Fiber laboratory at the Institute of Applied Physics, 2018.


Fiber laboratory at the Institute of Applied Physics, 2018.
Image: Jan-Peter Kasper (University of Jena)
2021 Show content
  1. L.Ouyang, T. Meier, K.-M. See, W.-L. Chen, F.-C. Lin. D. Akimov, S. Ehtesabi, M. Richter, M. Schmitt, Y.-M. Chang, S. Gräfe, J. Popp, and J.-S. Huang, "Spatially resolving the enhancement effect in surface-enhanced coherent Anti-Stokes Raman scattering by plasmonics Doppler gratings," ACS Nano, (2021)
  2. E. Najafidehaghani, Z. Gan, A. George, T. Lehnert, G. Q. Ngo, C. Neumann, T. Bucher, I. Staude, D. Kaiser, T. Vogl, U. Hübner, U. Kaiser, F. Eilenberger, A. TurchaninOne-dimensional p-n junction electronic and optoelectronic devices from transition metal dichalcogenide lateral heterostructures grown by one-pot chemical vapor deposition synthesis. Adv. Func. Mater. 31 (2021) 2101086
  3. F.J.F. Löchner, A. George, K. Koshelev, T. Bucher, E. Najafidehaghani, A. Fedotova, D. Yong Choi, T. Pertsch, I. Staude, Y. Kivshar, A. Turchanin, F. Setzpfandt Hybrid dielectric metasurfaces for enhancing second-harmonic generation in chemical vapor deposition grown MoS2 monolayers. ACS Photonics 8 (2021) 218-227
  4. A. George, M. V. Fistul, M. Gruenewald, D. Kaiser, T. Lehnert, R. Mupparapu, C. Neumann, U. Hübner, M. Schaal, N. Masurkar, A. L. M. Reddy, I. Staude, U. Kaiser, T. Fritz, A. TurchaninGiant persistent photoconductivity in monolayer MoS2 field-effect transistorsnpj 2D Mater. Appl. 5 (2021) 15
  5. R. Hollinger, P. Herrmann, V. Korolev, M. Zapf, V. Shumakova, R. Röder, I. Uschmann, A. Pugzlys, A. Baltuska, M. Zürch, C. Ronning, C. Spielmann, D. Kartashov Polarization dependent excitation and high harmonic generation from intense mid-IR laser pulses in ZnO (2021). 
  6. K. Kuruma, B. Pingault, C. Chia, D. Renaud, P. Hoffmann, S. Iwamoto, C. Ronning,  M. Lončar Coupling of a Single Tin-vacancy Center to a Photonic Crystal Cavity in Diamond (2021).
  7. P. Paul, Md. G. Hafiz, P. Schmitt, C. Patzig, F. Otto, T. Fritz, A. Tünnermann, A. Szeghalmi Optical bandgap control in Al2O3/TiO2 heterostructures by plasma enhanced atomic layer deposition: Toward quantizing structures and tailored binary oxides (2021).
  8. R. D. Rodriguez, C. J. Villagómez, A. Khodadadi, S. Kupfer, A. Averkiev, L. Dedelaite, F. Tang, M. Y. Khaywah, V. Kolchuzhin, A. Ramanavicius, P. Adam, S. Gräfe, E. Sheremet Chemical Enhancement vs Molecule−Substrate Geometry in Plasmon-Enhanced Spectroscopy (2021).
2020 Show content
  1. Q. Ngo, A. George, R. T. K. Schock, A. Tuniz, E. Najafidehaghani, Z. Gan, N. Geib, T. Bucher, H. Knopf, S. Saravi, C. Neumann, T. Lühder, E.P. Schartner, S.C. Warren‐Smith, H. Ebendorff‐Heidepriem, T. Pertsch, M.A. Schmidt, A. Turchanin, and F. Eilenberger, "Scalable Functionalization of Optical Fibers Using Atomically Thin Semiconductors," Adv. Mater. DOI: 10.1002/adma.202003826 (2020).

  2. A. Özogul, F. Trillitzsch, C. Neumann, A. George, A. Turchanin, and E. Gnecco, "Plowing-induced nanoexfoliation of mono- and multilayer MoS2 surfaces," Phys. Rev. Mater. 4, 033603 (2020).

  3. R. Mupparapu, M. Steinert, A. George, Z. Tang, A. Turchanin, T. Pertsch, and I. Staude, "Facile resist free nanopatterning of monolayers of MoS2 by focused ion beam milling," Advanced Materials Interfaces 7, 2000858 (2020).

  4. Paradeisanos, S. Shree, A. George, N. Leisgang, C. Robert, K. Watanabe, T. Taniguchi, R. J. Warburton, A. Turchanin, X. Marie, I. Gerber, and B. Urbaszek, "Controlling interlayer excitons in MoS2 layers grown by chemical vapor deposition," Nature Commun. 11, 2391 (2020).

  5. D. Sırmacı, Z. Tang, S. Fasold, C. Neumann, T. Pertsch, A. Turchanin, and I. Staude, "Plasmonic metasurfaces situated on ultrathin carbon nanomembranes," ACS Photonics 7, 1060 (2020).

  6. S. Creutzburg, J. Schwestka, A. Niggas, H. Inani, M. Tripathi, A. George, R. Heller, R. Kozubek, L. Madauss, N. McEvoy, S. Facsko, J. Kotakoski, M. Schleberger, A. Turchanin, P.L. Grande, F. Aumayr, and R.A. Wilhelm, "Vanishing influence of the band gap on the charge exchange of slow highly charged ions in freestanding single-layer MoS2," Phys. Rev. B 102, 045408 (2020).

  7. D. Okada, Z.H. Lin, J.S. Huang, O. Oki, M. Morimoto, X.Y. Liu, T. Minari, S. Ishii, T. Nagao, M. Irie, and Y. Yamamoto, "Optical microresonator arrays of fluorescence-switchable diarylethtens with unreplicable spectral fingerprints," Mater. Horizons 7, 1801 (2020).

  8. K. Fiederling, M. Abasifard, M. Richter, V. Deckert, S. Gräfe, and S. Kupfer, "The chemical effect goes resonant – a full quantum mechanical approach on TERS," Nanoscale 12, 6346 (2020).

  9. F. Trillitzsch, A. Janas, A. Özogul, C. Neumann, A. George, B. R. Jany, F. Krok, A. Turchanin, and E. Gnecco, "Scanning-Probe-Induced Assembling of Gold
    Striations on Mono- and Bi-Layered MoS2 on SiO2," MRS Advances, DOI: 10.1557/adv.2020.151 (2020).

  10. M. Richard-Lacroix and V. Deckert, "Direct molecular-level near-field plasmon and temperature assessment in a single plasmonic hotspot," Light: Sci. & Appl. 9, 35 (2020).

  11. J.W. Zhang, S.Y. Huang, Z.H. Lin, and J.S. Huang, "Generation of optical chirality patterns with plane waves, evanescent waves and surface plasmon waves," Opt. Express 28, 376062 (2020).

  12. S. Shree, A. George, T. Lehnert , C. Neumann, M. Benelajla, C. Robert,
    X. Marie, K. Watanabe, T. Taniguchi, U. Kaiser, B. Urbaszek, and A. Turchanin, "High optical quality of MoS2 monolayers grown by chemical vapor deposition," 2D Mater. 7, 015011 (2020). 
  13. M. Zapf, M. Ritzer, L. Liborius, A. Johannes, M. Hafermann, S. Schönherr, J. Segura-Ruiz, G. Martinez-Criado, W. Prost, C. Ronning Hot electrons in a nanowire hard X-ray detector (2020).
2019 Show content
  1. F. Löchner, R. Mupparapu, M. Steiner, A. George, Z. Tang, A. Turchanin, T. Pertsch, I. Staude, and F. Setzpfandt, "Controlling second-harmonic diffraction by
    nano-patterning MoS2 monolayers," Opt. Express 27, 35475 (2019).
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