Formation and dynamics of van der Waals molecules in buffer-gas traps

Brahms, Nathan; Tscherbul, Timur V.; Zhang, Peng; Kłos, Jacek; Forrey, Robert C.; Au, Yat Shan; Sadeghpour, H. R.; Dalgarno, A.; Doyle, John M.; Walker, Thad

doi:10.1039/c1cp21317b

Cited by 26 publications

(30 citation statements)

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“…A better understanding of the nature of these fundamental interactions would inform fields as diverse as molecule surface interactions [1] and buffer gas cooling. [2] The study of such molecules has been lent added impetus in recent years, by the popular use of rare gas atoms as messenger tags in action spectroscopy studies of gas-phase metal-ligand [3,4] naked metal [5][6][7][8] and metal oxide clusters. [9][10][11] In such studies, the structures of interest are widely assumed to be affected minimally by the presence of the inert tag with the result that the photodissociation action spectrum mirrors that of the naked species.…”

Section: Introductionmentioning

confidence: 99%

Dissociation energies of Ag–RG (RG = Ar, Kr, Xe) and AgO molecules from velocity map imaging studies

Cooper¹,

Kartouzian

Gentleman³

et al. 2015

The Journal of Chemical Physics

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The near ultraviolet photodissociation dynamics of silver atom -rare gas dimers have been studied by velocity map imaging. Ag-RG (RG = Ar, Kr, Xe) species generated by laser ablation are excited in the region of the C ( 2  + )  X ( 2  + ) continuum leading to direct, near-threshold dissociation generating Ag* ( 2 P 3/2 ) + RG ( 1 S 0 ) products. Images recorded at excitation wavelengths throughout the C ( 2  + )  X ( 2  + ) continuum, coupled with known atomic energy levels, permit determination of the ground X ( 2  + ) state dissociation energies of 85.9 ± 23.4 cm -1 (Ag-Ar), 149.3 ± 22.4 cm -1 (Ag-Kr) and 256.3 ± 16.0 cm -1 (Ag-Xe). Three additional photolysis processes, each yielding Ag atom photoproducts, are observed in the same spectral region. Two of these are markedly enhanced in intensity upon seeding the molecular beam with nitrous oxide, and are assigned to photodissociation of AgO at the two-photon level. These features yield an improved ground state dissociation energy for AgO of 15965  81 cm -1 , which is in good agreement with high level calculations. The third process results in Ag atom fragments whose kinetic energy shows anomalously weak photon energy dependence and is assigned tentatively to dissociative ionization of the silver dimer Ag 2 .3

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Section: Introductionmentioning

confidence: 99%

Dissociation energies of Ag–RG (RG = Ar, Kr, Xe) and AgO molecules from velocity map imaging studies

Cooper¹,

Kartouzian

Gentleman³

et al. 2015

The Journal of Chemical Physics

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“…Recent groundbreaking advances in the production and trapping of translationally cold molecules [16] made it possible to create trapped ensembles of cold polar molecules with high enough densities to study collisions and chemical reactions [16][17][18] and carry out ultra-precise spectroscopic measurements to probe the physics beyond the Standard Model [19]. The production and trapping of cold vdW molecules would similarly enable highly sensitive spectroscopic detection of heretofore unobserved clusters, as well as the study and control of their quantum dynamics [7,[20][21][22].We have recently observed the formation of cold, ground-state LiHe molecules in a cryogenic He buffer gas [23]. The LiHe molecule has a single near-threshold bound state with a binding energy of 0.024 cm −1 [24] comparable to that of the He 2 dimer [11,21].…”

mentioning

confidence: 99%

“…In condensed-phase chemical physics, vdW clusters serve as a model to study the mechanisms of solvation, nucleation, and chemical reactivity [6][7][8]. In the context of quantum many-body physics, vdW molecules can be used to explore the formation of exotic quasiparticles in superfluid helium nanodroplets [9].…”

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confidence: 99%

“…Due to their vanishingly small binding energies, these molecules belong to an exotic class of quantum halo dimers characterized by extremely delocalized wavefunctions, universal properties, and enormously large three-body formation rates [3,25]. As the binding energies of most other * weinstein@physics.unr.edu; http://www.physics.unr.edu/xap/ atoms and molecules with He are much larger than those of LiHe and He 2 [7], it is far from obvious whether atomHe vdW clusters would form upon immersing the parent atoms into cryogenic He buffer gas. In fact, no such clusterization was observed in recent buffer gas cooling experiments involving large hydrocarbon molecules [26].…”

mentioning

confidence: 99%

“…Lf, 33.15.Fm, Weakly bound complexes of atoms and molecules held together by long-range van der Waals (vdW) forces are key to understanding a wide range of phenomena in physics and chemistry, ranging from classical and quantum chaos [1] and phase transitions [2] to the universal physics of Efimov trimers and quantum droplets [3][4][5]. In condensed-phase chemical physics, vdW clusters serve as a model to study the mechanisms of solvation, nucleation, and chemical reactivity [6][7][8]. In the context of quantum many-body physics, vdW molecules can be used to explore the formation of exotic quasiparticles in superfluid helium nanodroplets [9].…”

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confidence: 99%

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Cold Anisotropically Interacting van der Waals Molecule: TiHe

et al. 2017

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We have used laser ablation and helium buffer-gas cooling to produce the titanium-helium van der Waals molecule at cryogenic temperatures. The molecules were detected through laser-induced fluorescence spectroscopy. Ground-state Ti(a 3 F2)-He binding energies were determined for the ground and first rotationally excited states from studying equilibrium thermodynamic properties, and found to agree well with theoretical calculations based on newly calculated ab initio Ti-He interaction potentials, opening up novel possibilities for studying the formation, dynamics, and non-universal chemistry of van der Waals clusters at low temperatures.PACS numbers: 34.50. Lf, 33.15.Fm, Weakly bound complexes of atoms and molecules held together by long-range van der Waals (vdW) forces are key to understanding a wide range of phenomena in physics and chemistry, ranging from classical and quantum chaos [1] and phase transitions [2] to the universal physics of Efimov trimers and quantum droplets [3][4][5]. In condensed-phase chemical physics, vdW clusters serve as a model to study the mechanisms of solvation, nucleation, and chemical reactivity [6][7][8]. In the context of quantum many-body physics, vdW molecules can be used to explore the formation of exotic quasiparticles in superfluid helium nanodroplets [9]. Helium-containing vdW molecules are the lightest of all vdW clusters, and hence are of particular interest as model systems, in which to study the emergence of macroscopic quantum phenomena such as superfluidity [10].Thus far, the experimental study of He-containing vdW molecules has focused on molecules formed in supersonic expansions [8,[11][12][13][14][15]. Recent groundbreaking advances in the production and trapping of translationally cold molecules [16] made it possible to create trapped ensembles of cold polar molecules with high enough densities to study collisions and chemical reactions [16][17][18] and carry out ultra-precise spectroscopic measurements to probe the physics beyond the Standard Model [19]. The production and trapping of cold vdW molecules would similarly enable highly sensitive spectroscopic detection of heretofore unobserved clusters, as well as the study and control of their quantum dynamics [7,[20][21][22].We have recently observed the formation of cold, ground-state LiHe molecules in a cryogenic He buffer gas [23]. The LiHe molecule has a single near-threshold bound state with a binding energy of 0.024 cm −1 [24] comparable to that of the He 2 dimer [11,21]. Due to their vanishingly small binding energies, these molecules belong to an exotic class of quantum halo dimers characterized by extremely delocalized wavefunctions, universal properties, and enormously large three-body formation rates [3,25]. As the binding energies of most other * weinstein@physics.unr.edu; http://www.physics.unr.edu/xap/ atoms and molecules with He are much larger than those of LiHe and He 2 [7], it is far from obvious whether atomHe vdW clusters would form upon immersing the parent atoms into cryogenic He buffer gas. ...

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Three-Body Recombination Between Helium and Silver Atoms at Cold Collision Energies

Suno

2024

Few-Body Syst

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Formation and dynamics of van der Waals molecules in buffer-gas traps

Cited by 26 publications

References 93 publications

Dissociation energies of Ag–RG (RG = Ar, Kr, Xe) and AgO molecules from velocity map imaging studies

Dissociation energies of Ag–RG (RG = Ar, Kr, Xe) and AgO molecules from velocity map imaging studies

Cold Anisotropically Interacting van der Waals Molecule: TiHe

Three-Body Recombination Between Helium and Silver Atoms at Cold Collision Energies

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