Thanja Lamberts
Assistant Professor
- Name
- Dr. A.L.M. Lamberts
- Telephone
- +31 71 527 4533
- a.l.m.lamberts@lic.leidenuniv.nl
- ORCID iD
- 0000-0001-6705-2022
Thanja Lamberts is an assistant professor at the Leiden Institute of Chemistry and Leiden Observatory. Her group focuses on computational astrochemistry to unravel which molecules can be formed efficiently in the dense regions of the interstellar medium. She is particularly interested in the chemistry that takes place on the surface of ice-coated dust grains.
More information about Thanja Lamberts
PhD candidates
News
-
‘Young Academy Leiden wants to stand up for young researchers, especially in difficult times’ -
Tracking the origin and evolution of molecules in space -
Leiden astronomers find building blocks for life in the darkest spots of star-forming cloud -
Towards molecular complexity in birth places of stars: Formaldehyde formation from carbon atoms reacting with water ice -
Long-awaited review reveals journey of water from interstellar clouds to habitable worlds
Teaching
Research interests
During my PhD with Prof. Dr. H. Linnartz (Laboratory for Astrophysics, Leiden University) I have worked on experimental surface astrochemistry using ultra-high vacuum and cryogenic technology in order to mimic the physical conditions in the interstellar medium. In particular, I studied water formation.
While confirmation or exclusion of reaction pathways is possible in experiments like these, it is nearly impossible to disentangle the relative importance of individual elemental processes, e.g., adsorption, diffusion, dissociation, recombination and desorption. Therefore, I have performed kinetic Monte Carlo (kMC) simulations in collaboration with Dr. H. Cuppen (Radboud University Nijmegen).
Subsequently, as an Alexander von Humboldt postdoctoral fellow in the group of Prof. Dr. J. Kästner (University of Stuttgart), I calculated reaction rate constants at low temperatures, i.e., well below 100 K. To overcome activation barriers in these cold interstellar conditions, tunneling needs to be taken into account. For this, instanton theory is a very suitable method.
I have worked as a Veni laureate with Dr. J. Meyer (Leiden University) to better understand how and how efficiently reaction excess energy dissipates into the surface degrees of freedom of molecular ices and solids relevant to the interstellar medium.
Currently, I make use of my experience outlined above and employ computational chemical techniques to study surface processes individually, and link the outcome to observational, experimental, and modeling work at Leiden Observatory.
Short Curriculum Vitae
Nationality: Dutch
Date of birth: 12 September 1987
Education
2015 PhD in experimental and modeling astrochemistry, Leiden University and Radboud University Nijmegen, The Netherlands
Thesis title: "Unraveling the surface formation of regular and deuterated water in space"
Advisors: Prof. Dr. H. Linnartz, Dr. H.M. Cuppen
2010 M.Sc. in Physical Chemistry - cum laude, Radboud University Nijmegen, The Netherlands
2008 B.Sc. in Chemistry - summa cum laude, Radboud University Nijmegen, The Netherlands
Current and previous research positions
2021 - present Assistant Professor, Leiden Institute of Chemistry and Leiden Observatory, Leiden University, The Netherlands
2018 -2022 Veni laureate, Leiden Institute of Chemistry, Leiden University, The Netherlands
2016 - 2017 Humboldt fellow, Institute for Theoretical Chemistry, University of Stuttgart, Germany
2016 Visiting researcher, Institute for Low-Temperature Studies, Sapporo, Japan
2016 Postdoctoral researcher, Institute for Theoretical Chemistry, University of Stuttgart, Germany
2015 Postdoctoral researcher, Radboud University Nijmegen (Dr. H.M. Cuppen), The Netherlands
Grants and awards
2017 Veni grant for independent postdoctoral research (NL)
2016 Alexander von Humboldt fellowship for postdoctoral research (DE)
2013 Poster prize Study Group Meeting NWO
2013 Poster prize HRSMC Symposium
2009 Unilever Research prize
Publication record:
Assistant Professor
- Science
- Leiden Institute of Chemistry
- LIC/Energy & Sustainability
- LIC/ES/Theoretical Chemistry
Assistant Professor
- Science
- Sterrewacht
- Sterrewacht
- Ferrari B.C., Molpeceres G., Kästner J., Aikawa Y., Hemert M.C. van, Meyer J. & Lamberts A.L.M. (2023), Floating in space: how to treat the weak interaction between CO molecules in interstellar ices, ACS Earth and Space Chemistry 7(7): 1423-1432.
- Cooke I.R., Xue C., Changala P.B., Shay H.T., Byrne A.N., Tang Q.Y., Fried Z.T.P., Kelvin Lee K.L., Loomis R.A., Lamberts T., Remijan A., Burkhardt A.M., Herbst E., McCarthy M.C. & McGuire B.A. (2023), Detection of interstellar E-1-cyano-1,3-butadiene in GOTHAM observations of TMC-1, The Astrophysical Journal 948(2): 133.
- Heyl J., Lamberts A.L.M.., Viti S. & Holdship J.R. (2023), Investigating the impact of reactions of C and CH with molecular hydrogen on a glycine gas-grain network, Monthly Notices of the Royal Astronomical Society 520(1): 503-512.
- McClure M.K., Rocha W.R.M., Pontoppidan K.M., Crouzet N., Chu L.E.U., Dartois E., Lamberts T., Noble J.A., Pendleton Y.J., Perotti G., Qasim D., Rachid M.G., Smith Z.L., Sun F., Beck T.L., Boogert A.C.A., Brown W.A., Caselli P., Charnley S.B., Cuppen H.M., Dickinson H., Drozdovskaya M.N., Egami E., Erkal J., Fraser H., Garrod R.T., Harsono D., Ioppolo S., Jiménez-Serra I., Jin M., Jørgensen J.K., Kristensen L.E., Lis D.C., McCoustra M.R.S., McGuire B.A., Melnick G.J., Ã-berg K.I., Palumbo M.E., Shimonishi T., Sturm J.A., Dishoeck E.F. van & Linnartz H. (2023), An ice age JWST inventory of dense molecular cloud ices, Nature Astronomy 7: 431-443.
- Carvalho Santos J. de, Chuang K., Lamberts A.L.M., Fedoseev G., Ioppolo S. & Linnartz H.V.J. (2022), First experimental confirmation of the CH3O + H2CO → CH3OH + HCO reaction: expanding the CH3OH formation mechanism in interstellar ices, Astrophysical Journal Letters 931(2): L33.
- Lamberts A.L.M., Fedoseev G., Hemert M.C. van, Qasim D.N, Chuang K., Carvalho Santos J. de & Linnartz H.V.J. (2022), Methane formation in cold regions from carbon atoms and molecular hydrogen, The Astrophysical Journal 928(1): 48.
- He J., Simons M., Fedoseev G., Chuang K., Qasim D., Lamberts A.L.M., Ioppolo S., McGuire B.A., Cuppen H. & Linnartz H.V.J. (2022), Methoxymethanol formation starting from CO hydrogenation, Astronomy and Astrophysics 659: A65.
- Fedoseev G., Qasim D., Chuang K., Ioppolo S., Lamberts A.L.M.., Dishoeck E.F. van & Linnartz H.V.J. (2022), Hydrogenation of accreting C atoms and CO molecules–simulating ketene and acetaldehyde formation under dark and translucent cloud conditions, The Astrophysical Journal 924(2): 110.
- Campisi D., Lamberts A.L.M., Dzade N.Y., Martinazzo R., Kate I.L. ten & Tielens A.G.G.M. (2022), Adsorption of polycyclic aromatic hydrocarbons and C60 onto forsterite: C–H bond activation by the schottky vacancy, ACS Earth and Space Chemistry 6(8): 2009-2023.
- Dishoeck E.F. van, Kristensen L.E., Mottram J.C., Benz A.O., Bergin E.A., Caselli P., Herpin F., Hogerheijde M.R., Johnstone D., Liseau R., Nisini B., Tafalla M., Tak F.F.S. van der, Wyrowski F., Baudry A., Benedettini M., Bjerkeli P., Blake G.A., Braine J., Bruderer S., Cabrit S., Cernicharo J., Choi Y., Coutens A., Graauw Th. de, Dominik C., Fedele D., Fich M., Fuente A., Furuya K., Goicoechea J.R., Harsono D., Helmich F.P., Herczeg G.J., Jacq T., Karska A., Kaufman M., Keto E., Lamberts T., Larsson B., Leurini S., Lis D.C., Melnick G., Neufeld D., Pagani L., Persson M., Shipman R., Taquet V., Kempen T. A. van, Walsh C., Wampfler S.F. & Yıldız U. (2021), Water in star-forming regions: physics and chemistry from clouds to disks as probed by Herschel spectroscopy, Astronomy and Astrophysics 648: A24.
- Campisi D., Lamberts T., Dzade N.Y., Martinazzo R., Kate I.L. ten & Tielens A.G.G.M. (2021), Interaction of aromatic molecules with forsterite: accuracy of the periodic DFT-D4 method, The Journal of Physical Chemistry A 125(13): 2770-2781.
- Molpeceres G., Kästner J., Fedoseev G., Qasim D., Schömig R., Linnartz H. & Lamberts T. (2021), Carbon atom reactivity with amorphous solid water: H2O-catalyzed formation of H2CO, Journal of Physical Chemistry Letters 12(44): 10854-10860.
- Dishoeck E.F. van, Kristensen L.E., Mottram J.C., Benz A.O., Bergin E.A., Caselli P., Herpin F., Hogerheijde M.R., Johnstone D., Liseau R., Nisini B., Tafalla M., Tak F.F.S. van der, Wyrowski F., Baudry A., Benedettini M., Bjerkeli P., Blake G.A., Braine J., Bruderer S., Cabrit S., Cernicharo J., Choi Y., Coutens A., de Graauw T., Dominik C., Fedele D., Fich M., Fuente A., Furuya K., Goicoechea J.R., Harsono D.S., Helmich F.P., Herczeg G.J., Jacq T., Karska A., Kaufman M., Keto E., Lamberts A.L.M., Larsson B., Leurini S., Lis D.C., Melnick G., Neufeld D., Pagani L., Persson M., Shipman R., Taquet V., Kempen T.A. van, Walsh C., Wampfler S.F. & Yıldız U. (2021), Water in star-forming regions: physics and chemistry from clouds to disks as probed by Herschel spectroscopy, Astronomy and Astrophysics 648: 1-57 (A24).
- Enrique-Romero J., Álvarez-Barcia S., Kolb F. J., Rimola A., Ceccarelli C., Balucani N., Meisner J., Ugliengo P., Lamberts T. & Kästner J. (2020), Revisiting the reactivity between HCO and CH3 on interstellar grain surfaces, Monthly Notices of the Royal Astronomical Society 493(2): 2523-2527.
- Simons M. A. J., Lamberts T. & Cuppen H. M. (2020), Formation of COMs through CO hydrogenation on interstellar grains, Astronomy and Astrophysics 634: A52.
- Shingledecker C.N., Lamberts T., Laas J.C., Vasyunin A., Herbst E., Kästner J. & Caselli P. (2020), Efficient production of S8 in interstellar ices: the effects of cosmic-ray-driven radiation chemistry and nondiffusive bulk reactions, The Astrophysical Journal 888(1): 52.
- Qasim D.N., Lamberts A.L.M., He J., Chuang K.-J., Fedoseev G., Ioppolo S., Boogert A.C.A. & Linnartz H.V.J. (2019), Extension of the HCOOH and CO_2 solid-state reaction network during the CO freeze-out stage: inclusion of H_2CO, 626: A118.
- Qasim D., Fedoseev G., Chuang K.-J., Taquet V., Lamberts T., He J., Ioppolo S., Dishoeck E.F. van & Linnartz H. (2019), Formation of interstellar propanal and 1-propanol ice: a pathway involving solid-state CO hydrogenation, 627: A1.
- Qasim D., Fedoseev G., Lamberts T., Chuang K.J., He J., Ioppolo S., Kastner J. & Linnartz H. (2019), Alcohols on the Rocks: Solid-State Formation in a H3CC CH + OH Cocktail under Dark Cloud Conditions, ACS Earth and Space Chemistry 3(6): 986-999.
- Markmeyer M.N., Lamberts A.L.M., Meisner J. & Kästner J. (2018), HOCO formation in astrochemical environments by radical-induced H-abstraction from formic acid, Monthly Notices of the Royal Astronomical Society 482(1): 293-300.
- Álvarez-Barcia S., Russ P., Kästner J. & Lamberts A.L.M. (2018), Hydrogen transfer reactions of interstellar Complex Organic Molecules, Monthly Notices of the Royal Astronomical Society 479(2): 2007–2015.
- Oba Y., Tomaru T., Lamberts A.L.M., Kouchi A. & Watanabe N. (2018), An infrared measurement of chemical desorption from interstellar ice analogues, Nature Astronomy 2(3): 228-232.
- Lamberts A.L.M. (2018), From interstellar carbon monosulfide to methyl mercaptan: paths of least resistance, Astronomy and Astrophysics 615: L2.
- Zaverkin V., Lamberts A.L.M., Markmeyer M.N. & Kästner J. (2018), Tunnelling dominates the reactions of hydrogen atoms with unsaturated alcohols and aldehydes in the dense medium, Astronomy and Astrophysics 617: A25.
- Cuppen H.M., Walsh C., Lamberts A.L.M., Semenov D., Garrod R.T., Penteado E.M. & Ioppolo S. (2017), Grain Surface Models and Data for Astrochemistry, Space Science Reviews 212(1-2): 1-58.
- Lamberts A.L.M., Ioppolo S., Cuppen H.M., Fedoseev G. & Linnartz H.V.J. (2015), Thermal H/D exchange in polar ice - deuteron scrambling in space, Monthly Notices of the Royal Astronomical Society 448(4): 3820-3828.
- Fedoseev G., Cuppen H.N., Ioppolo S., Lamberts A.L.M. & Linnartz H.V.J. (2015), Experimental evidence for glycolaldehyde and ethylene glycol formation by surface hydrogenation of CO molecules under dense molecular cloud conditions, Monthly Notices of the Royal Astronomical Society 448(2): 1288-1297.
- Fedoseev G., Ioppolo S., Zhao D., Lamberts A.L.M. & Linnartz H.V.J. (2015), Low-temperature surface formation of NH3 and HNCO: hydrogenation of nitrogen atoms in CO-rich interstellar ice analogues, Monthly Notices of the Royal Astronomical Society 446(1): 439-448.
- Lamberts A.L.M. (20 May 2015), Unraveling the surface formation of regular and deuterated water in space : a combined laboratory and computational study (Dissertatie. Leiden Observatory, Faculty of Science, Leiden University). Supervisor(s) and Co-supervisor(s): Linnartz H.V.J., Cuppen H.M. & Iopollo S.
- Lamberts T., De Vries X. & Cuppen H.M. (2014), The formation of ice mantles on interstellar grains revisited - the effect of exothermicity, Faraday Discussions 168: 327-347.
- Lamberts A.L.M., Cuppen H., Fedoseev G., Ioppolo S., Chuang K. & Linnartz H.V.J. (2014), Relevance of the H2 + O reaction pathway for the surface formation of interstellar water. Combined experimental and modeling study, Astronomy and Astrophysics 570: A57.
- Lamberts T., Cuppen H.M., Ioppolo S. & Linnartz H. (2013), Water formation at low temperatures by surface O2 hydrogenation III: Monte Carlo simulation, Physical Chemistry Chemical Physics 15(8287): .
- Cuppen H.M., Karssemeijer L.J. & Lamberts T. (2013), The Kinetic Monte Carlo Method as a Way To Solve the Master Equation for Interstellar Grain Chemistry, Chemical Reviews 113(12): 8840-8871.
- Ioppolo S., Fedoseev G., Lamberts A.L.M., Romanzin C. & Linnartz H.V.J. (2013), SURFRESIDE2: An ultrahigh vacuum system for the investigation of surface reaction routes of interstellar interest, Review of Scientific Instruments 84: 073112.