ComputEEL/MatSci

Nat Commun 14, 5367 (2023)

SSC 283 (2018) 27

Nodeless time-reversal symmetry breaking in Sc5Co4Si10

PRM 6, 064802 (2022)

PRB 103, 125134 (2021)

σsc(T) data in field-cooling mode with fits using various gap models in HfV2Ga4

PRR 2 (2020) 022001(R)

Liquid Bi–Pb and Bi–Li alloys: Mining thermodynamic properties from ab-initio molecular dynamics calculations using thermodynamic models

Calphad 67 (2019) 101687

Calphad 67 (2019) 101676

Materialia 4 (2018) 529

HfV2Ga3 electronic density in (001) planes

PRB 98 (2018) 045126

Calphad 62 (2018) 42

ComputEEL/MatSci > Team > Prof. Gabrielle Weber Martins

Prof. Gabrielle Weber Martins

Theoretical collaborator

Scientific publications

Ferreira, P.P., Manesco, A.L.R., Dorini, T.T., Correa, L.E., Weber, G., Machado, A.J.S., & Eleno, L.T.F. (2021) Strain engineering the topological type-II Dirac semimetal NiTe_2. Phys. Rev. B, 103, 125134.

DOI: 10.1103/PhysRevB.103.125134

@article{Ferreira2021,
  author = "Ferreira, P. P. and Manesco, A. L. R. and Dorini, T. T. and Correa, L. E. and Weber, G. and Machado, A. J. S. and Eleno, L. T. F.",
  title = "Strain engineering the topological type-{II} {D}irac semimetal {NiTe}$_{2}$",
  journal = "Phys. Rev. B",
  year = "2021",
  volume = "103",
  number = "12",
  pages = "125134",
  computeel = "Eleno, Ferreira, Manesco, Dorini, Correa, Weber, Machado",
  doi = "10.1103/PhysRevB.103.125134"
}

Bhattacharyya, A., Ferreira, P.P., Panda, K., Masunaga, S.H., de Faria, L.R., Correa, L.E., Santos, F.B., Adroja, D.T., Yokoyama, K., Dorini, T.T., Jardim, R.F., Eleno, L.T.F., & Machado, A.J.S. (2021) Electron-phonon superconductivity in C-doped topological nodal-line semimetal Zr5Pt3: a muon spin rotation and relaxation (μSR) study. J. Phys.: Condens. Matter, 34, 035602.

DOI: 10.1088/1361-648x/ac2bc7

@article{Bhattacharyya2021,
  author = "Bhattacharyya, A. and Ferreira, P. P. and Panda, K. and Masunaga, S. H. and de Faria, L. R. and Correa, L. E. and Santos, F. B. and Adroja, D. T. and Yokoyama, K. and Dorini, T. T. and Jardim, R. F. and Eleno, L. T. F. and Machado, A. J. S.",
  title = "{Electron-phonon superconductivity in C-doped topological nodal-line semimetal Zr5Pt3: a muon spin rotation and relaxation ({$\mu$}SR) study}",
  journal = "J. Phys.: Condens. Matter",
  year = "2021",
  volume = "34",
  number = "3",
  pages = "035602",
  computeel = "Eleno, Ferreira, Dorini, Correa, Weber, Machado",
  doi = "10.1088/1361-648x/ac2bc7",
  publisher = "IOP Publishing"
}

Manesco, A.L.R., Lado, J.L., Ribeiro, E.V.S., Weber, G., & Jr, D.R. (2020) Correlations in the elastic Landau level of spontaneously buckled graphene. 2D Materials, 8, 015011.

DOI: 10.1088/2053-1583/abbc5f

@article{magnetism_buckled_graphene,
  doi = "10.1088/2053-1583/abbc5f",
  url = "https://doi.org/10.1088/2053-1583/abbc5f",
  year = "2020",
  month = oct,
  publisher = "{IOP} Publishing",
  volume = "8",
  number = "1",
  pages = "015011",
  author = "Manesco, A L R and Lado, J L and Ribeiro, E V S and Weber, G and Jr, D Rodrigues",
  title = "Correlations in the elastic Landau level of spontaneously buckled graphene",
  journal = "2D Materials",
  computeel = "Manesco, Weber"
}

Manesco, A.L.R., Weber, G., & Rodrigues, D. (2019) Effective model for Majorana modes in graphene. Phys. Rev. B, 100, 125411.

DOI: 10.1103/PhysRevB.100.125411

@article{1D_majoranas_graphene,
  author = "Manesco, A. L. R. and Weber, G. and Rodrigues, D.",
  title = "Effective model for {Majorana} modes in graphene",
  journal = "Phys. Rev. B",
  year = "2019",
  volume = "100",
  number = "12",
  pages = "125411",
  month = sep,
  computeel = "Manesco, Weber",
  doi = "10.1103/PhysRevB.100.125411",
  file = "APS Snapshot:/home/antonio/Zotero/storage/397JATKG/PhysRevB.100.html:text/html;Submitted Version:/home/antonio/Zotero/storage/GAYDUP4H/Manesco et al. - 2019 - Effective model for Majorana modes in graphene.pdf:application/pdf",
  url = "https://link.aps.org/doi/10.1103/PhysRevB.100.125411",
  urldate = "2020-05-03"
}

Rodrigues, D., Antunes, L.H.M., Manesco, A.L.R., Moraes, E.M., & da Silva, L.B.S. (2015) Development and Characterization of Cu–Nb–MgB2 and CuNi–Nb–MgB2 Wires With VB2 and Carbon Nanotube Additions. IEEE Trans. Appl. Supercond., 25, 1–5.

DOI: 10.1109/TASC.2014.2387698

@article{mgb2_wire,
  author = "Rodrigues, Durval and Antunes, Luiz H. M. and Manesco, Antonio L. R. and Moraes, Eduardo M. and da Silva, Lucas B. S.",
  title = "Development and {Characterization} of {Cu}–{Nb}–{MgB2} and {CuNi}–{Nb}–{MgB2} {Wires} {With} {VB2} and {Carbon} {Nanotube} {Additions}",
  journal = "IEEE Trans. Appl. Supercond.",
  year = "2015",
  volume = "25",
  number = "3",
  pages = "1--5",
  month = jun,
  issn = "1558-2515",
  computeel = "Manesco, Weber",
  doi = "10.1109/TASC.2014.2387698",
  file = "IEEE Xplore Abstract Record:/home/antonio/Zotero/storage/TPUJGL25/7001581.html:text/html",
  keywords = "carbon nanotube, carbon nanotubes, carbon sources, Carbon sources, characterization, copper, copper alloys, critical current density, critical current density (superconductivity), crystal microstructure, Cu-Nb-MgB2-VB2-C, CuNi-Nb-MgB2-VB2-C, deformation, diboride addition, diboride additions, flux pinning, Heat treatment, high critical temperature, high energy milling, high-energy milling, low flux pinning, magnesium compounds, mechanical deformation, MgB2, MgB2, superconducting wires, microhardness, microstructure, Multifilamentary superconductors, multifilamentary wires, nickel alloys, niobium, Niobium, phase distribution, pinning centers, powders, Powders, raw materials, secondary phases, superconducting critical field, Superconducting filaments and wires, superconducting tape, superconducting transition temperature, superconducting wires, Temperature measurement, type II superconductors, upper critical field, vanadium compounds, Wires"
}