: "Atomic Force Microscopy in the Picometer Regime - Resolving Spins and Non-Trivial Surface Terminations"

Verteidigung Flo

Interview mit Reviews of Scientific Instruments

Franz J. Giessibl


Publikation Nr. 76

Atomically Resolved Graphitic Surfaces in Air by Atomic Force Microscopy

Daniel S. Wastl, Alfred J. Weymouth and Franz J. Giessibl

Wastl Paper

ACS Nano, DOI: 10.1021/nn501696q (2014)

Prof. Dr. Franz J. Gießibl erhält bedeutende Auszeichnung der Amerikanischen Physikalischen Gesellschaft:

Keithley Award Franz

Joseph F. Keithley Award for Advances in Measurement Science 2014

Publikation Nr. 75

CO Tip Functionalization Inverts Atomic Force Microscopy Contrast via Short-Range Electrostatic Forces

Maximilian Schneiderbauer, Matthias Emmrich, Alfred J. Weymouth, and Franz J. Giessibl

Max Pa

What does a balloon sticking to a wall have in common with an atomic-scale insulator?

When we consider the interaction between atoms, we often think about the forming and breaking of chemical bonds that is best described with quantum mechanics. But electrostatic forces, like the ones responsible for sticking a balloon on a wall after you rub on your head, also play a role at the atomic scale. Salt, made up of sodium and chloride, is a great example of the importance of these forces. The sodium and chloride atoms have different charges that keep the salt crystal together. Nanotechnology is making use of these ionic materials at the atomic scale as an insulating layer – like the plastic coating of a wire. We used an atomic force microscope to investigate one of these materials – Copper with Nitrogen in it – at the atomic scale to see what role electrostatics plays. By picking up or putting down a molecule on the tip, we can change the charge at the end of the tip. We then simulated these two cases – with and without a molecule – using just the electrostatic interaction. The great agreement between our model and our data tell us how important these interactions are even at the scale of two atoms.

Phys. Rev. Lett. 112, 166102 (2014)

Verteidigung von Thomas Hofmann

Titel: "Hochauflösende Rasterkraftmikroskopie auf Graphen und Kohlenmonoxid"

Verteidigung Tom

Publikation Nr. 72

Impact of thermal frequency drift on highest precision force microscopy using quartz-based force sensors at low temperatures

Florian Pielmeier, Daniel Meuer, Daniel Schmid, Christoph Strunk and Franz J. Giessibl

Pielmeier Graphical Abstract

Beilstein J. Nanotechnol., 5, 407–412 (2014)

Publikation Nr. 71

Chemical and Crystallographic Characterization of the Tip Apex in Scanning Probe Microscopy

Thomas Hofmann, Florian Pielmeier and Franz J. Giessibl

Illustration Kupferspitze Co2

Phys. Rev. Lett. 112, 066101 (2014)

Interview about the field of nanotechnology

Franz J. Giessibl, Christoph Gerber, James K. Gimzewski

iopscience (2014)

nanotechweb (2014)

Publikation Nr. 70

Quantifying molecular stiffness and interaction with lateral force microscopy

Alfred J. Weymouth, Thomas Hofmann, Franz J. Giessibl


One of the most impressive atomic force microscopy (AFM) images was taken by Leo Gross and coworkers at IBM of a molecule showing every carbon-carbon bond within it [Gross et al, Science 325, 1110]. A key step was to functionalize the tip with a CO molecule, making the apex of the AFM tip small and chemically inert [Bartels et al, Appl. Phys. Lett., 71, 213]. However, this comes with a complication: The CO isn’t stiff but rather pivots when a horizontal force is applied. Moreover, standard experimental and theoretical approaches have not been able to characterize this torsional spring. We modified our AFM to be sensitive to lateral forces (LFM). As we measure forces along the surface, we are highly sensitive to short-range interactions. We combined both LFM and AFM data of a CO terminated tip probing a CO surface molecule, to determine the parameters of a simple model: two torsional springs interacting via a Morse potential.

Science, 343, 1120-1122 (2014)

Interview über Reibungseffekte

31podcast 153 38433411c9 Cat3 7b8013f90e

Franz J. Giessibl

weltderphysik, Folge 153, (2014)


AG Prof. Gießibl

Sekretariat Petra Wild

Tel: +49 (0)941943-2106

Fax: +49 (0)941943-2754

Raum: PHY 1.1.23

Email: petra1.wild@ur.de