Johannes Jobst
Gast onderzoeker
- Naam
- Dr. J. Jobst
- Telefoon
- +31 71 527 5483
- jobst@physics.leidenuniv.nl
- ORCID iD
- 0000-0002-2422-1209
Meer informatie over Johannes Jobst
Nieuws
-
Nieuw spin-off bedrijf om cruciale hindernis in de quantumrevolutie te overwinnen -
Verdraaide supergeleider eindelijk begrepen -
Gestapeld grafeen spiegelt elektronenbundels -
Atomen gebruiken tunnels om te ontsnappen onder grafeen -
Our Talents and Discoveries 2016 -
Interacties blootgelegd in designermaterialen -
Leidse natuurkundigen ontmoeten Nobelprijswinnaars -
Leidse Natuurkunde organiseert NEVAC-dag 2016 -
Natuurkundigen ontwikkelen techniek om ‘slimme’ materialen te doorgronden -
Johannes Jobst, Jaap Kautz en Sense Jan van der Molen in Mare over geleiding in superdun materiaal -
Nieuwe techniek om geleiding te meten in gestapelde nanomaterialen -
14 Veni's voor Leidse wetenschappers
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Spanning op de nanoschaal: NeVac prijs voor Leidse onderzoekers
In de media
Gast onderzoeker
- Wiskunde en Natuurwetenschappen
- Leiden Instituut Onderzoek Natuurkunde
- LION - Quantum Matter & Optics
- Jobst J. & Molen S.J. van der (2018), A new perspective on new materials, Europhysics News 49(4): 23-26.
- Jobst J., Krasovskii E.E., Ribeiro R., Jong T.A. de, Dean C.R., Tromp R.M. & Molen S.J. van der (2025), Unoccupied bands in the molybdenum dichalcogenides MoS2, MoSe2, and MoTe2, Physical Review B 112: 125422.
- Jong T.A. de, Visser L., Jobst J., Tromp R.M. & Molen S.J. van der (2023), Stacking domain morphology in epitaxial graphene on silicon carbide, Physical Review Materials 7(3): 034001.
- Tebyani A., Schramm S.M., Hesselberth M.B.S., Boltje D.B., Jobst J., Tromp R.M. & Molen S.J. van der (2023), Low energy electron microscopy at cryogenic temperatures, Ultramicroscopy 253: 113815.
- Jong T.A. de, Chen X., Jobst J., Krasovskii E.E., Tromp R.M. & Molen S.J. van der (2023), Low-Energy Electron Microscopy contrast of stacking boundaries: comparing twisted few-layer graphene and strained epitaxial graphene on silicon carbide. arXiv. [working paper].
- Jong T.A. de, Visser L., Jobst J., Tromp R.M. & Molen S.J. van der (2022), Stacking domain morphology in epitaxial graphene on silicon carbide. arXiv. [working paper].
- Lisi S., Lu X., Benschop T., Jong T.A. de, Stepanov P., Duren J.R., Margot F., Cucchi I., Cappelli E., Hunter A., Tamai A., Kandyba V., Giampietri A., Barinov A., Jobst J., Stalman V., Leeuwenhoek M., Watanabe K., Taniguchi T., Rademaker L., Molen S.J. van der, Allan M.P., Efetov D.K. & Baumberger F. (2021), Observation of flat bands in twisted bilayer graphene , Nature Physics 17: 189-193.
- Jong T.A. de, Kok D.N.L., Benschop T., Jobst J. & Molen S.J. van der (2021), Using the scientific Python stack to analyze Low Energy Electron Microscopy data. SciPy2021, N/A. 12 juli 2021 - 18 juli 2021. [conferentie poster].
- Jong T.A. de, Kok D.N.L., Torren A.J.H. van der, Schopmans H., Tromp R.M., Molen S.J. van der & Jobst J. (2020), Quantitative analysis of spectroscopic Low Energy Electron Microscopy data: High-dynamic range imaging, drift correction and cluster analysis, Ultramicroscopy 213: 112913.
- Bespalov I., Zhang Y., Haitjema J., Tromp R.M., Molen S.J. van der, Brouwer A.M., Jobst J. & Castellanos S. (2020), The key role of very-low-energy-electrons in tin-based molecular resists for extreme ultraviolet nanolithography, ACS Applied Materials and Interfaces 12(8): 9881-9889.
- Jobst J., Boers L.M., Yin C., Aarts J., Tromp R.M. & Molen S.J. van der (2019), Quantifying work function differences using low-energy electron microscopy: The case of mixed-terminated strontium titanate, Ultramicroscopy 200: 43-49.
- Geelen D., Jobst J., Krasovskii E.E., Molen S.J. van der & Tromp R.M. (2019), Nonuniversal transverse electron mean free path through few-layer graphene, Physical Review Letters 123(8): 086802.
- Torren A.J.H. van der, Yuan H., Liao Z., Elshof J.E. ten, Koster G., Huijben M., Rijnders G.J.H.M., Hesselberth M.B.S., Jobst J., Molen S.J. van der & Aarts J. (2019), Growing a LaAlO3/SrTiO3 heterostructure on Ca2Nb3O10 nanosheets, Scientific Reports 9: 17617.
- Jong T.A. de, Jobst J., Krasovskii E.E., Molen S.J. van der, Ott C., Scholma D. & Tromp R.M. (2018), Data underlying the paper: Intrinsic Stacking domains in graphene on silicon carbide: a pathway for intercalation (data file and codebook): 4TU.Centre for Research Data. [dataset].
- Jong T.A. de, Jobst J., Yoo H., Krasovskii E.E., Kim P. & Molen S.J. van der (2018), Measuring the local twist angle and layer arrangement in Van der Waals Heterostructures, Physica Status Solidi. B: Basic Research 255(12): 1800191.
- Jong T.A. de, Krasovskii E.E., Ott C., Tromp R.M., Molen S.J. van der & Jobst J. (2018), Intrinsic stacking domains in graphene on silicon carbide: A pathway for intercalation, Physical Review Materials 2(10): 104005.
- Jobst J., Kautz J., Mytiliniou M., Tromp R.M. & Molen S.J. van der (2017), Low-energy electron potentiometry, Ultramicroscopy 181: 74-80.
- Kisslinger F., Popp M., Jobst J. & Weber H.B. (2017), Charge-carrier transport and classical correction in large-area epitaxial graphene, Annalen der Physik 529(11): 1700048.
- Jobst J., Torren A.J.H. van der, Krasovskii E.E., Balgley J., Dean C.R., Tromp R.M. & Molen S.J. van der (2016), Quantifying electronic band interactions in van der Waals materials using angle-resolved reflected-electron spectroscopy, Nature Communications 7: 13621.
- Kautz J., Jobst J. & Molen S.J. van der (2015), Quantum LEEP (Lage-energie-elektronenpotentiometrie): Spanning op de Nanoschaal!, Nevac blad 53 (2)(7): .
- Jobst J., Kautz J., Geelen D., Tromp R.M. & Molen S.J. van der (2015), Nanoscale measurements of unoccupied band dispersion in few-layer graphene, Nature Communications 6: 8926.
- Kautz J., Jobst J., Sorger C., Tromp R.M., Weber H.B. & Molen S.J. van der (2015), Low-Energy Electron Potentiometry: Contactless Imaging of Charge Transport on the Nanoscale, Scientific Reports 5: 13604.
- Sorger C., Hertel S., Jobst J., Steiner C., Meil K., Ullmann K., Albert A., Wang Y., Krieger M., Ristein J., Maier S. & Weber H.B. (2015), Gateless patterning of epitaxial graphene by local intercalation, Nanotechnology 26(025302): .