Selected Publications / Ausgewählte Publikationen
Invited Contributions (taken from the years 1998 - 2009) / Eingeladene Übersichtsartikel (1998 - 2009):
I-15.	R. Huber, P. Klemm, S. Neusser, B. Botters, A. Wittmann, M. Weiler, S.T.B. Goennenwein, C. Heyn, M. Schneider, P. Böni, and D. Grundler: „Advanced techniques for all-electrical spectroscopy on spin caloric phenomena”, Solid State Communications 150, 492 (2010). [link: click here]
I-14.	Sebastian Neusser and Dirk Grundler: „Magnonics: Spin Waves on the Nanoscale”, Advanced Materials 21, 2927 - 2932 (2009). [link: click here]
I-13.	Dirk Grundler, Fabian Giesen, and Jan Podbielski: „Spin Waves in the Inhomogeneous Internal Field of Nanostructured Rings”, book article in : Spin Wave Confinement, S. Demokritov (ed.), World Scientific (2008). [link: click here]
I-12.	Dirk Grundler, Fabian Giesen, and Jan Podbielski: „Tailoring spin excitations by nanolithography”, Physics in Canada 63 (Special Issue: Spintronics), 63 (2007). [full article (pdf): click here]           [journal homepage "Physics in Canada" click here]
I-11.	J. Podbielski, F. Giesen, M. Berginski, N. Hoyer, and D. Grundler: „Spin configurations in nanostructured magnetic rings: from DC transport to GHz spectroscopy”, Superlattices and Microstructures 37, 341 (2005) [abstract: click here]
I-10.	A. Wittmann, C. H. Möller, O. Kronenwerth, M. Holz, and D. Grundler: „Hybrid ferromagnet/semiconductor nanostructures: spin-valve effect and extraordinary magnetoresistance”, J. Phys.: Condens. Matter 16, S5645 (2004) [abstract: click here]
I-9.	Dirk Grundler, Thomas M. Hengstmann, and Haiko Rolff: „Magnetic nanostructures for lateral spin-transport devices”, Brazilian Journal of Physics 34, no. 2A, 598 (2004). [full article (pdf): click here]           [BRAZILIAN JOURNAL click here]
I-8.	D. Grundler, T. Matsuyama, and C.-H. Möller: „Spin injection in ferromagnet/semiconductor hybrid structures”, Festkörperprobleme, Advances in Solid State Physics 43, 443 (2003).
I-7.	Dirk Grundler: „Ballistic electrons in ferromagnet/semiconductor hybrid structures: from nanomagnetometry to spin injection”, Acta Physica Polonica A 102, 529 (2002).
I-6.	Dirk Grundler:„Spintronics”, Physics World 15, 39 (April 2002). [full article (pdf): click here]            [journal homepage PHYSICS WOLRD]
I-5.	Dirk Grundler: „Spins im Nadelöhr”, in Phys. Bl. 9, 21 (2001).
I-4.	Dirk Grundler: „Spintronik”, Beitrag in „Welt der Physik” [webpage: click here]
I-3.	Guido Meier and Dirk Grundler: „Rashba spin-splitting and ferromagnetic electrodes on InAs”, Festkörperprobleme, Advances in Solid State Physics 40, 295-308 (2000).
I-2.	Dirk Grundler: „Magnetization phenomena of two-dimensional electron systems in the Quantum Hall effect regime ”, Festkörperprobleme, Advances in Solid State Physics 39, 221-230 (1999).
I-1.	I. Meinel, D. Grundler, S. Bargstädt-Franke, Ch. Heyn, and D. Heitmann: „SQUID-Susceptometry up to 10 Tesla: An Improved Method for Magnetization Studies on a Two-Dimensional Electron System ”, Appl. Supercond. 5, 261-267 (1998). [abstract: click here]
Selected Publications in Journals (1993 - 2009) / Ausgewählte Zeitschriftenbeiträge:
57.	Marco Madami, Silvia Tacchi, Gianluca Gubbiotti, Giovanni Carlotti, Adekunle O. Adeyeye, Sebastian Neusser, Bernhard Botters, and Dirk Grundler: „Angular dependence of magnetic normal modes in NiFe antidot lattices with different lattice symmetry”, Manuscript for Intermag/MMM, (2009).
56.	J. Topp, D. Heitmann, and D. Grundler: „Interaction effects on microwave-assisted switching of Ni80Fe20 nanowires in densely packed arrays”, Phys. Rev. B 80, 174421 (2009). [full text (pdf): click here]
55.	T. Windisch, X. Huang, S. Dasgupta, B. Rupprecht, C. Heyn, M. Bichler, A. Fontcuberta i Morral, M. Grayson, G. Abstreiter,  M. A. Wilde, and D. Grundler: „De Haas-van Alphen effect and energy gaps of a correlated two-dimensional electron system in an AlAs two-valley pseudospin system”, Phys. Rev. B 80, 205306 (2009). [full text (pdf): click here]
54.	Silvia Tacchi, Marco Madami, Gianluca Gubbiotti, Giovanni Carlotti, Adekunle O. Adeyeye, Sebastian Neusser, Bernhard Botters, and Dirk Grundler: „Magnetic normal modes in squared antidot array with circular holes: a combined Brillouin light scattering and broadband ferromagnetic resonance study”, IEEE Trans. on Magn., in press(2009).
53.	N. Ruhe, G. Stracke, Ch. Heyn, D. Heitmann, H. Hardtdegen, T. Schäpers, B. Rupprecht, M. A. Wilde, and D. Grundler: „Origin and limiting mechanism of induced nonequilibrium currents in gated two-dimensional electron systems”, Phys. Rev. B 80, 115336 (2009). [full text (pdf): click here]
52.	M. A. Wilde, D. Reuter, Ch. Heyn, A. D. Wieck, and D. Grundler: „Inversion-asymmetry-induced spin splitting observed in the quantum oscillatory magnetization of a two-dimensional electron system”, Phys. Rev. B 79, 125330 (2009). [full text (pdf): click here]
51.	Jesco Topp, Jan Podbielski, Detlef Heitmann, and Dirk Grundler: „Formation and control of internal spin-wave channels in arrays of densely packed Permalloy nanowires”, J. Appl. Phys. 105, 07D302 (2009). [full text (pdf): click here]
50.	S. Neusser, B. Botters, M. Becherer, D. Schmitt-Landsiedel, and D. Grundler: „Spin wave localization between nearest and next-nearest neighboring holes in an antidot lattice”, Appl. Phys. Lett. 93, 122501 (2008). [full text (pdf): click here]
49.	S. Neusser, B. Botters, and D. Grundler: „Localization, confinement, and field-controlled propagation of spin waves in antidot lattices”, Phys. Rev. B 78, 054406 (2008). [full text (pdf): click here]
48.	J. Topp, J. Podbielski, D. Heitmann, and D. Grundler: „Internal spin-wave confinement in magnetic nanowires due to zig-zag magnetization”, Phys. Rev. B 78, 024431 (2008). [full text (pdf): click here]
47.	A. Brandlmaier, S. Geprägs, M. Weiler, A. Boger, M. Opel, H. Huebl, C. Bihler, M. S. Brandt, B. Botters, D. Grundler, R. Gross, and S. T. B. Goennenwein: „In situ manipulation of magnetic anisotropy in magnetite thin films”, Phys. Rev. B 77, 104445 (2008). [full text (pdf): click here]
46.	E. V. Konenkova, D. Grundler, M. Morgenstern, and R. Wiesendanger: „Metal–Insulator Transition in Graphite: A Comparison to Heterostructures with High Carrier Mobility”, Technical Physics Letters 34, 30 (2008) [Original Russian Text: Pis’ma v Zhurnal Tekhnicheskoi Fiziki 34, 65 (2008)]. [full text (pdf): click here]
45.	M. A. Wilde, J. I. Springborn, O. Roesler, N. Ruhe, M. P. Schwarz, D. Heitmann, and D. Grundler: „Magnetometry on quantum Hall systems: Thermodynamic energy gaps and the density of states distribution”, Phys. Stat. Sol. (b) 245, 344 (2008). [abstract: click here]
44.	J. Podbielski, D. Heitmann, and D. Grundler: „Microwave Assisted Switching of Microscopic Rings: Correlation between Nonlinear Spin Dynamics and Critical Microwave Fields”, Phys. Rev. Lett. 99, 207202 (2007). [full text (pdf): click here]
43.	F. Giesen, J. Podbielski, and D. Grundler: „Mode localization transition in ferromagnetic microscopic rings”, Phys. Rev. B 76, 014431 (2007). [full text (pdf): click here]
42.	F. Giesen, J. Podbielski, B. Botters, and D. Grundler: „Vortex circulation control in large arrays of asymmetric magnetic rings”, Phys. Rev. B 75, 184428 (2007). [full text (pdf): click here]
41.	N. Ruhe, J. I. Springborn, Ch. Heyn, M. A. Wilde, and D. Grundler: „Simultaneous measurement of the de Haas-van Alphen and the Shubnikov-de Haas effect in a two-dimensional electron system”, Phys. Rev. B 74, 235326 (2006). [full text (pdf): click here]
40.	Bernhard Botters, Fabian Giesen, Jan Podbielski, Peter Bach, Georg Schmidt, Laurens W. Molenkamp, and Dirk Grundler: „Stress dependence of ferromagnetic resonance and magnetic anisotropy in a thin NiMnSb film on InP(001)”, Appl. Phys. Lett. 89, 242505 (2006). [full text (pdf): click here]
39.	J. Podbielski, F. Giesen, and D. Grundler: „Spin-Wave Interference in Microscopic Rings”, Phys. Rev. Lett. 96, 167207 (2006). [full text (pdf): click here]
38.	Matthias Hoener, Oliver Kronenwerth, Christian Heyn, Dirk Grundler, and Matthias Holz: „Geometry-enhanced magnetoresistance of narrow Au/InAs hybrid structures incorporating a two-dimensional electron system”, J. Appl. Phys. 99, 036102(R) (2006). [full text (pdf): click here]
37.	M. A. Wilde, M. P. Schwarz, Ch. Heyn, D. Heitmann, D. Grundler, D. Reuter, and A. D. Wieck: „Experimental evidence of the ideal de Haas–van Alphen effect in a two-dimensional system”, Phys. Rev. B 73, 125325 (2006). [full text (pdf): click here]
36.	M. Holz, O. Kronenwerth, and D. Grundler: „Semiconductor-metal hybrid structures as local magnetic-field probes: Magnetoresistance and spatial sensitivity profile”, Appl. Phys. Lett. 87, 172501 (2005) [abstract: click here]
35.	F. Giesen, J. Podbielski, T. Korn, and D. Grundler: „Multiple ferromagnetic resonance in mesoscopic permalloy rings”, J. Appl. Phys. 97, 10A712 (2005) [full text (pdf): click here]
34.	F. Giesen, J. Podbielski, T. Korn, M. Steiner, A. van Staa, and D. Grundler: „Hysteresis and control of ferromagnetic resonances in rings”, Appl. Phys. Lett. 86, 112510 (2005) [full text (pdf): click here]
33.	M. Holz, O. Kronenwerth, and D. Grundler: „Enhanced sensitivity due to current redistribution in the Hall effect of semiconductor-metal hybrid structures”, Appl. Phys. Lett. 86, 072513 (2005) [abstract: click here]
32.	M. A. Wilde, M. Rhode, Ch. Heyn, D. Heitmann, D. Grundler, U. Zeitler, F. Schäffler, and R. J. Haug: „Direct measurements of the spin and valley splittings in the magnetization of a Si/SiGe quantum well in tilted magnetic fields”, Phys. Rev. B 72, 165429 (2005). [full text (pdf): click here]
31.	C.-H. Möller, O. Kronenwerth, Ch. Heyn, and D. Grundler: „Low-noise magnetic-flux sensors based on the extraordinary magnetoresistance effect”, Appl. Phys. Lett. 84, 3343 (2004). [abstract: click here]
30.	H. Rolff, W. Pfützner, Ch. Heyn, and D. Grundler: „Hall magnetometry on a ferromagnetic nanoring”, Journal of Magnetism and Magnetic Materials 272-276, 1623 (2004) [abstract: click here]
29.	M.A. Wilde, J.I. Springborn, Ch. Heyn, D. Heitmann, and D. Grundler: „Magnetization of GaAs quantum wires with quasi-one-dimensional electron systems”, Physica E 22, 729 (2004). [abstract: click here]
28.	M. Holz, O. Kronenwerth, and D. Grundler: „Optimization of the extraordinary magnetoresistance in semiconductor–metal hybrid structures for magnetic-field sensor applications”, Physica E 21, 897 (2004).[abstract: click here]
27.	M. Holz, O. Kronenwerth, and D. Grundler: „Optimization of semiconductor-metal hybrid structures for application in magnetic-field sensors and read heads”, Appl. Phys. Lett. 83, 3344 (2003) [abstract: click here]
26.	C.-H. Möller, Ch. Heyn, and D. Grundler: „Spin splitting in narrow InAs quantum wells with In0.75Ga0.25As barrier layers”, Appl. Phys. Lett. 83, 2181 (2003). [abstract: click here]
25.	M. Holz, O. Kronenwerth, and D. Grundler: „Magnetoresistance in metal/semiconductor hybrid structures: the effect of material parameters and contact resistance”, Phys. Rev. B 67, 195312 (2003). [abstract: click here]
24.	M.P. Schwarz, D. Grundler, Ch. Heyn, D. Heitmann, D. Reuter, and A.D. Wieck: „Induced non-equilibrium currents in the magnetization of mesoscopic dots in the quantum Hall regime”, Phys. Rev. B 68, 245315 (2003) . [abstract: click here]
23.	O. Wunnicke, Ph. Mavropoulos, R. Zeller, P.H. Dederichs, and D. Grundler: „Ballistic spin injection from Fe(001) into ZnSe and GaAs”, Phys. Rev. B 65, 241306 (2002). [abstract: click here]
22.	C.-H. Möller, O. Kronenwerth, D. Grundler, W. Hansen, Ch. Heyn, and D. Heitmann:„Extraordinary magnetoresistance effect in microstructured metal/semiconductor hybrid structures”, Appl. Phys. Lett. 80, 3988 (2002). [abstract: click here]
21.	M.P. Schwarz, M.A. Wilde, S. Groth, D. Grundler, Ch. Heyn, and D. Heitmann: „Sawtooth-like de Haas-van Alphen oscillations of a two-dimensional electron system ”, Phys. Rev. B 65, 245315 (2002).[abstract: click here]
20.	D. Grundler, T.M. Hengstmann, N. Klockmann, Ch. Heyn, and D. Heitmann: „Bend-resistance nanomagnetometry: spatially resolved magnetization studies in ferromagnet/semiconductor hybrid structures”, Physica E 12, 248 (2002). [abstract: click here]
19.	T. Matsuyama, C.-M. Hu, D. Grundler, G. Meier, and U. Merkt: „Ballistic spin transport and spin interference in ferromagnet/InAs(2DES)/ferromagnet devices”, Phys. Rev. B 65, 155322 (2002). [abstract: click here]
18.	M. P. Schwarz, D. Grundler, H. Rolff, M. Wilde, S. Groth, Ch. Heyn, and D. Heitmann: „De Haas-van Alphen effect in a two-dimensional electron system”, Physica E 12, 140 (2002). [abstract: click here]
17.	M. P. Schwarz, D. Grundler, M. Wilde, Ch. Heyn, and D. Heitmann: „Magnetization of semiconductor quantum dots”, J. Appl. Phys. 91, 6875 (2002). [abstract: click here]
16.	Dirk Grundler: „Oscillatory Spin Filtering due to Gate-Control of the Spin-dependent Interface Conductance”, Phys. Rev. Lett. 86, 1058 (2001). [abstract: click here]
15.	Dirk Grundler: „Ballistic spin-filter transistor”, Phys. Rev. B 63, 161307 (R) (2001). [abstract: click here]
14.	T.M. Hengstmann, D. Grundler, Ch. Heyn, and D. Heitmann: „Stray-field investigation on permalloy nanodiscs”, J. Appl. Phys. 90, 6542 (2001). [abstract: click here]
13.	I. Meinel, D. Grundler, D. Heitmann, M. Bichler, W. Wegscheider, V. Gudmundsson, and A. Manolescu: „Enhanced magnetization of the integer quantum Hall effect”, Phys. Rev. B 64, 121306 (R) (2001). [abstract: click here]
12.	G. Meier, D. Grundler, K.-B. Broocks, Ch. Heyn, and D. Heitmann: „Effect of tilted magnetic fields on bistable nanomagnets in hybrid semiconductor/ferromagnet devices ”, Journal of Magnetism and Magnetic Materials 210, 138-142 (2000). [abstract: click here]
11.	Dirk Grundler: „Large Rashba-Splitting in InAs-Quantum Wells due to Electron Wave Function Penetration into the Barrier Layers”, Phys. Rev. Lett. 84, 6074-6077 (2000). [abstract: click here]
10.	M. P. Schwarz, D. Grundler, I. Meinel, Ch. Heyn, and D. Heitmann: „Micromechanical cantilever-magnetometer with an integrated two-dimensional electron system”, Appl. Phys. Lett. 76, 3564 (2000). [abstract: click here]
9.	I. Meinel, T. Hengstmann, D. Grundler, D. Heitmann, W. Wegscheider, and M. Bichler: „Magnetization of the Fractional Quantum Hall States”, Phys. Rev. Lett. 82, 819-822 (1999). [abstract: click here]
8.	G.Meier, M. Kleiber, D. Grundler, D. Heitmann, and R. Wiesendanger: „Vertical Polarization of Quantum Magnets in High Density Arrays of Nickel Dots with small Height-to-Diameter Ratio ”, Appl. Phys. Lett. 72, 2168 (1998). [abstract: click here]
7.	I. Meinel, D. Grundler, S. Bargstädt-Franke, Ch. Heyn, D. Heitmann, and B. David: „High-sensistive Superconducting Magnetometry on a Two-Dimensional Electron Gas up to 10 Tesla”,  Appl. Phys. Lett. 70, 3305 (1997). [abstract: click here]
6.	B. David, D. Grundler, S. Krey, V. Doormann, R. Eckart, J.-P. Krumme, G. Rabe, and O. Dössel: „High-Tc SQUID Magnetometers for Biomagnetic Measurements”, Supercond. Sci. Technol. 9 , A 96 (1996) . [abstract: click here]
5.	Dirk Grundler, Bernd David, and Olaf Dössel: „Experimental investigation of the kinetic inductance in YBa2Cu3O7 square washer SQUIDs”, J. Appl. Phys. 77, 5273 (1995). [abstract: click here]
4.	V. Polushkin, S. Uchaikin, S. Knappe, H. Koch, B. David, and D. Grundler: „Current Phase Relation of YBa2Cu3O7-d Step Edge Junction”, IEEE Trans. Appl. Supercond. 5, 2790 (1995) [access to abstract: click here]
3.	D. Grundler, J.-P. Krumme, B. David, and O. Dössel: „YBa2Cu3O7 ramp-type junctions and superconducting quantum interference devices with an ultrathin barrier of NdGaO3 ”, Appl. Phys. Lett. 65, 1841 (1994). [abstract: click here]
2.	D. Grundler, B. David, R. Eckart, and O. Dössel: „Highly sensitive YBa2Cu3O7 dc SQUID magnetometer with thin-film flux transformer ”, Appl. Phys. Lett. 63, 2700 (1993). [full text (pdf): click here]
1.	D. Grundler, R. Eckart, B. David, and O. Dössel: „Origin of 1/f noise in YBa2Cu3O7-x step-edge dc SQUIDs ”, Appl. Phys. Lett. 62, 2134 (1993). [abstract: click here]