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Rydberg-State Double-Well Potentials of Van der Waals Molecules (review) |
T. Urbańczyk, A. Kędziorski, M. Krośnicki, J. Koperski |
Molecules 29, 4657 |
2024 |
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Genetic algorithm for obtaining potential energy curve of diatomic molecules based on dispersed fluorescence spectra |
T. Urbańczyk, J. Koperski, G. Kaszewski, M. Synak, J. Swenda, M. Krośnicki |
Sci. Rep. 13, 17413 |
2023 |
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Application of Deep Neural Network in Finding of Repulsive Part of Molecular Potential Based on Dispersed Emission Spectra |
P. Gosz, M. Krośnicki, J. Koperski, T. Urbańczyk |
Acta Phys. Polon. A 141, 81-87 |
2022 |
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Optical-optical double resonance process in free-jet supersonic expansion of van der Waals molecules: characteristics of the expansion, number of excited molecules and emitted photons |
J. Sobczuk, T. Urbańczyk, J. Koperski |
Mol. Phys. 120, e2024614 |
2022 |
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Rydberg states of ZnAr complex |
A. Kędziorski, P. Zobel, M. Krośnicki, J. Koperski |
Mol. Phys. 120, e2073282 |
2022 |
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Two-color laser scattering for diagnostics of hydrogen plasma |
F. Sobczuk, K. Dzierżęga, W. Zawadzki, B. Pokrzywka, E. Stambulchik |
Plasma Sources Sci. Technol. 31, 115012 |
2022 |
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The lowest-lying Rydberg state of CdAr van der Waals complex: The improved characterization of the interatomic potential |
J. Sobczuk, T. Urbańczyk, J. Koperski |
Spectrochimica Acta A: Mol. Biomol. Spectrosc. 282, 121655 |
2022 |
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Rotational characterization of the E3Σ1+(5s6s 3S1) Rydberg state of CdNe van der Waals complex via selective J-excitation in OODR process |
Tomasz Urbańczyk, Joanna Sobczuk, Jarosław Koperski |
Spectrochimica Acta A: Mol. Biomol. Spectrosc., 264, 120248 |
2022 |
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Zero- to Ultralow-Field NMR Spectroscopy of Small Biomolecules |
Piotr Put, Szymon Pustelny, Dmitry Budker, Emanuel Druga, Tobias F. Sjolander, Alexander Pines, and Danila A. Barskiy |
Anal. Chem. 93, 6, 3226–3232 |
2021 |
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Zero-Field NMR J-Spectroscopy of Organophosphorus Compounds |
S. Alcicek, P. Put, V. Kontul, S. Pustelny |
J. Phys. Chem. Lett. 2021, 12, 2, 787–79 |
2021 |
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Deep neural network for fitting analytical potential energy curve of diatomic molecules from ro-vibrational spectra |
D. Horwat, M. Krośnicki, T. Urbańczyk, J. Koperski |
Molecular Simulation 47, 650 |
2021 |
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Observation of gerade Rydberg state of Cd2 van der Waals complex cooled in free-jet expansion beam and excited using optical-optical double resonance method |
T. Urbańczyk, M. Krośnicki and J. Koperski |
Spectrochimica Acta A: Mol. Biomol. Spectrosc., 253, 119500 |
2021 |
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Bound->free and bound->bound multichannel emission spectra from selectively excited Rydberg states in the ZnAr and CdAr van der Waals complexes |
J. Dudek, A. Kędziorski, J.P. Zobel, M. Krośnicki, T. Urbańczyk, K. Puczka, J. Koperski |
Journal of Molecular Structure, 1222, 128840 |
2020 |
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Ro-vibrational cooling of diatomic molecules Cd2 and Yb2: rotational energy structure included |
T. Urbańczyk, J. Koperski |
Molecular Physics 118, e1694712 |
2020 |
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Genetic Algorithm for quick finding of diatomic molecule potential parameters |
T. Urbańczyk, J. Koperski |
Molecular Simulation 46, 1073 |
2020 |
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Spectroscopy of CdKr van der Waals complex using OODR process: New determination of the E3Σ+1(5s6s 3S1) Rydberg state potential |
T. Urbańczyk , J. Koperski |
Chem. Phys. 525, 110406 |
2019 |
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Rydberg states of the CdAr van der Waals complex |
M. Krośnicki, A. Kędziorski, T. Urbańczyk, J. Koperski |
Phys. Rev. A, 99, 052510 |
2019 |
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High-temperature continuous molecular beam source for aggressive elements: An example of zinc |
J. Dudek, K. Puczka, T. Urbańczyk, J. Koperski |
Rev. Sci. Instrum. 90, 115109 |
2019 |
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Isotopologue-selective excitation studied via optical-optical double resonance using the E3Σ1+(63S1)←A3Π0+(53P1)←X1Σ0+(51S0) transitions in CdAr and CdKr van der Waals complexes |
T. Urbańczyk, J. Dudek, J. Koperski |
J. Quant. Spectrosc. Radiat. Transf. 212, 32 |
2018 |
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Exploration of molecular ro-vibrational energy structure: on the perspective of Yb2 and Cd2 internal cooling, and 171Yb-version of Einstein-Podolsky-Rosen experiment |
T. Urbańczyk, M. Strojecki, J. Koperski |
Mol. Phys. 116, 3475 |
2018 |
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Neural networks and determination of diatomic molecule interatomic potential of cadmium dimer |
T. Urbańczyk, J. Koperski |
Spectrochim. Acta A: Mol. Biomol. Spectrosc. 189, 502 |
2018 |
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The E3Σ1+(63S1) ← A3Π0(53P1) transition in CdAr revisited: The spectrum and new analysis of the E3Σ1+ Rydberg state interatomic potential |
T. Urbańczyk, M. Krośnicki, A. Kędziorski, J. Koperski |
Spectrochim. Acta A: Mol. Biomol. Spectrosc. 196, 58 |
2018 |
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Interatomic potentials of metal dimers: probing agreement between experiment and advanced ab initio calculations for van der Waals dimer Cd2 |
T. Urbańczyk, M. Strojecki, M. Krośnicki, A. Kędziorski, P.S. Żuchowski, J. Koperski |
Int. Rev. Phys. Chem. 36, 541 |
2017 |
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The ambiguity in determination of interatomic potential of diatomic molecule |
T. Urbańczyk, J. Koperski, A. Pashov |
J. Phys. Conf. Series 810, 012041 |
2017 |
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Interatomic potentials of van der Waals dimers Hg2 and Cd2: Probing discrepancies between theory and experiment |
T. Urbańczyk, M. Krośnicki, M. Strojecki, A. Pashov, A. Kędziorski, P. Żuchowski, J. Koperski |
J. Phys. Conf. Series, 810, 012018 |
2017 |
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Rotational profiles in the excitation spectrum recorded for the B31(53P1)←X10+(51S0) transition in CdNe van der Waals complex |
T. Urbańczyk, J. Koperski |
Chem. Phys. Lett. 644, 231-234 |
2016 |
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Determination of interatomic potentials for diatomic molecules from low resolution spectra |
T. Urbanczyk, J. Koperski and A. Pashov |
J. Mol. Spectrosc. 330, 165 |
2016 |
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The E3Σ+(63S1)-state interatomic potential of CdAr in the long range region revisited: a new method for bond length adjustment |
T. Urbańczyk, J. Koperski |
Chem. Phys. Lett. 640, 82-86 |
2015 |
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Interatomic potentials of the heavy van der Waals dimer Hg2: A ‘‘test-bed’’ for theory-to-experiment agreement |
M. Krośnicki, M. Strojecki, T. Urbańczyk, A. Pashov, J. Koperski |
Phys. Reports 591, 1-31 |
2015 |
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Free←bound and bound←bound profiles in excitation spectra of the B31(53P1)←X10+(51S0) transition in CdNg (Ng=noble gas) complexes |
J. Koperski, T. Urbańczyk, M. Krośnicki and M. Strojecki |
Chem. Phys. 428, 43 |
2014 |
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Rotational profiles of vibrational bands recorded at the B31(53P1)←X10+(51S0) transition in CdAr complex |
T. Urbańczyk and J. Koperski |
Chem. Phys. Lett. 591, 64 |
2014 |
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Profiles of (υ′;υ″=0) bands recorded in excitation spectra using b30+u ←X10+g transition in Cd2 and B31←X10+ transitions in CdAr |
T. Urbańczyk and J. Koperski |
Mol. Phys. 112, 2486 |
2014 |
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Pulsed supersonic source of vdW complexes for high-temperature applications: Spectroscopy and beam characteristics |
T. Urbańczyk and J. Koperski |
Eur. Phys. J. Special Topics (Advances in Atomic and Molecular Spectroscopy), 222, 2187 |
2013 |
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From molecular spectroscopy to entanglement of atoms – a trek with supersonic velocity |
J. Koperski |
Opt. Appl. 42, 417-431 |
2012 |
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Structure of vibrational bands of the E3Σ+(63S1)←A3(53P1), B3Σ+1(53P1) transitions in CdAr and CdKr studied by optical-optical double resonance method. |
T. Urbańczyk, M. Strojecki and J. Koperski |
Chem. Phys. Lett. 503, 18 |
2011 |
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Potentials of the D10u+(61S0) and F31u(63P2) electronic Rydberg states of Cd2 from ab initio calculations and LIF excitation spectra |
J. Koperski, M. Strojecki, M. Krośnicki and T. Urbańczyk |
J. Phys. Chem. A 115, 6851 |
2011 |
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Characterization of bound parts of the b30u+(53P1), c31u(53P2) and X10g+ states of Cd2 revisited: bound-bound excitation and dispersed emission spectra |
M. Strojecki, M. Krośnicki, P. Zgoda and J. Koperski |
Chem. Phys. Lett. 489, 20 |
2010 |
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Excitation spectra of Cd-rare gas complexes recorded at the D1Σ0+←X1Σ0+ transition: from the heaviest CdXe to the lightest CdHe |
M. Strojecki, M. Krośnicki, M. Łukomski and J. Koperski |
Chem. Phys. Lett. 471, 29 |
2009 |
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LIF dispersed emission spectra and characterization of ZnRg (Rg=Ne, Ar, Kr) ground-state potentials |
M. Strojecki and J. Koperski |
Chem. Phys. Lett. 479, 189 |
2009 |
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Repulsive and bound parts of the interatomic potentials of the lowest singlet electronic energy states of the MeRg complexes (Me=Zn, Cd; Rg=He, Ne, Ar, Kr, Xe) |
M. Strojecki, M. Krośnicki and J. Koperski |
J. Mol. Spectrosc. 256, 128 |
2009 |
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Potential energy curves for the B11u state and short-range part of the X10g+ state of Cd2 determined from excitation and dispersed fluorescence spectra recorded using the B11u↔X10g+ transition |
M. Ruszczak, M. Strojecki, M. Łukomski, and J. Koperski |
J. Phys. B: At. Mol. Opt. Phys. 41, 245101 |
2008 |
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Group-12 vdW dimers in free-jet supersonic beams - the legacy of Eugeniusz Czuchaj continues |
J. Koperski |
Eur. Phys. J. 144, 107-114 |
2007 |
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Molecules in the cold environment of a supersonic free-jet beam: from spectroscopy of neutral-neutral interactions to test of Bell's inequality |
J. Koperski, E.S. Fry |
J. Phys. B: At. Mol. Opt. Phys. 39, S1125-50 |
2006 |
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Van der Waals Complexes in Supersonic Beams. Laser Spectroscopy of Neutral-Neutral Interactions |
J. Koperski |
book, Wiley-VCH, Weinheim, 2003, 237 pp. |
2003 |
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Study of diatomic van der Waals complexes in supersonic beams |
J. Koperski |
Physics Reports 369, 177-326 |
2002 |
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