{"id":414,"date":"2014-08-01T11:08:45","date_gmt":"2014-08-01T11:08:45","guid":{"rendered":"http:\/\/www.icmm.csic.es\/tqe\/?page_id=414"},"modified":"2026-02-26T09:15:52","modified_gmt":"2026-02-26T09:15:52","slug":"maria-jose-calderon-publications","status":"publish","type":"page","link":"https:\/\/wp.icmm.csic.es\/tqe\/people\/maria-jose-calderon\/maria-jose-calderon-publications\/","title":{"rendered":"Publications"},"content":{"rendered":"

Mar\u00eda Jos\u00e9 Calder\u00f3n<\/a><\/p>\n

On the arXiv<\/a>
\nGoogle Scholar<\/a>
\nResearcher ID:\u00a0A-4888-2009<\/a>
\nORCID<\/a><\/p>\n

71. Granular aluminum induced superconductivity in germanium for hole spin-based hybrid devices. <\/strong>Giorgio Fabris, Paul Falthansl-Scheinecker,\u00a0Devashish Shah,\u00a0Daniel Michel Pino,\u00a0Maksim Borovkov,\u00a0Anton Bubis,\u00a0Kevin Roux,\u00a0Dina Sokolova,\u00a0Alejandro Andres Juanes,\u00a0Tommaso Costanzo,\u00a0Inas Taha,\u00a0Aziz Gen\u00e7,\u00a0Jordi Arbiol,\u00a0Stefano Calcaterra,\u00a0Afonso De Cerdeira Oliveira,\u00a0Daniel Chrastina,\u00a0Giovanni Isella,\u00a0Ruben Seoane Souto,\u00a0Maria Jose Calderon,\u00a0Ramon Aguado,\u00a0Jose Carlos Abadillo-Uriel,\u00a0Georgios Katsaros. arXiv:2602.21364<\/a><\/p>\n

70. Switchable spin-photon coupling with hole spins in single-quantum dots.<\/strong> C. Sagaseta, M.J. Calder\u00f3n, J.C. Abadillo-Uriel. arXiv:2510.05301. <\/a>Accepted in Materials for Quantum Technology.<\/a><\/p>\n

69. Flux-tunable parity-protected qubit based on a single full-shell nanowire Josephson junction. <\/strong>G. Giavaras, Rub\u00e9n Seoane Souto, Maria Jos\u00e9 Calder\u00f3n, and Ram\u00f3n Aguado.\u00a0 Phys. Rev. B\u00a0111<\/b>, 235432 (2025).\u00a0<\/a><\/p>\n

68. Theory of superconducting proximity effect in hole-based hybrid semiconductor-superconductor devices.<\/strong> \u00a0D. Michel Pino, Rub\u00e9n Seoane-Souto, Mar\u00eda Jos\u00e9 Calder\u00f3n, Ram\u00f3n Aguado, Jos\u00e9 Carlos Abadillo-Uriel. Physical Review B 111,<\/strong> 235443 (2025).<\/a> arXiv:2501.00088<\/a><\/p>\n

67. Cascades in transport and optical conductivity of Twisted Bilayer Graphene.<\/strong> \u00a0M. J. Calder\u00f3n, A. Camjayi, A. Datta, E. Bascones. Phys. Rev. B\u00a0112<\/b>, L041126 (2025).\u00a0<\/a>arXiv:2412.20855.\u00a0 <\/a><\/p>\n

66. High-Harmonic Generation with a twist: all-optical characterization of magic-angle twisted bilayer graphene. <\/strong>Eduardo B. Molinero, Anushree Datta, Mar\u00eda J. Calder\u00f3n, Elena Bascones, Rui E. F. Silva. Optica 11, 171 (2024)<\/a>. arXiv:2302.04127.\u00a0<\/a><\/p>\n

65. Heavy quasiparticles and cascades without symmetry breaking in twisted bilayer graphene.\u00a0<\/strong> Anushree Datta, M.J. Calder\u00f3n, A. Camjayi, E. Bascones. Nature Communications 14, 5036 (2023)<\/a>. arXiv:2301.13024. <\/a><\/span><\/p>\n

64. Twisted bilayered graphenes at magic angles and Casimir interactions: correlation-driven effects. <\/strong>Pablo Rodriguez-Lopez, Dai-Nam Le, Mar\u00eda J. Calder\u00f3n, Elena Bascones, and Lilia M. Woods. 2D Mater. 10, 014006 (2023).<\/a> arxiv:2210.02378<\/a><\/p>\n

63. Mott correlations in ABC graphene trilayer aligned with hBN.<\/strong> M.J. Calder\u00f3n, A. Camjayi, E. Bascones. arXiv:2202.13857<\/a>. Phys. Rev. B 106, L081123 (2022).<\/a><\/p>\n

62. The role of orbital nesting in the superconductivity of iron-based superconductors. <\/strong>R. Fern\u00e1ndez-Mart\u00edn, M.J. Calder\u00f3n, L. Fanfarillo and Bel\u00e9n Valenzuela. arXiv:2107.02825. <\/a>Condens. Matter 6(3), 34 (2021).<\/p>\n

61. Interactions in the 8-orbital model for twisted bilayer graphene. <\/strong>M. J. Calder\u00f3n and E. Bascones. arXiv:2007.16051. <\/a>Phys. Rev. B 102, 155149 (2020).<\/a><\/p>\n

60. Correlated states in magic angle twisted bilayer graphene under the optical conductivity scrutiny.<\/strong> M. J. Calder\u00f3n and E. Bascones. arXiv:1912.09935. <\/a>npj Quantum Materials<\/i><\/a> \u00a05<\/b>, 57<\/span> (2020<\/span>).<\/a><\/p>\n

59. Lifting of Spin Blockade by Charged Impurities in Si-MOS Double Quantum Dot Devices. <\/strong>Cameron King, Joshua S. Schoenfield, M. J. Calder\u00f3n, Belita Koiller, Andr\u00e9 Saraiva, Xuedong Hu, HongWen Jiang, Mark Friesen, S. N. Coppersmith. arXiv: 1807.11064.\u00a0<\/a>Phys. Rev. B 101, 155411 (2020)<\/a><\/p>\n

58.\u00a0 Signatures of atomic-scale structure in the energy dispersion and coherence of a Si quantum-dot qubit.<\/strong> J. C. Abadillo-Uriel, Brandur Thorgrimsson, Dohun Kim, L. W. Smith, C. B. Simmons, Daniel R. Ward, Ryan H. Foote, J. Corrigan, D. E. Savage, M. G. Lagally, M. J. Calder\u00f3n, S. N. Coppersmith, M. A. Eriksson, Mark Friesen. arXiv:1805.10398.\u00a0<\/a>Phys. Rev. B 98, 165438 (2018).<\/a><\/p>\n

57.\u00a0 Electric-field tuning of the valley splitting in silicon corner dots.<\/strong> David J. Ibberson, L\u00e9o Bourdet, Jos\u00e9 C. Abadillo-Uriel, Imtiaz Ahmed, Sylvain Barraud, Mar\u00eda J. Calder\u00f3n, Yann-Michel Niquet, M. Fernando Gonzalez-Zalba.\u00a0arXiv:1805.07981.\u00a0<\/a>Appl. Phys. Lett. 113<\/b>, 053104 (2018).<\/a><\/p>\n

56. The nature of correlations in the insulating states of twisted bilayer graphene.<\/strong> J. M. Pizarro, M. J. Calder\u00f3n, E. Bascones. arXiv:1805.07303. <\/a>Journal of Physics Communications (2019).<\/a><\/p>\n

55.<\/strong> 2-dimensional semiconductors pave the way towards dopant based quantum computing.<\/strong> J. C. Abadillo-Uriel, Belita Koiller, M. J. Calder\u00f3n. arXiv:1801.02222.\u00a0\u00a0<\/a>Beilstein J. Nanotechnol. 9, 2668\u20132673 (2018).<\/a><\/p>\n

54. Enhancement of spin-orbit coupling at manganite surfaces<\/strong>. S. Valencia, M.J. Calder\u00f3n, L. L\u00f3pez-Mir, Z. Kostantinovic, E. Schierle, E. Weschke, L. Brey, B. Mart\u00ednez, and Ll. Balcells. arXiv:1808.09990.\u00a0<\/a>Phys Rev B 98, 115142 (2018)<\/a><\/p>\n

53. Fully tunable coherence and control of acceptor qubits in Si.\u00a0<\/strong>J. C. Abadillo-Uriel, J. Salfi, X. HU, S. Rogge, M. J. Calder\u00f3n and D. Culcer. arXiv:1706.08858.\u00a0<\/a>Appl. Phys. Lett. 113<\/b>, 012102 (2018).<\/a> Article highlighted in an APL editorial<\/a>.<\/p>\n

52.\u00a0Spin qubit manipulation of acceptor bound states in group IV quantum wells.\u00a0<\/strong>J. C. Abadillo-Uriel, M. J. Calder\u00f3n. New Journal of Physics<\/a>. \u00a0arXiv:1702.00960<\/a><\/p>\n

51.\u00a0Strong correlations and the search for high-Tc superconductivity in chromium pnictides and chalcogenides. <\/strong>Kaleidoscope<\/a>.\u00a0<\/strong>J.M. Pizarro, M.J. Calder\u00f3n, J. Liu, M.C. Mu\u00f1oz, and E. Bascones. Phys. Rev. B 95<\/b>, 075115 (2017),\u00a0<\/a>arXiv:1610.09560<\/a>.<\/p>\n

50. Interface effects on acceptor qubits in silicon and germanium.<\/strong>
\nJ. C. Abadillo-Uriel, M. J. Calder\u00f3n.\u00a0\u00a0Nanotechnology 27, 024003 (2016)<\/a>,\u00a0arXiv:1509.00699<\/a><\/p>\n

49.\u00a0<\/strong>Donor Wavefunctions in Si Gauged by STM Images.<\/strong>
\nA. L. Saraiva, J. Salfi, J. Bocquel, B. Voisin, S. Rogge, Rodrigo B. Capaz, M.J. Calder\u00f3n, Belita Koiller.
\narXiv:1508.02772<\/a>.Phys. Rev. B 93<\/b>, 045303 (2016).<\/a><\/p>\n

48. Magnetic interactions in iron superconductors: A review.\u00a0<\/strong>
\nE. Bascones, B. Valenzuela, and M.J. Calder\u00f3n.\u00a0arXiv:1503.04223<\/a>.
\nComptes Rendus Physique 17, 36 (2016).<\/a><\/p>\n

47.\u00a0Signatures of a two-dimensional ferromagnetic electron gas at the\u00a0La0.7<\/sub>Sr0.3<\/sub>MnO3<\/sub>\/SrTiO3<\/sub> interface arising from orbital reconstruction.\u00a0<\/strong>
\nNorbert Nemes, Mar\u00eda Jos\u00e9 Calder\u00f3n, Juan Ignacio Beltr\u00e1n, Flavio Yair Bruno,\u00a0Javier Garc\u00eda-Barriocanal, Zouhair Sefrioui, Carlos Le\u00f3n, Mar Garc\u00eda-Hern\u00e1ndez, Carmen\u00a0Mu\u00f1oz, Luis Brey, and Jacobo Santamar\u00eda.\u00a0Advanced Materials\u00a026, 7516 (2014)<\/a>.\u00a0<\/i><\/p>\n

46. Theory of one and two donors in Silicon<\/strong>
\nA.L. Saraiva, A. Baena, M.J. Calder\u00f3n,\u00a0Belita\u00a0Koiller
\nJ. Phys.: Condens. Matter 27, 154208 (2015)<\/a>\u00a0(Special Issue on Single donors).\u00a0arXiv:1407.8224<\/a>.\u00a0Labtalk article.<\/a><\/p>\n

45.\u00a0Correlation, doping and interband effects on the optical conductivity of iron superconductors<\/strong>
\nM.J. Calder\u00f3n, L. de’ Medici, B. Valenzuela, and \u00a0E. Bascones
\n\u00a0Phys. Rev. B 90, 115128 (2014).\u00a0<\/a>arXiv:1407.6935<\/a><\/p>\n

44. An exchange-coupled donor molecule in silicon<\/strong>
\nM.F. Gonz\u00e1lez-Zalba,\u00a0A.L.Saraiva,\u00a0D.\u00a0Heiss, M.J. Calder\u00f3n,\u00a0Belita\u00a0Koiller, A.J.\u00a0Ferguson
\nNano Letters 14, 5672 (2014).\u00a0<\/a>arXiv:1312.4589<\/a>.
\n<\/em><\/p>\n

43. Coupling of the A1g\u00a0As phonon to magnetism in iron pnictides<\/strong>
\nN.A. Garc\u00eda-Mart\u00ednez, B. Valenzuela, S. Ciuchi, E. Capelluti,M.J. Calder\u00f3n, and E. Bascones
\nPhys. Rev. B 88, 165106 (2013).<\/a>\u00a0arXiv:1307.7065.<\/a><\/p>\n

42. Optical conductivity and Raman scattering of iron superconductors<\/strong>
\nB. Valenzuela, M.J. Calder\u00f3n, G. Le\u00f3n, E. Bascones
\nPhysical Review B 87, 075136 (2013).\u00a0\u00a0<\/a>\u00a0arXiv:1212.4765<\/a>.<\/p>\n

41. Orbital differentiation and the role of orbital ordering in the magnetic state of Fe superconductors<\/strong>
\nE.\u00a0Bascones, B. Valenzuela, M.J. Calder\u00f3n
\nPhysical\u00a0Review\u00a0B 86, 174508 (2012).<\/a>\u00a0arXiv:1208.1917<\/a><\/p>\n

40. Magnetic interactions in iron superconductors studied with a five-orbital model within the Hartree-Fock and Heisenberg approximations<\/strong>
\nM.J. Calder\u00f3n,\u00a0G.\u00a0Leon,\u00a0B. Valenzuela,\u00a0E.\u00a0Bascones
\nPhysical\u00a0Review\u00a0B 86, 104514 (2012).<\/a>\u00a0arXiv:1107.2279<\/a><\/p>\n

39. Impact of the valley degree of freedom on the control of donor electrons near a Si\/SiO2\u00a0interface<\/strong>
\nA. Baena,\u00a0A.L.Saraiva,\u00a0Belita Koiller,\u00a0M.J. Calder\u00f3n
\nPhysical\u00a0Review\u00a0B 86, 035317 (2012).<\/a>\u00a0arXiv:1203.6245<\/a>.<\/p>\n

38. Magnetic Field Probing of an SU(4) Kondo Resonance in a Single Atom Transistor<\/strong>
\nG.C. Tettamanzi,\u00a0J. Verduijn,\u00a0G.P. Lansbergen,\u00a0M. Blaauboer,\u00a0M.J. Calder\u00f3n,\u00a0R. Aguado,\u00a0S. Rogge.
\nPhysical Review Letters 108, 046803 (2012).<\/a>\u00a0arXiv:1102.2977<\/a><\/p>\n

37. Intervalley coupling for interface-bound electrons in silicon: An effective mass study<\/strong>
\nA.L.\u00a0Saraiva, M.J. Calder\u00f3n, R. Capaz, X.\u00a0Hu, S. Das\u00a0Sarma, B.\u00a0Koiller.
\nPhysical Review B 84,155320 (2011)<\/a>.\u00a0arXiv:1006.3338<\/a>.<\/p>\n

36. Magnetoelectric coupling at the interface of BiFeO3\/La0.7Sr0.3MnO3\u00a0multilayers.<\/strong>
\nM.J. Calder\u00f3n, S. Liang, R. Yu, J. Salafranca, S. Dong, S. Yunoki, L. Brey, A. Moreo, and E. Dagotto.
\nPhysical Review B 84, 024422 (2011)<\/a>.\u00a0arXiv:1012.1448<\/a>.<\/p>\n

35. Effect of strain on the orbital and magnetic ordering of manganite thin films and their interface with an insulator.<\/strong>
\nA.Baena, L. Brey, and M.J. Calder\u00f3n.
\nPhysical Review B 83, 064424 (2011)<\/a>.\u00a0arXiv:1009.4548<\/a>.<\/p>\n

34. Conductivity anisotropy in the antiferromagnetic state of iron pnictides.\u00a0<\/strong>
\nB. Valenzuela, E. Bascones, and M.J. Calder\u00f3n.
\nPhys. Rev. Lett.\u00a0105<\/strong>, 207202 (2010)<\/a>.\u00a0arXiv:1007.3483<\/a><\/p>\n

33. Heterointerface effects on the charging energy of shallow D- ground state in silicon: the role of dielectric mismatch.\u00a0<\/strong>
\nM.J. Calder\u00f3n, J. Verduijn, G.P. Lansbergen, G.C. Tettamanzi, S. Rogge, Belita Koiller.
\nPhys. Rev. B\u00a082<\/strong>, 075317 (2010)<\/a>.\u00a0arXiv:1005.1237<\/a><\/p>\n

32. All-Manganite Tunnel Junctions with Interface-Induced Barrier Magnetism.<\/strong>
\nZ. Sefrioui, C. Visani, M.J. Calder\u00f3n, K. March, C. Carr\u00e9t\u00e9ro, M. Walls, A. Rivera-Calzada, C. Le\u00f3n, R. L\u00f3pez Ant\u00f3n, T. R. Charlton, D. Imhoff, L. Brey, M. Bibes, J. Santamar\u00eda and A. Barth\u00e9l\u00e9my.
\nAdvanced Materials\u00a022<\/strong>, 5029 (2010).<\/a><\/p>\n

31. Low magnetization and anisotropy in the antiferromagnetic state of undoped iron pnictides.\u00a0<\/strong>
\nE. Bascones, M.J. Calder\u00f3n, and B. Valenzuela.
\nPhysical Review Letters\u00a0104<\/strong>, 227201 (2010)<\/a>.\u00a0arXiv:1002.2584<\/a>.<\/p>\n

30. Tight binding model for iron pnictides.<\/strong>
\nM.J.\u00a0Calder\u00f3n, B. Valenzuela, and E.\u00a0Bascones.
\nPhys. Rev. B\u00a080<\/strong>, 094531 (2009)<\/a>.\u00a0arXiv:0907.1259<\/a>.<\/p>\n

29. Physical mechanisms of interface-mediated intervalley coupling in Si.<\/strong>
\nA.L.\u00a0Saraiva, M.J. Calder\u00f3n, X.\u00a0Hu, S. Das\u00a0Sarma, and B.\u00a0Koiller.
\nPhys. Rev. B\u00a080<\/strong>, 081305 (2009)<\/a>.\u00a0arXiv:0901.4702<\/a>.<\/p>\n

28. Quantum control and manipulation of donor electrons in Si-based quantum computing.<\/strong>
\nM.J. Calder\u00f3n, A. Saraiva, B. Koiller and S. Das Sarma.
\nJournal of Applied Physics\u00a0105,<\/strong>\u00a0122410 (2009).<\/a>\u00a0arXiv:0809.3660<\/a>.
\nInvited Presentation at the 29th International Conference on the Physics of Semiconductors, Rio de Janeiro – Brazil, Jul 27-Aug 1, 2008.<\/em><\/p>\n

27. Effect of the tetrahedral distortion on the electronic properties of iron-pnictides.<\/strong>
\nM.J. Calder\u00f3n, B. Valenzuela, and E. Bascones.
\nNew Journal of Physics\u00a011<\/strong>, 013051 (2009)\u00a0<\/a>.\u00a0arXiv:0810.0019<\/a>.<\/p>\n

26. Electron gas at the interface between two antiferromagnetic insulating manganites.<\/strong>
\nM.J. Calder\u00f3n, J. Salafranca, and L. Brey.
\nPhys. Rev. B\u00a078<\/strong>, 024415 (2008)<\/a>.\u00a0arXiv:0804.3454<\/a>.<\/p>\n

25. Model of valley interference effects on a donor electron close to a Si\/SiO2\u00a0interface.\u00a0<\/strong>
\nM.J. Calder\u00f3n, B. Koiller, and S. Das Sarma.
\nPhys. Rev. B\u00a077<\/strong>, 155302 (2008)<\/a>.\u00a0arXiv:0712.1823<\/a>.<\/p>\n

24. Limited local electron-lattice coupling in manganites: An electron diffraction study.\u00a0<\/strong>
\nD. S\u00e1nchez, M.J. Calder\u00f3n, J. S\u00e1nchez-Ben\u00edtez, A.J. Williams, J.P. Attfield, P.A. Midgley and N.D. Mathur.
\nPhys. Rev. B\u00a077<\/strong>, 092411 (2008)<\/a>.\u00a0arXiv:0801.4626<\/a>.<\/p>\n

23. Magnetoresistance of an all-manganite spin-valve: A thin antiferromagnetic insulator sandwiched between two ferromagnetic metallic electrodes.\u00a0<\/strong>
\nJ. Salafranca, M.J. Calder\u00f3n, and L. Brey.
\nPhys. Rev. B\u00a077<\/strong>, 014441 (2008)<\/a>.\u00a0arXiv:0709.3720<\/a>.<\/p>\n

22. Heitler-London treatment for exchange gates in semiconductor double-dot quantum computer architectures.\u00a0<\/strong>
\nA.L. Saraiva, M.J. Calder\u00f3n, and Belita Koiller.
\nPhys. Rev. B\u00a076<\/strong>, 233302 (2007)<\/a>.\u00a0arXiv:0706.3354<\/a>.<\/p>\n

21. The current spin on manganites.
\n<\/strong>COVER STORY IN MATERIALS TODAY, OCTOBER 2007.<\/a>
\nC. Israel, M. J. Calder\u00f3n, and N. D. Mathur.
\nMaterials Today\u00a010<\/strong>, 24 (2007)<\/a>.\u00a0arXiv:0707.0746\u00a0<\/a>.<\/p>\n

20. Re-entrant ferromagnetism in a generic class of diluted magnetic semiconductors.\u00a0<\/strong>
\nM.J. Calder\u00f3n and S. Das Sarma.
\nPhys. Rev. B\u00a075<\/strong>, 235203 (2007)<\/a>.\u00a0cond-mat\/0611384\u00a0<\/a>.<\/p>\n

19. Proposal for electron spin relaxation measurement using double-donor excited states in Si quantum computer architectures.<\/strong>
\nM.J. Calder\u00f3n, Belita Koiller, and S. Das Sarma.
\nPhys. Rev. B\u00a075<\/strong>, 161304(R) (2007)<\/a>.\u00a0cond-mat\/0610089\u00a0<\/a>.<\/p>\n

18. External field control of donor electron exchange at the Si\/SiO2\u00a0interface.<\/strong>
\nM.J. Calder\u00f3n, Belita Koiller, and S. Das Sarma.
\nPhys. Rev. B\u00a075<\/strong>, 125311 (2007)<\/a>.\u00a0cond-mat\/0612093\u00a0<\/a>.<\/p>\n

17. Theory of carrier mediated ferromagnetism in dilute magnetic oxides<\/strong>.
\nM.J. Calder\u00f3n, S. Das Sarma.
\nAnnals of Physics\u00a0322<\/strong>, 2618 (2007)<\/a>.\u00a0cond-mat\/0603182\u00a0<\/a>.<\/p>\n

16. Mean-field theory for double perovskites: Coupling between itinerant electron spins and localized spins<\/strong>.
\nL. Brey, M.J. Calder\u00f3n, S. Das Sarma, and F. Guinea,
\nPhys. Rev. B\u00a074<\/strong>, 094429 (2006)<\/a>.\u00a0cond-mat\/0603143<\/a>.<\/p>\n

15. Magnetic field-assisted manipulation and entanglement of Si spin qubits<\/strong>.
\nM.J. Calder\u00f3n, Belita Koiller, and S. Das Sarma,
\nPhys. Rev. B\u00a074<\/strong>, 081302(R) (2006)<\/a>.\u00a0cond-mat\/0602597<\/a>.<\/p>\n

14. Exchange coupling in semiconductor nanostructures: Validity and limitations of the Heitler-London approach<\/strong>.
\nM.J. Calder\u00f3n, Belita Koiller, and S. Das Sarma,
\nPhys. Rev. B\u00a074<\/strong>, 045310 (2006)<\/a>.\u00a0cond-mat\/0512321<\/a>.<\/p>\n

13. Strain control of superlattice implies weak charge-lattice coupling in La0.5Ca0.5MnO3<\/strong>.
\nS. Cox, E. Rosten, J.C. Loudon, J.C. Chapman, S. Kos, M.J. Calder\u00f3n, D.J. Kang, P.B. Littlewood, P.A. Midgley, and N.D. Mathur,
\nPhys. Rev. B\u00a073<\/strong>, 132401 (2006)<\/a>.\u00a0cond-mat\/0504476<\/a>.<\/p>\n

12. Quantum control of donor electrons at the Si-SiO2\u00a0interface\u00a0<\/strong>.
\nM.J. Calder\u00f3n, Belita Koiller, Xuedong Hu and S. Das Sarma,
\nPhys. Rev. Lett.\u00a096<\/strong>, 096802 (2006)<\/a>.\u00a0cond-mat\/0508647<\/a>.<\/p>\n

11. Electronically soft phases in manganites<\/strong>.
\nG.C. Milward, M.J. Calder\u00f3n, and P.B. Littlewood,
\nNature\u00a0433<\/strong>, 607 (2005)<\/a>.\u00a0cond-mat\/0407727<\/a>.<\/p>\n

10. Evaluation of evidence for magnetic polarons in EuB6<\/strong>.
\nM.J. Calder\u00f3n, L.G.L. Wegener and P.B. Littlewood,
\nPhys. Rev. B\u00a070<\/strong>, 092408 (2004)<\/a>.\u00a0cond-mat\/0312437<\/a>.<\/p>\n

9. Strain selection of charge and orbital ordering patterns in half-doped manganites<\/strong>.
\nM.J. Calder\u00f3n, A.J. Millis and K.H. Ahn,
\nPhys. Rev. B\u00a068<\/strong>, 100401(R) (2003)<\/a>.\u00a0cond-mat\/0305440<\/a>.<\/p>\n

8. Impurity-Semiconductor band hybridization effects on the critical temperature of diluted magnetic semiconductors<\/strong>.
\nM.J. Calder\u00f3n, G. Gomez-Santos and L. Brey,
\nPhys. Rev. B\u00a066<\/strong>, 075218 (2002)<\/a>.\u00a0cond-mat\/0203404<\/a>.<\/p>\n

7. Low-temperature resistivity in double-exchange systems<\/strong>.
\nM.J. Calder\u00f3n and L. Brey,
\nPhys. Rev. B\u00a064<\/strong>, 140403(R) (2001)<\/a>.\u00a0cond-mat\/0010312<\/a><\/p>\n

6. Skyrmion strings and anomalous Hall effect in double-exchange systems.<\/strong>.
\nM.J. Calder\u00f3n and L. Brey,
\nPhys. Rev. B\u00a063<\/strong>, 054421 (2001)<\/a>.\u00a0cond-mat\/0001404<\/a><\/p>\n

5. Stability and dynamics of free magnetic polarons<\/strong>.
\nM.J. Calder\u00f3n, L. Brey and P.B. Littlewood,
\nPhys. Rev. B\u00a062<\/strong>, 3368 (2000)<\/a>.\u00a0cond-mat\/9911109<\/a><\/p>\n

4. Surface electronic structure and magnetic properties of doped manganites<\/strong>.
\nM.J. Calder\u00f3n, L. Brey and F. Guinea,
\nPhys. Rev. B\u00a060<\/strong>, 6698 (1999)<\/a>.\u00a0cond-mat\/9811337<\/a><\/p>\n

3. Conductance as a function of the temperature in the double exchange model<\/strong>.
\nM.J. Calder\u00f3n, J.A. Verg\u00e9s and L. Brey,
\nPhys. Rev. B\u00a059<\/strong>, 4170 (1999)<\/a>.\u00a0cond-mat\/9806157<\/a><\/p>\n

2. Monte Carlo Simulations for the Magnetic Phase Diagram of the Double Exchange Hamiltonian<\/strong>.
\nM.J. Calder\u00f3n and L. Brey,
\nPhys. Rev. B\u00a058<\/strong>, 3286 (1998)<\/a>.\u00a0cond-mat\/9801311<\/a><\/p>\n

1. Backscattering from perfectly reflective random media<\/strong>.
\nE.Bascones, M.J.Calder\u00f3n, D.Castelo, T.L\u00f3pez-Ciudad and J.J.S\u00e1enz,
\nPhys. Rev. B\u00a055<\/strong>, R11911 (1997)<\/a>.<\/p>\n

Other publications<\/h2>\n

Viewpoint: Ultrafast Phase Control in Oxide Thin Films<\/strong>
\nM.J. Calder\u00f3n
\nPhysics 5, 37 (2012)<\/a><\/p>\n

Quantum control of donor-bound electrons at the Si-SiO2\u00a0interface<\/strong>.
\nBelita\u00a0Koiller, M.J. Calder\u00f3n, X.\u00a0Hu\u00a0and S. Das\u00a0Sarma.
\nPHYSICS OF SEMICONDUCTORS: 28th International Conference on the Physics of Semiconductors – ICPS 2006.
\nAIP Conf. Proc.\u00a0893<\/strong>, 1095 (2007).<\/p>\n

Spin dependent tunneling<\/strong>.
\nF. Guinea, M.J. Calder\u00f3n and L. Brey, in\u00a0Spin electronics<\/em>, Eds. M. Ziese and M.J. Thornton. Springer-Verlag Berlin 2001.<\/p>\n

Magnetic properties of manganites<\/strong>.
\nM.J.Calder\u00f3n. Proceedings of the VIII Reunion de Fisica Estadistica. Anales de Fisica, Monografias RSEF Vol. X<\/p>\n

Dissipative quantum systems<\/strong>.\u00a0(pdf)\u00a0<\/a>
\nF. Guinea, E. Bascones, and M.J. Calder\u00f3n. Proceedings of\u00a0II training course in the physics of correlated systems and high Tc superconductors.<\/em>\u00a0IIASS. Vietri sul Mare (SA). Published by the American Institute of Physics, June 1998. Ed. F.Mancini.<\/p>\n

PhD Thesis<\/h2>\n

“Magnetic and electric properties of systems with colossal magnetoresistance”<\/a>. July 2001. Universidad Aut\u00f3noma de Madrid.<\/p>\n","protected":false},"excerpt":{"rendered":"

Mar\u00eda Jos\u00e9 Calder\u00f3n On the arXiv Google Scholar Researcher ID:\u00a0A-4888-2009 ORCID 71. Granular aluminum induced superconductivity in germanium for hole spin-based hybrid devices. Giorgio Fabris, Paul Falthansl-Scheinecker,\u00a0Devashish Shah,\u00a0Daniel Michel Pino,\u00a0Maksim Borovkov,\u00a0Anton Bubis,\u00a0Kevin Roux,\u00a0Dina Sokolova,\u00a0Alejandro Andres Juanes,\u00a0Tommaso Costanzo,\u00a0Inas Taha,\u00a0Aziz Gen\u00e7,\u00a0Jordi Arbiol,\u00a0Stefano Calcaterra,\u00a0Afonso De Cerdeira Oliveira,\u00a0Daniel Chrastina,\u00a0Giovanni Isella,\u00a0Ruben Seoane Souto,\u00a0Maria Jose Calderon,\u00a0Ramon Aguado,\u00a0Jose Carlos Abadillo-Uriel,\u00a0Georgios Katsaros. arXiv:2602.21364 … Continue reading Publications<\/span> →<\/span><\/a><\/p>\n","protected":false},"author":1,"featured_media":0,"parent":68,"menu_order":0,"comment_status":"closed","ping_status":"closed","template":"page-templates\/full-width.php","meta":{"footnotes":""},"class_list":["post-414","page","type-page","status-publish","hentry"],"_links":{"self":[{"href":"https:\/\/wp.icmm.csic.es\/tqe\/wp-json\/wp\/v2\/pages\/414","targetHints":{"allow":["GET"]}}],"collection":[{"href":"https:\/\/wp.icmm.csic.es\/tqe\/wp-json\/wp\/v2\/pages"}],"about":[{"href":"https:\/\/wp.icmm.csic.es\/tqe\/wp-json\/wp\/v2\/types\/page"}],"author":[{"embeddable":true,"href":"https:\/\/wp.icmm.csic.es\/tqe\/wp-json\/wp\/v2\/users\/1"}],"replies":[{"embeddable":true,"href":"https:\/\/wp.icmm.csic.es\/tqe\/wp-json\/wp\/v2\/comments?post=414"}],"version-history":[{"count":35,"href":"https:\/\/wp.icmm.csic.es\/tqe\/wp-json\/wp\/v2\/pages\/414\/revisions"}],"predecessor-version":[{"id":1860,"href":"https:\/\/wp.icmm.csic.es\/tqe\/wp-json\/wp\/v2\/pages\/414\/revisions\/1860"}],"up":[{"embeddable":true,"href":"https:\/\/wp.icmm.csic.es\/tqe\/wp-json\/wp\/v2\/pages\/68"}],"wp:attachment":[{"href":"https:\/\/wp.icmm.csic.es\/tqe\/wp-json\/wp\/v2\/media?parent=414"}],"curies":[{"name":"wp","href":"https:\/\/api.w.org\/{rel}","templated":true}]}}