On the conductivity of antidot lattices in magnetic fieldsOAKESHOTT, R. B. S; MACKINNON, A.Journal of physics. Condensed matter (Print). 1994, Vol 6, Num 8, pp 1519-1528, issn 0953-8984Article

Negative magnetoresistance and anomalous diffusion of two-dimensional electrons in a disordered array of antidotsGUSEV, G. M; BASMAJI, P; KVON, Z. D et al.Surface science. 1994, Vol 305, Num 1-3, pp 443-447, issn 0039-6028Conference Paper

Manifestation of quantum chaos in the spectra of quasi-one-dimensional surface superlatticesHONGQI XU.Journal of physics. Condensed matter (Print). 1998, Vol 10, Num 18, pp 4001-4014, issn 0953-8984Article

Exciton trapping in a hybrid ferromagnetic/semiconductor magnetic antidotFREIRE, J. A. K; MATULIS, A; PEETERS, F. M et al.Journal of magnetism and magnetic materials. 2001, Vol 226-30, pp 2038-2039, issn 0304-8853, 2Conference Paper

Anisotropic magneto-resistance in Ni₈₀Fe₂₀ antidot arrays with different lattice configurationsCOÏSSON, Marco; MANZIN, Alessandra; BARRERA, Gabriele et al.Applied surface science. 2014, Vol 316, pp 380-384, issn 0169-4332, 5 p.Article

Arrays of nanostructured antidot in Ni₈₀Fe₂₀ magnetic thin films by photolithography of polystyrene nanospheresTIBERTO, Paola; BOARINO, Luca; CELEGATO, Federica et al.Applied surface science. 2012, Vol 259, pp 44-48, issn 0169-4332, 5 p.Article

On the validity of quantum hydrodynamics for describing antidot array devicesBARKER, J. R; FERRY, D. K.Semiconductor science and technology. 1998, Vol 13, Num 8A, pp A135-A139, issn 0268-1242Conference Paper

Quantum transport and quantum chaos in antidot superlattices in a magnetic fieldSILBERBAUER, H; ROTTER, P; SUHRKE, M et al.Semiconductor science and technology. 1994, Vol 9, Num 11S, pp 1906-1911, issn 0268-1242Conference Paper

Surface superconducting states near elliptic antidots and in elliptic microdisksMEYERS, C; DAUMENS, M; BUZDIN, A et al.Physica. C. Superconductivity and its applications. 1999, Vol 325, Num 3-4, pp 118-126Article

Far-infrared excitations in antidot systems on silicon MOS structuresHUBER, A; JEJINA, I; LORENZ, H et al.Semiconductor science and technology. 1995, Vol 10, Num 3, pp 365-368, issn 0268-1242Article

Aharonov-Bohm conductance oscillation of an antidotTAKAGAKI, Y; FERRY, D. K.Surface science. 1994, Vol 305, Num 1-3, pp 669-673, issn 0039-6028Conference Paper

Magnetoplasmons and FIR response of an antidot arrayWU, G. Y; ZHAO, Y.Surface science. 1994, Vol 305, Num 1-3, pp 601-605, issn 0039-6028Conference Paper

Electronic structure of antidot superlattices in commensurate magnetic fieldsANISIMOVAS, Egidijus; JOHANSSON, Peter.Journal of physics. Condensed matter (Print). 2001, Vol 13, Num 14, pp 3365-3379, issn 0953-8984Article

Electron phase coherence length in a lattice of antidotsPOUYDEBASQUE, A; POGOSOV, A. G; BUDANTSEV, M. V et al.Physica. B, Condensed matter. 2001, Vol 298, Num 1-4, pp 287-290, issn 0921-4526Conference Paper

Magnetic irreversibility of the Fe antidot arrays film by depositing on the porous alumina templatesCHANGJUN JIANG; WENWEN WEI; QINGFANG LIU et al.Applied surface science. 2012, Vol 258, Num 8, pp 3723-3725, issn 0169-4332, 3 p.Article

Fractional statistics of Laughlin quasiparticles in quantum antidotsGOLDMAN, V. J; JUN LIU; ZASLAVSKY, A et al.Physical review B. Condensed matter and materials physics. 2005, Vol 71, Num 15, pp 153303.1-153303.3, issn 1098-0121Article

Symmetry and spectral statistics of the magnetic band structure of a one-dimensional surface superlatticeXU, H. Q; GU, Ben-Yuan.Journal of physics. Condensed matter (Print). 2001, Vol 13, Num 42, pp 9505-9514, issn 0953-8984Article

Flux confinement by regular arrays and clusters of antidots in Pb/Cu bilayersROSSEEL, E; PUIG, T; VAN BAEL, M. J et al.Superlattices and microstructures. 1998, Vol 23, Num 2, pp 489-492, issn 0749-6036Article

Quantum dot and antidot infrared photodetectors: Iterative methods for solving the laplace equation in domains with involved geometryPAVLOV, B. S; RYZHII, V. I.Theoretical and mathematical physics. 2004, Vol 141, Num 2, pp 1469-1481, issn 0040-5779, 13 p.Article

Geometric coercivity scaling in magnetic thin film antidot arraysRUIZ-FEAL, I; LOPEZ-DIAZ, L; NATALI, M et al.Journal of magnetism and magnetic materials. 2002, Vol 242-45, pp 597-600, issn 0304-8853, 1Conference Paper

Electronic properties of nanostructures defined in Ga[Al]As heterostructures by local oxidationFUHRER, A; DORN, A; LÜSCHER, S et al.Superlattices and microstructures. 2002, Vol 31, Num 1, pp 19-42, issn 0749-6036Article

Quantum interference effects on the conductance of a finite antidot array in a quantum wireBARBOSA, José Camilo; HAI, Guo-Qiang; MAREGA, Euclydes JR et al.Solid state communications. 2001, Vol 117, Num 12, pp 723-726, issn 0038-1098Article

Charge density wave transport in submicron antidot arrays in NbSe3LATYSHEV, Y. I; PANNETIER, B; MONCEAU, P et al.The European physical journal. B, Condensed matter physics. 1998, Vol 3, Num 4, pp 421-426, issn 1434-6028Article

From the two-dimensional electron gas to antidot superlattices : Magnetoresistance effects in the transition regimeSTEFFENS, O; SCHLÖSSER, T; ROTTER, P et al.Journal of physics. Condensed matter (Print). 1998, Vol 10, Num 17, pp 3859-3872, issn 0953-8984Article

Mesoscopic conductance fluctuations of a two-dimensional electron gas in a one-dimensional lattice of antidotsBUDANTSEV, M. V; KVON, Z. D; POGOSOV, A. G et al.Superlattices and microstructures. 1998, Vol 24, Num 4, pp 291-293, issn 0749-6036Article