Hendrich.org

Veröffentlichungen und Patente

Symbolbild, Quelle: PixabayTeilchenstrahlgerät und Verfahren zum Betrieb eines Teilchenstrahlgeräts, 2015
K. Hegele, E. Fichter, M. Aliman, D. Preikszas, C. Hendrich, M. Mommsen, M. Schnell, K. Schubert
Patent DE 102015210941 A1

High-voltage supply unit and circuit arrangement for generating a high voltage for a particle beam apparatus, 2015
E. Fichter, J. Fober, D. Preikszas, C. Hendrich, M. Schnell, M. Mommsen
Patente US20160314931, DE102015207484A1

Particle beam device comprising an electrode unit, 2014
J. Fober, E. Fichter, K. Schubert, D. Preikszas, C. Hendrich, M. Mommsen, M. Schnell, L. Lechner
Patent US9312093B1

Determination of fundamental morphological parameters of supported nanoparticle ensembles: Extracting the functional dependence between nanoparticle shape and size
F. Hubenthal, C. Hendrich, T.A. Vartanyan, F. Träger
Plasmonics, Volume 8, Issue 2, pp 435-448 (2013), Abstract

Printed circuit board multipole for ion focusing, 2011
A. Laue, A. Glasmachers, C. Hendrich, D. Preikszas, M. Aliman, H. Mantz, U. Zeile, H. Dömer
Patente DE102010001349A1, DE102010001349B4, DE102010001349B9, EP2355127A1, US20110220788

Apparatus for focusing and for storage of ions and for separation of pressure areas, 2010
A. Laue, A. Glasmachers, C. Hendrich, D. Preikszas, M. Aliman, H. Mantz, U. Zeile, H. Dömer
Patente US20110220788A1, US20160020064

Damping of the localized surface plasmon polariton resonance of gold nanoparticles
F. Hubenthal, C. Hendrich und F. Träger
Appl. Phys. B 100, 225-230 (2010), Abstract

Verfahren zum Erzeugen von Korpuskularstrahlbildern mit einem Korpuskularstrahlgerät, 2008
C. Hendrich
Patente DE102008038216A1, US020100038534A1

Teilchenoptische Vorrichtung mit Magnetanordnung, 2008
D. Preikszas, M. Steigerwald, T. Daniel, A. Eisele, M. Mommsen, D. Dönitz, C. Hendrich
Patente DE102008064696A1, DE102008062888B4, DE102008062888A1, JP002010153382A, NL000002003998A, US020100155597A1, US8063364

Measurement of the size of embedded metal clusters by mass spectrometry, transmission electron microscopy and small angle X-ray scattering
C. Hendrich, L. Favre, D.N. Ievlev, A.N. Dobrynin, W. Bras, U. Hörmann, E. Piscopiello, G. Van Tendeloo, P. Lievens and K. Temst
Appl. Phys. A 86, 533-538 (2007), Abstract

Influence of finite size effects on exchange anisotropy in oxidized Co nanocluster assembled films
A. N. Dobrynin, D. N. Ievlev, C. Hendrich, K. Temst, P. Lievens, U. Hörmann, J. Verbeeck, and G. Van Tendeloo, A. Vantomme
Phys. Rev. B 73, 245416 (2006), Abstract

Modeling the optical spectra of supported nanoparticle ensembles: Extraction of the relationship between particle shape and size
C. Hendrich, T. Vartanyan, F. Hubenthal, and F. Träger
Unveröffentlicht, 2005

Size dependent decay of the surface plasmon excitation in gold nanoparticles
C. Hendrich, F. Hubenthal, and F. Träger
Unveröffentlicht, 2005

Preparation of gold nanoparticles with narrow size distribution and well defined shapes
F. Hubenthal, C. Hendrich, H. Ouacha, D. Blázquez-Sánchez, F. Träger
Int. J. Mod. Phys. B 19, 2604-2609 (2005), Abstract

Irradiation of supported gold and silver nanoparticles with continuous-wave, nanosecond and femtosecond laser light: a comparative study
F. Hubenthal, M. Alschinger, M. Bauer, D. Blázquez Sánchez, N. Borg, M. Brezeanu, R. Frese, C. Hendrich, B. Krohn, M. Aeschlimann, F. Träger
Proceedings of SPIE 5838, 224-235 (2005), Abstract

Laser-assisted growth of gold nanoparticles: shaping and optical characterization
H. Ouacha, C. Hendrich, F. Hubenthal, F. Träger
Appl. Phys. B 81, 663-668, Abstract

Tuning the surface plasmon resonanceby preparation of gold-core/silver-shell and alloy nanoparticles
F. Hubenthal, T. Ziegler, C. Hendrich, F. Träger
Eur. Phys. Jour. D 34, 165-168 (2005), Abstract

Untersuchung der Elektronendynamik in Goldnanoteilchen durch Messung der Dephasierungszeit des Oberflächenplasmons mit spektralem Lochbrennen
C. Hendrich
Dissertation (2004)

Ultrafast dephasing of surface plasmon excitation in metal nanoparticles
C. Hendrich, T. Ziegler, J. Bosbach, T. Vartanyan, F. Hubenthal, F. Träger
Proc. SPIE 5352, 90-100 (2004), Abstract

Dephasing times of surface plasmon excitation in Au nanoparticles determined by persistent spectral hole burning
T. Ziegler, C. Hendrich, F. Hubenthal, T.Vartanyan, F. Träger
Chem. Phys. Lett. 386, 319-324 (2004), Abstract

The influence of the reduced dimension on the dephasing time of surface plasmon excitation in gold nanoparticles
F. Hubenthal, T. Ziegler, C. Hendrich, T.Vartanyan, F. Träger
Proceedings of SPIE 5221, 29-40 (2003), Abstract

Chemical interface damping of surface plasmon excitation in metal nanoparticles: a study by persistent spectral hole burning
C. Hendrich, J. Bosbach, F. Stietz, F. Hubenthal, T. Vartanyan, F. Träger
Applied Physics B 76, 8, 869-875, DOI: 10.1007/s00340-003-1168-9 (2003), Abstract

Ultrafast dephasing of surface plasmon excitation in silver nanoparticles: Influence of particle size, shape and chemical surrounding
J. Bosbach, C. Hendrich, F. Stietz, T. Vartanyan, F. Träger
Phys. Rev. Lett. 89, 25, 257404 (2002), Abstract

Theoretical foundations for size and shape selective laser-based manipulation of supported metal nanoparticles
T. Vartanyan, J. Bosbach, C. Hendrich, F. Stietz, F. Träger
in "Nanoscience using laser-solid interactions", editors: K. Murakami, D.B. Geohegan, F. Träger, Proceedings of SPIE 4636, 31 (2002), Abstract

Spectral hole burning in absorption profiles of metal nanoparticles prepared by laser assisted growth
J. Bosbach, C. Hendrich, T. Vartanyan, F. Stietz, F. Träger
European Physics Journal D 16, 213 (2001), Abstract, PDF

Laser manipulation of the size and shape of supported metal nanoparticles
J. Bosbach, C. Hendrich, T. Vartanyan, F. Stietz, T. Wenzel, F. Träger
Proceedings of SPIE 4274, 1 (2001), Abstract, PDF