Search: karman

1. Scheme for Deterministic Loading of Laser-Cooled Molecules into Optical Tweezers
   Etienne F. Walraven, Michael R. Tarbutt, and Tijs Karman
   Phys. Rev. Lett., 132, 183401 (2024)  [doi]  [pdf]
2. Rotational-state dependence of interactions between polar molecules
   Etienne F. Walraven and Tijs Karman
   Phys. Rev. A, 109, 043310 (2024)  [doi]  [pdf]
3. Ultracold chemistry as a testbed for few-body physics
   Tijs Karman, Michał Tomza, and Jesús Pérez-Rios
   Nature Phys., 20, 722 (2024)  [crossref]
4. Quantum state-resolved molecular dipolar collisions over four decades of energy
   Guoqiang Tang, Matthieu Besemer, Stach Kuijpers, Gerrit C. Groenenboom, Ad van der Avoird, Tijs Karman, and Sebastiaan Y. T. van de Meerakker
   Science, 379, 1031 (2023)  [doi]   [arXiv:2302.06866]  [pdf]  [Supplement]
5. Spectrum of Feshbach Resonances in Na Li+ Na Collisions
   Juliana J Park, Hyungmok Son, Yu-Kun Lu, Tijs Karman, Marcin Gronowski, Michał Tomza, Alan O Jamison, and Wolfgang Ketterle
   Phys. Rev. X, 13, 031018 (2023)  [crossref]
6. Resonances in Non-universal Dipolar Collisions
   Tijs Karman
   J. Phys. Chem. A, 127, 2194 (2023)  [doi]   [arXiv:2212.03065]
7. Ab initio calculation of the spectrum of Feshbach resonances in NaLi+Na collisions
   Tijs Karman, Marcin Gronowski, Michał Tomza, Juliana J. Park, Hyungmok Son, Yu-Kun Lu, Alan O. Jamison, and Wolfgang Ketterle
   Phys. Rev. A, 108, 023309 (2023)  [doi]  [https://link.aps.org/doi/10.1103/PhysRevA.108.023309]
8. Field-linked resonances of polar molecules
   Xing-Yan Chen, Andreas Schindewolf, Sebastian Eppelt, Roman Bause, Marcel Duda, Shrestha Biswas, Tijs Karman, Timon Hilker, Immanuel Bloch, and Xin-Yu Luo
   Nature, 614, 59 (2023)  [doi]  [pdf]
9. Collisionally stable gas of bosonic dipolar ground-state molecules
   Niccol`o Bigagli, Claire Warner, Weijun Yuan, Siwei Zhang, Ian Stevenson, Tijs Karman, and Sebastian Will
   Nature Phys., 19, 1579 (2023)  [doi]   [arXiv:2303.16845]
10. Parameterized model to approximate theoretical collision-induced absorption band shapes for O2-O2 and O2-N2
    Erin M Adkins, Tijs Karman, Alain Campargue, Didier Mondelain, and Joseph T Hodges
    J. Quant. Spectrosc. Radiat. Transfer, 310, 108732 (2023)   [openurl]
11. Correlated rotational excitations in NO-CO inelastic collisions
    Guoqiang Tang, Matthieu Besemer, Jolijn Onvlee, Tijs Karman, Ad van der Avoird, Gerrit C. Groenenboom, and Sebastiaan Y. T. van de Meerakker
    J. Chem. Phys., 156, 214304 (2022)  [doi]  [pdf]  ©
12. Control of reactive collisions by quantum interference
    Hyungmok Son, Juliana J. Park, Yu-Kun Lu, Alan O. Jamison, Tijs Karman, and Wolfgang Ketterle
    Science, 375, 1006 (2022)  [doi]  [pdf]  [Supplement]
13. Evaporation of microwave-shielded polar molecules to quantum degeneracy
    Andreas Schindewolf, Roman Bause, Xing-Yan Chen, Marcel Duda, Tijs Karman, Immanuel Bloch, and Xin-Yu Luo
    Nature, 607, 677 (2022)  [doi]  [pdf]  [Supplement]
14. Ab initio study of the reactivity of ultracold RbSr + RbSr collisions
    Marijn P. Man, Tijs Karman, and Gerrit C. Groenenboom
    New J. Phys., 24, 055001 (2022)  [doi]   [arXiv:2108.02511]  [pdf]
15. Symmetry breaking in sticky collisions between ultracold molecules
    Marijn P. Man, Gerrit C. Groenenboom, and Tijs Karman
    Phys. Rev. Lett., 129, 243401 (2022)  [doi]   [arXiv:2203.13598]  [pdf]  [Supplement]
16. Resonant and first-order dipolar interactions between ultracold ¹Σ molecules in static and microwave electric fields
    Tijs Karman, Zoe Z. Yan, and Martin Zwierlein
    Phys. Rev. A, 105, 013321 (2022)  [doi]   [arXiv:2106.01610]  [pdf]
17. Koude moleculen met microgolven beschermd
    Tijs Karman
    Nederlands Tijdschrift voor Natuurkunde, 88, 22 (2022)  [http://www.ntvn.nl]
18. Glory scattering in deeply inelastic molecular collisions
    Matthieu Besemer, Guoqiang Tang, Zhi Gao, Ad van der Avoird, Gerrit C. Groenenboom, Sebastiaan Y. T. van de Meerakker, and Tijs Karman
    Nature Chem., 14, 664 (2022)  [doi]  [pdf]  [Supplement]
19. Para-ortho hydrogen conversion: solving a 90-year old mystery
    Xia Zhang, Tijs Karman, Gerrit C. Groenenboom, and Ad van der Avoird
    Nat. Sci., 1, e10002 (2021)  [doi]  [https://onlinelibrary.wiley.com/doi/epdf/10.1002/ntls.10002]  [pdf]  [Supplement]
20. Resonant and first-order dipolar interactions between ultracold 1Sigma molecules in static and microwave electric fields
    Tijs Karman, Zoe Z. Yan, and Martin Zwierlein
    Phys. Rev. A, 105, 013321 (2021)  [doi]   [arXiv:2106.01610]  [pdf]
21. Lossy quantum defect theory of ultracold molecular collisions
    Arthur Christianen, Gerrit C. Groenenboom, and Tijs Karman
    Phys. Rev. A, 104, 043327 (2021)  [doi]   [arXiv:2108.02724]  [pdf]
22. Collisions of ultracold molecules in bright and dark optical dipole traps
    Roman Bause, Andreas Schindewolf, Renhao Tao, Marcel Duda, Xing-Yan Chen, Goulven Quéméner, Tijs Karman, Arthur Christianen, Immanuel Bloch, and Xin-Yu Luo
    Phys. Rev. Res., 3, 033013 (2021)  [doi]  [pdf]
23. Observation of microwave shielding of ultracold molecules
    Loïc Anderegg, Sean Burchesky, Yicheng Bao, Scarlett S. Yu, Tijs Karman, Eunmi Chae, Kang-Kuen Ni, Wolfgang Ketterle, and John M. Doyle
    Science, 373, 779 (2021)  [doi]  [pdf]  [Supplement]
24. Resonant dipolar collisions of ultracold molecules induced by microwave dressing
    Zoe Z Yan, Jee Woo Park, Yiqi Ni, Huanqian Loh, Sebastian Will, Tijs Karman, and Martin Zwierlein
    Phys. Rev. Lett., 125, 063401 (2020)  [doi]  [pdf]
25. Measurements and semi-empirical calculations of CO₂+ CH₄ and CO₂+H₂ collision-induced absorption across a wide range of wavelengths and temperatures. Application for the prediction of early Mars surface temperature
    Martin Turbet, Christian Boulet, and Tijs Karman
    Icarus, 346, 113762 (2020)  [doi]  [pdf]
26. Photo-excitation of long-lived transient intermediates in ultracold reactions
    Yu Liu, Ming-Guang Hu, Matthew A Nichols, David D Grimes, Tijs Karman, Hua Guo, and Kang-Kuen Ni
    Nature Phys., 16, 1132 (2020)  [doi]  [pdf]
27. Microwave shielding with far-from-circular polarization
    Tijs Karman
    Phys. Rev. A, 101, 042702 (2020)  [doi]  [pdf]
28. Imaging the onset of the resonance regime in low-energy NO-He collisions
    Tim de Jongh, Matthieu Besemer, Quan Shuai, Tijs Karman, Ad van der Avoird, Gerrit C. Groenenboom, and Sebastiaan Y. T. van de Meerakker
    Science, 368, 626 (2020)  [doi]  [pdf]  [Supplement]
29. Rotational-vibrational resonance states
    A. G. Császár, I. Simkó, T. Szidarovszky, G. C. Groenenboom, T. Karman, and A. van der Avoird
    Phys. Chem. Chem. Phys., 22, 15081 (2020)  [doi]  [pdf]
30. Lichtabsorptie door botsende O₂-moleculen
    Tijs Karman, Ad van der Avoird, and Gerrit C. Groenenboom
    Nederlands Tijdschrift voor Natuurkunde, 85, 35 (2019)  [http://www.ntvn.nl]  [pdf]
31. Microwave shielding of ultracold polar molecules with imperfectly circular polarization
    Tijs Karman and Jeremy M. Hutson
    Phys. Rev. A, 100, 052704 (2019)  [doi]  [pdf]
32. Update of the HITRAN collision-induced absorption section
    Tijs Karman, Iouli E. Gordon, Ad van der Avoird, Yury I. Baranov, Christian Boulet, Brian J. Drouin, Gerrit C. Groenenboom, Magnus Gustafsson, Jean-Michel Hartmann, Robert L. Kurucz, Laurence S. Rothman, Kang Sun, Keeyoon Sung, Ryan Thalman, Ha Tran, Edward H. Wishnow, Robin Wordsworth, Andrey A. Vigasin, Rainer Volkamer, and Wim J. van der Zande
    Icarus, 328, 160 (2019)  [doi]  [http://www.sciencedirect.com/science/article/pii/S0019103518306997]  [pdf]
33. Theory and simulation of spectral line broadening by exoplanetary atmospheric haze
    Z. Felfli, T. Karman, V. Kharchenko, D. Vrinceanu, J. F. Babb, and H. R. Sadeghpour
    Mon. Not. R. Astron. Soc., 482, 1330 (2019)  [doi]  [pdf]
34. Photoinduced two-body loss of ultracold molecules
    Arthur Christianen, Martin W. Zwierlein, Gerrit C. Groenenboom, and Tijs Karman
    Phys. Rev. Lett., 123, 123402 (2019)  [doi]  [pdf]
35. Six-dimensional potential energy surface for NaK-NaK collisions: Gaussian Process representation with correct asymptotic form
    Arthur Christianen, Tijs Karman, Rodrigo A. Vargas-Hernández, Gerrit C. Groenenboom, and Roman V. Krems
    J. Chem. Phys., 150, 064106 (2019)  [doi]  [pdf]  ©
36. Quasiclassical method for calculating the density of states of ultracold collision complexes
    Arthur Christianen, Tijs Karman, and Gerrit C. Groenenboom
    Phys. Rev. A, 100, 032708 (2019)  [doi]  [pdf]
37. Scattering resonances in bimolecular collisions between NO radicals and H₂ challenge the theoretical gold standard
    Sjoerd N. Vogels, Tijs Karman, Jacek Kłos, Matthieu Besemer, Jolijn Onvlee, Ad van der Avoird, Gerrit C. Groenenboom, and Sebastiaan Y. T. van de Meerakker
    Nature Chem., 10, 435 (2018)  [doi]  [http://rdcu.be/HlDr]  [pdf]  [Supplement]
38. Energy dependent parity-pair behavior in NO + He collisions
    Jolijn Onvlee, Sjoerd N. Vogels, Tijs Karman, Gerrit C. Groenenboom, Sebastiaan Y. T. van de Meerakker, and Ad van der Avoird
    J. Chem. Phys., 149, 084306 (2018)  [doi]  [pdf]  ©
39. O₂-O₂ and O₂-N₂ collision-induced absorption mechanisms unravelled
    Tijs Karman, Mark A. J. Koenis, Agniva Banerjee, David H. Parker, Iouli E. Gordon, Ad van der Avoird, Wim J. van der Zande, and Gerrit C. Groenenboom
    Nature Chem., 10, 549 (2018)  [doi]  [https://rdcu.be/K2fO]  [pdf]  [Supplement]
40. Microwave shielding of ultracold polar molecules
    Tijs Karman and Jeremy M. Hutson
    Phys. Rev. Lett., 121, 163401 (2018)  [doi]  [pdf]
41. Near-threshold bound states of the dipole-dipole interaction
    Tijs Karman, Matthew D. Frye, John D. Reddel, and Jeremy M. Hutson
    Phys. Rev. A, 98, 062502 (2018)  [doi]  [pdf]
42. Collision-induced absorption by oxygen and nitrogen molecules
    Tijs Karman , Ph. D. thesis (Radboud University Nijmegen, 2018)  [http://hdl.handle.net/2066/190319]  [pdf]
43. Diabatic states, nonadiabatic coupling, and the counterpoise procedure for weakly interacting open-shell molecules
    Tijs Karman, Matthieu Besemer, Ad van der Avoird, and Gerrit C. Groenenboom
    J. Chem. Phys., 148, 094105 (2018)  [doi]  [pdf]  ©
44. Observation of correlated excitations in bimolecular collisions
    Zhi Gao, Tijs Karman, Sjoerd N. Vogels, Matthieu Besemer, Ad van der Avoird, Gerrit C. Groenenboom, and Sebastiaan Y. T. van de Meerakker
    Nature Chem., 10, 469 (2018)  [doi]  [pdf]  [Supplement]
45. Correlated energy transfer in rotationally and spin-orbit inelastic collisions of NO(X,²Π_1/2,j=1/2 f) with O₂(³Σ_g^-)
    Zhi Gao, Tijs Karman, Guoqiang Tang, Ad van der Avoird, Gerrit C. Groenenboom, and Sebastiaan Y. T. van de Meerakker
    Phys. Chem. Chem. Phys., 20, 12444 (2018)  [doi]  [pdf]
46. Potential energy and dipole moment surfaces of the triplet states of the O₂(X³Σ_g^-)-O₂(X³Σ_g^-,a¹Δ_g,b¹Σ_g⁺) complex
    Tijs Karman, Ad van der Avoird, and Gerrit C. Groenenboom
    J. Chem. Phys., 147, 084306 (2017)  [doi]  [pdf]  ©
47. Line-shape theory of the X³Σ_g^-→ a¹Δ_g,b¹Σ_g⁺ transitions in O₂-O₂ collision-induced absorption
    Tijs Karman, Ad van der Avoird, and Gerrit C. Groenenboom
    J. Chem. Phys., 147, 084307 (2017)  [doi]  [pdf]  ©
48. The HITRAN2016 Molecular Spectroscopic Database
    I. E. Gordon, L.S. Rothman, C. Hill, R.V. Kochanov, Y. Tan, P.F. Bernath, M. Birk, V. Boudon, A. Campargue, K.V. Chance, B.J. Drouin, J.-M. Flaud, R.R. Gamache, J.T. Hodges, D. Jacquemart, V.I. Perevalov, A. Perrin, K.P. Shine, M.-A.H. Smith, J. Tennyson, G.C. Toon, H. Tran, V.G. Tyuterev, A. Barbe, A.G. Császár, V.M. Devi, T. Furtenbacher, J.J. Harrison, J.-M. Hartmann, A. Jolly, T.J. Johnson, T. Karman, I. Kleiner, A.A. Kyuberis, J. Loos, O.M. Lyulin, S.T. Massie, S.N. Mikhailenko, N. Moazzen-Ahmadi, H.S.P. Müller, O.V. Naumenko, A.V. Nikitin, O.L. Polyansky, M. Rey, M. Rotger, S.W. Sharpe, K. Sung, E. Starikova, S.A. Tashkun, J. Vander Auwera, G. Wagner, J. Wilzewski, P. Wcisło, S. Yu, and E.J. Zak
    J. Quant. Spectrosc. Radiat. Transfer, 203, 3 (2017)  [doi]  [pdf]
49. State-to-state differential cross sections for inelastic collisions of NO radicals with para-H₂ and ortho-D₂
    Zhi Gao, Sjoerd Vogels, Matthieu Besemer, Tijs Karman, Gerrit C. Groenenboom, Ad van der Avoird, and Sebastiaan Y. T. van de Meerakker
    J. Phys. Chem. A, 121, 7446 (2017)  [doi]  [pdf]
50. Imaging diffraction oscillations for inelastic collisions of NO radicals with He and D₂
    Tim de Jongh, Tijs Karman, Sjoerd N. Vogels, Matthieu Besemer, Jolijn Onvlee, Arthur G. Suits, James O. F. Thompson, Gerrit C. Groenenboom, Ad van der Avoird, and Sebastiaan Y. T. van de Meerakker
    J. Chem. Phys., 147, 013918 (2017)  [doi]  [pdf]  ©
51. Imaging quantum stereodynamics through Fraunhofer scattering of NO radicals with rare gas atoms
    Jolijn Onvlee, Sean D. S. Gordon, Sjoerd N. Vogels, Thomas Auth, Tijs Karman, Bethan Nichols, Ad van der Avoird, Gerrit C. Groenenboom, Mark Brouard, and Sebastiaan Y. T. van de Meerakker
    Nature Chem., 9, 226 (2016)  [doi]  [pdf]  [Supplement]
52. Communication: Multiple-property-based diabatization for open-shell van der Waals molecules
    Tijs Karman, Ad van der Avoird, and Gerrit C. Groenenboom
    J. Chem. Phys., 144, 121101 (2016)  [doi]  [pdf]  ©
53. Quantum scattering calculations for ro-vibrational de-excitation of CO by hydrogen atoms
    Lei Song, Naduvalath Balakrishnan, Ad van der Avoird, Tijs Karman, and Gerrit C. Groenenboom
    J. Chem. Phys., 142, 204303 (2015)  [doi]  [pdf]  ©
54. Collision-induced absorption with exchange effects and anisotropic interactions: theory and application to H₂-H₂
    Tijs Karman, Ad van der Avoird, and Gerrit C. Groenenboom
    J. Chem. Phys., 142, 084305 (2015)  [doi]  [pdf]  ©
55. Quantum mechanical calculation of the collision-induced absorption spectra of N₂-N₂ with anisotropic interactions
    Tijs Karman, Evangelos Miliordos, Katharine L. C. Hunt, Gerrit C. Groenenboom, and Ad van der Avoird
    J. Chem. Phys., 142, 084306 (2015)  [doi]  [pdf]  ©
56. A renormalized potential-following propagation algorithm for solving the coupled-channels equations
    Tijs Karman, Liesbeth M. C. Janssen, Rik Sprenkels, and Gerrit C. Groenenboom
    J. Chem. Phys., 141, 064102 (2014)  [doi]  [pdf]  ©
57. Cold magnetically trapped ²D_g scandium atoms. II. Scattering dynamics
    Tijs Karman and Gerrit C. Groenenboom
    Phys. Rev. A, 90, 052702 (2014)  [doi]  [pdf]
58. Cold magnetically trapped ²D_g scandium atoms. I. Interaction potential
    Tijs Karman, Xi Chu, and Gerrit C. Groenenboom
    Phys. Rev. A, 90, 052701 (2014)  [doi]  [pdf]
59. Observation of Bose-Einstein Condensation of Dipolar Molecules
    Niccolò Bigagli, Weijun Yuan, Siwei Zhang, Boris Bulatovic, Tijs Karman, Ian Stevenson, and Sebastian Will
    Nature, , (2024)  [doi]   [arXiv:2312.10965]  [pdf]