Publications

Wlodzimierz Jaskolski

1. PhD Thesis
   Metody quasirelatywistyczne w teorii elastycznego rozpraszania elektonow i pozytonow na atomach

 

2. Original papers
1. J. Karwowski, J. Styszynski, and W. Jaskolski,
   Cross terms between correlation and relativistic effects in closed-shell atoms,
   Proceedings of 6th Seminar on Computational Methods in Quantum Chemistry, Garching 1984, Ed. by W.E. Kraemer
2. W. Jaskolski,
   Relativistic effects in the elastic scattering of slow electrons by heavy atoms,
   Acta Phys. Polon. A67 (1985) 815-821
3. W. Jaskolski and J. Karwowski,
   Quasi-relativistic approach to low-energy electron scattering from closed-shell atoms,
   J. Phys. B 19 (1986) 1093-1105
4. J. Kobus, J. Karwowski, and W. Jaskolski,
   Matrix elements of r^q for quasirelativistic and Dirac hydrogenic wavefunctions,
   J. Phys. A 20 (1987) 3347-3352
5. W. Jaskolski, J. Karwowski, and J. Kobus,
   Quasirelativistic calculations of the Elastic Scattering of Slow Electrons from Xe Atoms,
   Physica Scripta 36 (1987) 436-440
6. J. Kobus and W. Jaskolski,
   Numerical comparison between DHF and RHF methods,
   J. Phys. B 20 (1987) 4949-4961
7. J. Karwowski, W. Jaskolski, and J. Kobus,
   Comment on "A Comparison of Relativistic and Quasirelativistic Line Strengths" by A.K. Mohanty and D.H. Sampson,
   Physica Scripta 38 (1988) 554-556
8. W. Jaskolski,
   Quasirelativistic approach to many-channel electron scattering from atoms
   J. Phys. B 22 (1989) 3275-3287
9. W. Jaskolski, J. Karwowski, and J. Kobus,
   A remark on the outward integration procedure fro quasirelativistic radial equations,
   Acta Phys. Polon. A78 (1990) 693-695
10. W. Jaskolski, V.R. Velasco, and F. Garcia-Moliner
    Practical Use of Transfer Martix for Matching calculations,
    Physica Scripta 42 (1990) 495-500
11. W. Jaskolski, V.R. Velasco, and F. Garcia-Moliner
    Electronic States in a Metallic Quantum Well,
    Physica Scripta 43 (1990) 337-339
12. M.L. Glasser, W. Jaskolski, F. Garcia-Moliner, and V.R. Velasco
    Quasibound states in an electric field,
    Phys. Rev.B 42 (1990) 7630-7632
13. W. Jaskolski,
    Matching formalism for surface states and surface resonances,
    Phys. Rev. B 45 (1992) 4398-4402
14. L. Chico, W. Jaskolski, and F. Garcia-Moliner
    The Confined Electron Gas in Modulation Doped Quantum Wells,
    Physica scripta 47 (1993) 284-288
15. L. Chico, W. Jaskolski, and V.R. Velasco
    On the electronic structure of externally delta-doped quantum wells,
    Czech. J. Phys. 43 (1993) 893-898
16. L. Chico, W. Jaskolski, R. Perez-Alvarez, and F. Garcia-Moliner
    On the theory of GaAs-based Quantum wells with external delta-doping,
    J. Phys. C 5 (1993) 9069-9076
17. W. Jaskolski,
    Multiband approach to surface resonances,
    Vacuum (Pergamon Press) 45 (1994) 183-185
18. M. Steslicka, R. Kucharczyk, L. Dobrzynski, B. Djafari-Rouhani, E.-H. El Boudouti, and W. Jaskolski,
    Prog. Surf. Sci. 46 (1994) 219-223
19. C. Zicovich-Wilson, J. Planelles, and W. Jaskolski,
    Spatially Confined Simple Quantum Mechanical Systems,
    Intern. J. Quantum Chem. 50 (1994) 429-444.
20. M. Grinberg, W. Jaskolski, Cz. Koepke, J. Planelles, and M. Janowicz,
    Spectroscopic manifestation of a confinement-type lattice anharmonicity,
    Phys. Rev. B 50 (1994) 6504-6507.
21. C. Zicovich-Wilson, W. Jaskolski, and J. Planelles,
    Atoms and molecules in cavities: a method for study of spatial confinement effects,
    Intern. J. Quantum Chem. 54 (1995) 61-72.
22. M. Grinberg, W. Jaskolski, Cz. Koepke, J. Planelles, and M. Janowicz,
    Manifestation of a confinement-type anharmonicity in emission spectra of Niobate glass,
    Radiation Effects and Defects in Solids, 136 (1995) 141-144.
23. W. Jaskolski,
    Confined many-electron systems,
    Physisc Reports, 271 (1996) 1-66.
24. J. Planelles, C. Zicovich-Wilson, W. Jaskolski, and A. Corma,
    Semiempirical hamiltonians for spatially confined pi-electron systems,
    Int. J. Quantum Chem., 60 (1996) 971-981. 

Papers published after D.Sc. thesis

25. F. Rajadell, J. Planelles, W. Jaskolski, and C. Zicovich-Wilson,
    Selection of basis sets for atoms and molecules in cavities,
    Int. J. Quantum Chem., 60 (1996) 993-999.
26. M. Bylicki, W. Jaskolski, and R. Oszwaldowski,
    Resonant tunnelling in multi-barrier structures - complex rotation approach,
    J. Phys. Condens. Matter 8 (1996) 6393-6403.
27. W. Jaskolski and M. Bylicki,
    Resonant tunnelling in quantum dots - complex coordinate approach,
    Vacuum, 48 (1997) 235-239.
28. M. Bylicki, W. Jaskolski, and R. Oszwaldowski,
    Resonant tunnelling in non-symmetrical double barrier structures - complex coordinate approach,
    Czech. J. Phys. 47, 1997 373-378
29. M. Grinberg and W. Jaskolski,
    Influence of a confinement-type lattice anharmonicity on the non-radiative processes in solids,
    Phys. Rev. B 55, 1997 5581-5584
30. M.Grinberg, W. Jaskolski, P.J. Macfarlane, and K. Holliday,
    The influence of substitutionaldisorder on non-radiative transitions in Cr3+ doped gallogermanate crystals
    J. Phys. Condens. Matter, 9, 1997 2815-2829
31. M. Grinberg, W. Jaskolski, P. Macfarlane, B. Handerson and K. Holliday
    Cryastal field distribution of non-radiative transitions in Cr3+ dopped gallogermanates
    J. Luminescence 72-74, 1997 193-194
32. W. Jaskolski and Garnett W. Bryant,
    Multiband theory of quantum dots-quantum wells,
    Phys. Rev. B 57, 1998, R4237
33. U. Banin, J.C. Lee, A.A. Guzelian, A.V. Kadavanish, A.P. Alivisatos, W. Jaskolski, G.W. Bryant, Al. L. Efros, M.Rosen,
    Size dependent electronic level structure of narrow gapsemiconductor nanocrystals: InAs quantum dots,
    J. Chem. Phys. 109, 1998, 2306
34. R. Oszwaldowski and W. Jaskolski,
    Infrared absorption of multiple quantum wells: bound to continuum transitions
    Acta Phys. Polon. 94, 1998, 473
35. M. Bylicki and W. Jaskolski,
    Resonance spectra of quantum dots in magnetic field
    Acta Phys. Polon. 94, 1998, 271
36. W. Jaskolski, J. Planelles, and G. Peris,
    Shape-generated blue-shift in the photoluminescence spectra of hemispherical nanocrystals,
    Physica E, 4, 1999, 176
37. J. Planelles, J. Karwowski, and W. Jaskolski,
    Adaptation of One-Electron Basis Set to Spatial Confinements
    International J. Quantum. Chem, 73, 1999, 341
38. M.Grinberg, I.Skolska, S.Kuck, and W.Jaskolski,
    Analysis of the temperature emision quenching of the Cr3+ ions
    in LiTaO3 crystal on the framework of confined potential model,
    Phys. Rev. B 60 (1999) 8595-8601
39. G.W. Bryant, W. Jaskolski, and S.E. Burke,
    Quantum-Dot Quantum-Well Heteronanostructures: Multiband and Tight-binding Theory,
    Proceedings of the 24th International Conference on the Physics of Semiconductors, (World Scientific, Singapore, 1999).
40. W. Jaskolski and Garnett W. Bryant,
    Excitons in quantum-dot quantum well structures
    In "High Technology of the NATO Sciences Series", Kluver 2000
41. M. Bylicki and W. Jaskolski,
    Binding of resonance states in a magnetic field
    Phys. Rev. B. 60 (1999) 15924
42. W.Jaskolski, R.Oszwaldowski and G.W.Bryant,
    On boundary condition-induced states in low-dimensional
    semiconductor structures
    Vacuum 63 (2001) 191
43. G.W. Bryant and W. Jaskolski,
    Designing Nanocrystal Nanosystems: Quantum-dot quantum wells to quantumdot solids,
    physica status solidi 224, 751 (2001)
44. W.Jaskolski, M.Bosek, M.Bylicki,J.Planelles,
    Resonant states of quantum dots with donor impurity center in a magnetic field,
    Vacuum 63 (2001) 185
45. G.W. Bryant and W. Jaskolski,
    Designing quantum dots and quantum- dot solids
    Physica E 11, 72 (2001)
46. J. Planelles, W. Jaskolski, J.I. Aliaga
    Energy structure of quantum rings in a magnetic field
    Phys. Rev. B. 65, 033306 (2001)

Papers published after professorship

47. G.W. Bryant, W. Jaskolski
    Electronic structure of quantum-dot molecules and solids
    Physica E 13, 293 (2002)
48. W.Jaskolski, G.W. Bryant, J. Planelles, M. Zielinski,
    Artificial Molecules
    Int. J. Quantum Chem. 90, 1075, 2002
49. R. Xie, G.W. Bryant, S. Lee, and W. Jaskolski
    Electron-hole correlations and optical gaps in quantum dot quantum wells: tight-binding approach
    Phys. Rev. B 65, 235306, 2002
50. J. Planelles, J. Diaz, I. Climente, W. Jaskolski
    Multilayer nanocrystals in a magnetic field
    Phys. Rev. B 65, 245302, 2002
51. J. S. Sims, W. L. George, S. G. Satterfield, H. K. Hung, J. G. Hagedorn, P. M. Ketcham, T. J. Griffin, S. A. Hagstrom, J. C. Franiatte, G. W. Bryant, W. Jaskolski, N. S. Martys, C. E. Bouldin, V. Simmons, O. P. Nicolas, J. A. Warren, B. A. am Ende, J. E. Koontz, B. J. Filla, V. G. Pourprix, S. R. Copley, R. B. Bohn, A. P. Peskin, Y. M. Parker and J. E. Devaney
    Accelerating scientific discovery through computation and visualization II
    NIST Research Journal 107,223, 2002
52. A Thränhardt, C Ell, G Khitrova, HM Gibbs, SW Koch, MA Lieb, A Drechsler, C Debus, AJ Meixner, S Longhi, Eugenia D Eugenieva, Demetrios N Christodoulides, Nikos K Efremidis, Suzanne Sears, Mordechai Segev, CAC Bosco, GS Maciel, Cid B de Araújo, LH Acioli, AM Simas, Ming-Feng Shih, Chien-Chung Jeng, Fan-Wen Sheu, Chao-Yin Lin, R Delgado-Macuil, MD Iturbe-Castillo, I Gur-Arie, A Shoham, S Bar-Ad, RJ Delgado Macuil, S Chávez Cerda, MD Iturbe Castillo, J Aizpurua, R Xie, GW Bryant, W Jaskolski, MV Fedorov, ME Sukharev, Kenichi Ishikawa, Hiroshi Kumagai, Katsumi Midorikawa, S Eden, T Löffler, M Thomson, HG Roskos, YS Lee, TB Norris, Kenichiro Tanaka, Fumiaki Sano, Takayuki Takahashi, Takashi Kondo, Eugeniy E Mikhailov, Yuri V Rostovtsev, George R Welch, Jen-Hao Cheng, Min Yan, Edward Rickey, Yifu Zhu, Sergey Polyakov, Roman Malendevich, Ladislav Jankovic, George Stegeman, Christian Bosshard, Peter Gunter

Dipole moment in radiative broadening of interface fluctuation quantum dots

OSA Trends in Optics and Photonics (TOPS), 74, 129-130, 2002

53. W. Jaskolski, M. Zielinski and G.W. Bryant
    Electronic properties of quantum-dot molecules
    Physica E 17, 40 (2003)
54. J. Planelles, J. Diaz, I. Climente, W. Jaskolski
    Hole energy structure of multilayer nanocrystals in a magnetic field
    J. Phys.: Condens. Matter 14, 1 (2002)
55. J. Planelles and W. Jaskolski
    kp Hamiltonians for quantum dots in a magnetic field
    J.Phys.: Condens. Matter 15, L67 (2003)
56. G. W. Bryant and W. Jaskolski
    Tight-binding theory of quantum-dot quantum wells: Single particle effects and near band-edge structure
    Phys. Rev. B 67, 205320, 2003
57. G.W. Bryant, J. Aizpurua, W. JAskolski, M. Zielinski
    Tunnel-Coupled Quantum Dots: Atomistic Theory of Quantum Dot Molecules and Arrays
    Mat. Res. Soc. Symp. Proc. 737, E1.2.1, 2003
58. J. Planelles, J. Diaz, I. Climente, W. Jaskolski
    Maggnetotransitions in multilayer nanocrystals
    J. Phys.:Cond. Matter, 15, 3593, 2003
59. J. Climente, J. Planelles, W. Jaskolski
    Magnetooptical transitions in nanoscopic rings
    Phys. Rev. B 68, 075307, 2003
60. J. Diaz, W. Jaskolski, J. Planelles, and G.W. Bryant
    Nanocrystal molecules and chains
    J. Chem. Phys. 119, 7484, 2003
61. J. Aizpurua, G.W. Bryant, W. Jaskolski
    Atomistic description of the electronic structure of T-shaped quantum wires
    Microele. Journal 34, 603 (2003)
62. L. Chico and W. Jaskolski
    Localized states and conductance gaps in metallic carbon nanotubes
    Phys. Rev. B 69, 085406, 2004
63. L. Chico and W. Jaskolski
    Localized states in metallic carbon nanotubes
    Microel. Journal 35, 3, 2004
64. A. Strozecka, W. Jaskolski, M. Zielinski, G.W. Bryant
    Stark effect in semiconductor nanocrystals: Tight-binding approach.
    Vacuum 74, 259 2004
65. W. Jaskolski, M. Zielinski, and G.W. Bryant,
    Coupling and strain effects in vertically stacked double InAs/GaAs quantum dots: tight-binding approach
    Acta Phys. Polon. A 106, 193, 2004
66. G.W. Bryant,W. Jaskolski,
    Surface states in passivated, unpassivated and core/shell nanocrystals: electronic structure and optical properties.
    Quantum Dots, Nanoparticles and Nanowires Symposium (Mater. Res. Soc. Symposium Proceedings Vol.789). Mater. Res. Soc. 2004, pp.319-24.
67. L. Chico, W. Jaskolski, M.P. Lopez-Sancho, M.C.Munoz
    Quantum confinement in carbon nanotube systems
    Int. J. Nanotechnology, 2, 103, 2005
68. W. Jaskolski, M. Zielinski, A. Strozecka, G.W. Bryant, J. Aizpurua
    Quantum dot molecules and chains
    in "Quantum Dots: Fundamentals, Applications and Frontiers", 257,
    NATO SCIENCE SERIES II.190
    Springer, 2005
69. W. Jaskolski and L.Chico,
    Localized and conducting states in carbon nanotube superlattices
    Phys. Rev. B 71, 155405, 2005
70. W. Jaskolski, A. Stachow, L.Chico
    Band sructure and quantum conductance of metallic carbon nanotube superlattices
    Acta Phys. Pol. 108, 697, 2005
71. M. Zielinski, W. Jaskolski, J. Aizpurua, G.W. Bryant
    Strain and spin-orbit effects in self assembled quantum dots
    Acta Phys. Pol. 108, 929, 2005
72. W. Jaskolski, M.Bylicki, J. Diaz, A. Stachow
    Resonance states of two-lectron quantum dots.
    Phys. Rev. B 72, 075434, 2005
73. G.W. Bryant, W. Jaskolski
    Surface effects on capped and uncapped nanocrystals
    J. Phys. Chem. B 109, 19650, 2005
74. J. Planelles, J. Movilla, and W. Jaskolsi
    From independent particles to Wigner crystalization: The effect of dielectric confinement
    Phys. Rev. B 73, 35305, 2006
75. W. Jaskolsi, L. Chico
    Symmetry and structural properties of of carbon nanotube quantum dots and superlattices
    J. Phys.: Conference Series, 30, 230, 2006
76. J. Diaz, G.W. Bryant and W. Jaskolski
    Optical fine structure of II-VI and III-V nanocrystals: the role of d orbitals in a tight-binding approach
    phys. stat. sol. (c) 3, 3823, 2006
77. J. Diaz, W. Jaskolski, M. Zielinski and G.W. Bryant
    Pressure-induced optoelectronic properties of InP nanocrystals: Tight-binding approach
    phys. stat. sol. (c) 3, 3832, 2006
78. J. Diaz, M. Zielinski, W. Jaskolski, G.W. Bryant
    Tight-binding theory of ZnS/CdS nanoheterostructures. The role of strain and d orbitals
    Phys. Rev. B 74, 205309, 2006
79. W. Jaskolski, M. Zielinski, G.W. Bryant, J. Aizpurua
    Strain effects on the electronic structure of strongly coupled self-assembled InAs/GaAs quantum dots: Tight-binding approach
    Phys. Rev. B 74, 195339, 2006
80. J. Diaz, G.W. Bryant, W. Jaskolski
    Theory of InP nanocrystals under pressure
    Phys. Rev. B 76, 245433, 2007
81. M. Pelc and W. Jaskolski

Carbon nanotube superlattices in a magnetic field

Int. J. Quant. Chem. 108, 2261, 2008

82. A. Ayuela, L. Chico, W. Jaskolskii

Electronic band structure of carbon nanotube superlattices from first-principles calculations

Phys. Rev. B 77, 085435, 2008

83. L. Chico, A. Ayuela, M. Pelc, H. Santos and W. Jaskolski

Friedel oscillations in carbon nanotube quantum dots and superlattices

Acta Phys. Pol, 114, 1085, 2008

84. A. Ayuela, W. Jaskolski, M. Pelc, H. Santos and L. Chico,

Friedel-like oscillations in carbon nanotube quantum dots

Appl. Phys. Lett. 93, 133106, 2008

85. H. Santos, A. Ayuela, W. Jaskolski, M. Pelc, and L. Chico

Interface states in carbon nanotube junctions: Rolling up graphene.

Phys. Rev. B, 035436, 2009

86. W. Jaskolski, M. Pelc, H. Santos, L. Chico, and A. Ayuela

Interface bands in carbon nanotube superlattices.

phys. stat. sol. c7, 382, 2010

87.  L.Chico, H.Santos, A.Ayuela, W.Jaskolski, M.Pelc, and L.Brey

Unzipped and defective nanotubes: rolling up grapheme and unrolling tubes

accepted to Acta. Phys. Pol. 2009

88. G. W. Bryant, M. Zielinski, N. Malkova, J. Sims,W. Jaskolski, J. Aizpurua,

Effect of mechanical strain on the optical properties of quantum dots:Controlling exciton shape, orientation, and phase with a mechanical strain

Phys. Rev. Lett. 105, 067404, 2010   

89.  L. Chico, H. Santos, A. Ayuela, W. Jaskolski, M. Pelc, L. Brey,

Unzipped and defective nanotubes: rolling up grapheme and unrolling tubes

Acta Phys. Pol. A  118  (2010); 433 – 441

90.  W. Jaskolski, Andres Ayuela, M. Pelc, Hernan Santos, Leonor Chico,
Edge states and flat bands in graphene nanoribbons with arbitrary geometries
Phys. Rev. B.  83  (2011); 235424 – 235429

91.   G. W. Bryant, M. Zieliński, N. Malkova, J. Sims, W. Jaskolski, J. Aizpurua,
Controlling the optics of quantum dots with nanomechanical strain
Phys. Rev. B.  84  (2011); 235412 – 235425

92.  W. Jaskolski, M. Pelc, Leonor Chico, Andres Ayuela,
Octagonal defect lines in graphene structures
IEEE Conference on Nanotechnology  1  (2012); 1 – 5

93.   W. Jaskolski, M. Pelc, A. Ayuela, L. Chico,
Octagonal defects at carbon nanotube junctions
ScientificWorldJournal  2013  (2013); 1 – 7

94.  M. Pelc, W. Jaskolski, Andres Ayuela, Leonor Chico,
Octagonal defects as the source of gap states in graphene semiconductor structures
Acta Phys. Pol. A  124  (2013); 777 – 780

95.  M. Pelc, Leonor Chico, Andres Ayuela, W. Jaskolski,
Grain boundaries with octagonal defects in graphene nanoribbons and nanotubes
Phys. Rev. B.  87  (2013); 165427-1 - 165427-7

96.  W. Jaskolski, Andres Ayuela,
Coulomb edge effects in graphene nanoribbons
Solid State Commun.  196  (2014); 1 – 7

97.  A. Ayuela, W. Jaskolski, H. Santos, L. Chico,
Electronic properties of graphene grain boundaries
New J. Phys.  16  (2014); 083018-1 - 083018-10

98.  W. Jaskolski, L. Chico, A. Ayuela,
Divacancy-induced ferromagnetism in graphene nanoribbons
Phys. Rev. B.  91  (2015); 165427 – 165432

99.   M. Pelc, W. Jaskolski, A. Ayuela, L. Chico,
Topologically confined states at corrugations of gated bilayer graphene
Phys. Rev. B.  92  (2015); 085433 - 085433-8

100.                  W. Jaskolski, M. Pelc, L. Chico, and A. Ayuela

Existence of nontrivial topologically protected states at grain boundaries in bilayer graphene: signatures and electrical switching 

Nanoscale 8, (2016) 6097 , DOI: 10.1039/c5nr08630b

101.                  W.Jaskolski, M. Pelc, G.W. Bryant, L. Chico, A. Ayuela

Controlling the layer localization of gapless states in bilayer Graphene with a gate voltage,

2D Materials, 5 (2018) 025006

102.                  W. Jaskolski,

Single-layer graphene with electronic properties of a gated bilayer,

Phys. Rev. B 100 (2019) 035436

103.                  W. Jaskolski and A. Ayuela,

Spin-layer Locked Gapless States in Gated Bilayer Graphene

RSC Advances, 9 (2019) 42140

104.                  W. Jaskolski and G. Sarbicki,

Topologically protected gap states and resonances in gated trilayer graphene,

Phys. Rev. B 102 (2020) 035424

105.                  W. Jaskolski

Electronic Structure of trilayer graphene with internal layer broken

Mol. Phys. e2013554 (2022)

106.                  W. Jaskolski

Gapless states and current control in strongly distorted gated trilayer graphene

Solid State Communications 360 (2023) 115043

107.                  W. Jaskolski,

Controlling spin polarization of gapless states in defected trilayer graphene with a gate voltage

Physica E: Low-dimensional Systems and Nanostructures, 157 (2024) 115878

108.                  W. Jaskolski

Metal-semiconductor behavior along the line of stacking order change in gated multilayer graphene,

Materials, 17 (2024) 1915

109.                  W. Jaskolski

Electric field-defined superlattices in bilayer graphene: formation of topological bands in two dimensions

Materials, 18 (2025) 1521