Menlo Systems GmbH


Industrie / privates Unternehmen

Standort der Organisation:
Planegg, Deutschland


Publikationen in Kooperation mit FAU-Wissenschaftlerinnen und Wissenschaftlern


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Hänsel, W., Hoogland, H., Giunta, M., Schmid, S., Steinmetz, T., Doubek, R.,... Holzwarth, R. (2017). All polarization-maintaining fiber laser architecture for robust femtosecond pulse generation. Applied Physics B-Lasers and Optics, 123(1). https://dx.doi.org/10.1007/s00340-016-6598-2
Kanai, T., Malevich, P., Kangaparambil, S.S., Ishida, K., Mizui, M., Yamanouchi, K.,... Baltuska, A. (2017). Parametric amplification of 100 fs mid-infrared pulses in ZnGeP2 driven by a Ho:YAG chirped-pulse amplifier. Optics Letters, 42(4), 683-686. https://dx.doi.org/10.1364/OL.42.000683
Kerse, C., Kalaycıoğlu, H., Elahi, P., Çetin, B., Kesim, D.K., Akçaalan, Ö.,... Ilday, F. (2016). Ablation-cooled material removal with ultrafast bursts of pulses. Nature, 537(7618), 84-88. https://dx.doi.org/10.1038/nature18619
Sanchez, D., Hemmer, M., Baudisch, M., Cousin, S.L., Zawilski, K., Schunemann, P.,... Biegert, J. (2016). Broadband 7 mu m OPCPA pumped by a 2 mu m picosecond Ho: YLF CPA system. In SPIE Proceedings 9730. 97300X San Francisco: IEEE COMPUTER SOC.
Malevich, P., Kanai, T., Hoogland, H., Holzwarth, R., Baltuska, A., & Pugzlys, A. (2016). Broadband mid-infrared pulses from potassium titanyl arsenate/zinc germanium phosphate optical parametric amplifier pumped by Tm, Ho-fiber-seeded Ho:YAG chirped-pulse amplifier. Optics Letters, 41(5), 930-933. https://dx.doi.org/10.1364/OL.41.000930
Hoogland, H., McNeur, J., Kozak, M., Hommelhoff, P., & Holzwarth, R. (2016). Compact Ultrashort Pulsed 2.05 mu m All-PM Fiber Laser For Dielectric Laser Acceleration of Non-relativistic Electrons. In OSA Technical Digest (pp. paper SF1I.7).
McNeur, J., Kozak, M., Schönenberger, N., Leedle, K., Deng, H., Ceballos, A.,... Hommelhoff, P. (2016). Elements of a dielectric laser accelerator. arXiv, 4(4).
Kozak, M., McNeur, J., Leedle, K., Deng, H., Schönenberger, N., Ruehl, A.,... Hommelhoff, P. (2016). Transverse and longitudinal characterization of electron beams using interaction with optical near-fields. Optics Letters, 41(15), 3435-3438. https://dx.doi.org/10.1364/OL.41.003435
Hoogland, H., & Holzwarth, R. (2015). Compact polarization-maintaining 2.05-mu m fiber laser at 1-MHz and 1-MW peak power. Optics Letters, 40(15), 3520-3523. https://dx.doi.org/10.1364/OL.40.003520
Sanchez, D., Sanchez, D., Hemmer, M., Baudisch, M., Baudisch, M., Zawilski, K.,... Biegert, J. (2014). Broadband mid-IR frequency comb with CdSiP2 and AgGaS2 from an Er,Tm:Ho fiber laser. Optics Letters, 39(24), 6883-6886. https://dx.doi.org/10.1364/OL.39.006883
Vernaleken, A., Schmidt, B., Haensch, T.W., Holzwarth, R., & Hommelhoff, P. (2014). Carrier-envelope frequency stabilization of a Ti:sapphire oscillator using different pump lasers: part II. Applied Physics B-Lasers and Optics, 117(1), 33. https://dx.doi.org/10.1007/s00340-014-5795-0
Hoogland, H., Wittek, S., Hänsel, W., Stark, S., & Holzwarth, R. (2014). Fiber chirped pulse amplifier at 2.08 μm emitting 383-fs pulses at 10 nJ and 7 MHz. Optics letters, 39(23), 6735-6738. https://dx.doi.org/10.1364/OL.39.006735
Hoogland, H., Thai, A., Sanchez, D., Sanchez, D., Cousin, S.L., Hemmer, M.,... Holzwarth, R. (2013). All-PM coherent 2.05 µm Thulium/Holmium fiber frequency comb source at 100 MHz with up to 0.5 W average power and pulse duration down to 135 fs. Optics Express, 21(25), 31390-31394. https://dx.doi.org/10.1364/OE.21.031390
Vernaleken, A., Schmidt, B., Wolferstetter, M., Haensch, T.W., Holzwarth, R., & Hommelhoff, P. (2012). Carrier-envelope frequency stabilization of a Ti:sapphire oscillator using different pump lasers. Optics Express, 20, 18387. https://dx.doi.org/10.1364/OE.20.018387
Hommelhoff, P., Hänsel, W., Steinmetz, T., Hänsch, T., & Reichel, J. (2005). Transporting, splitting and merging of atomic ensembles in a chip trap. New Journal of Physics, 7, 3. https://dx.doi.org/10.1088/1367-2630/7/1/003
Treutlein, P., Hommelhoff, P., Steinmetz, T., Hänsch, T., & Reichel, J. (2004). Coherence in microchip traps. Physical Review Letters, 92, 203005. https://dx.doi.org/10.1103/PhysRevLett.92.203005
Long, R., Steinmetz, T., Hommelhoff, P., Hänsel, W., Hänsch, T., & Reichel, J. (2003). Magnetic microchip traps and single-atom detection. Philosophical Transactions of the Royal Society A-Mathematical Physical and Engineering Sciences, 361, 1375-1389. https://dx.doi.org/10.1098/rsta.2003.1207
Treutlein, P., Hommelhoff, P., Long, R., Rom, T., Steinmetz, T., & Hänsch, T. (2002). Speedy BEC in a tiny trap: coherent matter waves on a microchip. In Proceedings of the XV International Conference on Laser Spectroscopy (pp. 289). Singapore: World Scientific.
Reichel, J., Hänsel, W., Hommelhoff, P., & Hänsch, T. (2001). Applications of integrated magnetic microtraps. Applied Physics B-Lasers and Optics, 72, 81-89.
Hänsel, W., Hommelhoff, P., Hänsch, T., & Reichel, J. (2001). Bose–Einstein condensation on a microelectronic chip. Nature, 413, 498-501. https://dx.doi.org/10.1038/35097032

Zuletzt aktualisiert 2017-10-05 um 07:01