Probing the electronic structure and Au–C chemical bonding in AuC2− and AuC2 using high-resolution photoelectron spectroscopy

León, Íker; Yang, Zhenhua; Wang, Lai-Sheng

doi:10.1063/1.4865978

Cited by 28 publications

(24 citation statements)

References 56 publications

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“…29 Our high-resolution imaging study of Au 2 − achieved a vibrational temperature of ∼175 K. 20 Dimer anions are especially challenging to cool in our laser vaporization source because we cannot achieve long enough resident time in the nozzle due to ion loss. We have recently observed a vibrational temperature of 125 K for AuC 2 − , 23 whereas for Au 4 − we were able to essentially eliminate all vibrational hot bands by using the helium carrier gas seeded with 5% Ar in combination with an optimal resident time. 21…”

Section: A the Laser-vaporization Supersonic Cluster Sourcementioning

confidence: 95%

“…(3) for small R or low energy electrons. [20][21][22][23] Furthermore, the calibration parameter a increases essentially linearly with the voltage applied to the repeller plate (V R ). With our current geometry (a 50 cm distance between the interaction zone and the imaging detector plane), the constant a is 3.720 × 10 −6 for V R = −300 V, and for KE in eV and R in μm.…”

Section: A the Image Quality And Image Calibrationmentioning

confidence: 99%

“…It has been fully tested and has yielded some very interesting initial results. [20][21][22][23] The new VMI system is based on a previous photoion-imaging strategy that highlight how weak fields in the electrostatic lenses during the initial acceleration stage allow achieving a better velocity focusing at the cost of sacrificing temporal focusing. 24 Our new VMI system can reach a resolution of 1.2 cm −1 for near threshold electrons comparable to that reported by Neumark, 16 while still maintaining good energy resolution ( KE/KE ∼ 0.53%) for higher energy electrons comparable to that reported by Cavanagh and co-workers.…”

Section: Introductionmentioning

confidence: 99%

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The design and construction of a high-resolution velocity-map imaging apparatus for photoelectron spectroscopy studies of size-selected clusters

León

Yang

Liu

et al. 2014

Review of Scientific Instruments

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142

102

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A new velocity-map imaging apparatus equipped with a laser-vaporization supersonic cluster source and a time-of-flight mass spectrometer is described for high-resolution photoelectron spectroscopy studies of size-selected cluster anions. Vibrationally cold anion clusters are produced using a laser-vaporization supersonic cluster source, size-selected by a time-of-flight mass spectrometer, and then focused co-linearly into the interaction zone of the high-resolution velocity-map imaging (VMI) system. The multilens VMI system is optimized via systematic simulations and can reach a resolution of 1.2 cm(-1) (FWHM) for near threshold electrons while maintaining photoelectron kinetic energy resolutions (ΔKE/KE) of ~0.53% for higher energy electrons. The new VMI lens has superior focusing power over a large energy range, yielding highly circular images with distortions no larger than 1.0025 between the long and short radii. The detailed design, simulation, construction, testing, and performance of the high-resolution VMI apparatus are presented.

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Section: A the Laser-vaporization Supersonic Cluster Sourcementioning

confidence: 95%

Section: A the Image Quality And Image Calibrationmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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The design and construction of a high-resolution velocity-map imaging apparatus for photoelectron spectroscopy studies of size-selected clusters

León

Yang

Liu

et al. 2014

Review of Scientific Instruments

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142

102

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“…: +86 10 62635054, Fax: +86 10 62563167. microwave (FTMW) spectroscopy. 22 The photoelectron spectra of AuC 2 , 23,24 AuC 3 H , 25 and AuC 4 H 26 as well as those of AuC n and AuC n H (n = 2, 4, and 6) 27 were measured using electron velocity map imaging (VMI) technique. The photoelectron spectra and bonding properties of LAuC 2 H (L = Cl, I, and C 2 H) were investigated using the magnetic-bottle anion photoelectron spectroscopy experiment and theoretical calculations.…”

Section: Introductionmentioning

confidence: 99%

Gas phase anion photoelectron spectroscopy and theoretical investigation of gold acetylide species

Wang

Zhang

et al. 2017

The Journal of Chemical Physics

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We conducted gas phase anion photoelectron spectroscopy and density functional theory studies on a number of gold acetylide species, such as AuCH, AuCAu, and AuCH. Based on the photoelectron spectra, the electron affinities of AuCH, AuCAu, and AuCH are measured to be 1.54(±0.04), 1.60(±0.08), and 4.23(±0.08) eV, respectively. The highest occupied molecular orbital-lowest unoccupied molecular orbital (HOMO-LUMO) gaps of AuCH and AuCAu are measured to be about 2.62 and 2.48 eV, respectively. It is interesting that photoelectron spectra of AuCH and AuCAu display similar spectral features. The comparison of experimental and theoretical results confirms that the ground-state structures of AuCH, AuCAu, and their neutrals are all linear with Au-C≡C-H and Au-C≡C-Au configurations. The similar geometric structures, spectral features, HOMO-LUMO gaps, and chemical bonding between AuCH and AuCAu demonstrate that Au atom behaves like H atom in these species. The photoelectron spectrum of AuCH shows that AuCH has a high electron affinity of 4.23(±0.08) eV, indicating AuCH is a superhalogen. Further, we found an unusual similarity between the terminal Au atom of AuCH and the iodine atom of IAuCH.

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“…Particularly well understood from the vantage point of quantitative measurements are gaseous C 2 Au and the corresponding anion 22 . The ground state of C 2 Au (X 2 Σ + ) has been shown by photoelectron spectroscopy to be linear but only ca 0.2 kJ mol −1 lower in energy than the bent first excited state (A ′2 π).…”

Section: Gas Phase Gold-carbon Clusters Of the Type [C M Au N ] mentioning

confidence: 99%

Aurocarbons: Binary Gold Carbides, Binary Carbon Aurides and their Derivatives

Perks

Liebman

2014

Patai's Chemistry of Functional Groups

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This chapter discusses diverse aurocarbons, organometallic species which in their simplest form, the first class, are composed of only carbon and gold: they may be understood as binary gold carbides, binary carbon aurides, and as hydrocarbons in which the hydrogens have been replaced by gold. Such species include the highly explosive solid C 2 Au 2 and gas phase exohedral gold‐fullerene complexes (C 60 )2Au + . The second class of aurocarbons are species of the first class in which ligands have been affixed to the gold atoms. This includes the stable C 2 Au 2 (P(C 6 H 5 ) 3 ) 2 and the octahedral [C(AuL) 6 ] 2+ (L = phenyl(bis(p‐tolyl)) phosphine, the latter isolable as the crystalline (BF 4 ) − salt. The third class allows for the presence of “a few” hydrogens or other univalent groups and so includes salts of the anion [HCCCCAuCCCCAuCCCCH] 2− and solutions of the cation [C 6 H 5 CC(AuP(C 6 H 5 ) 3 ) 2 ] + . It is to be emphasized that there must be direct gold–carbon bonding and so the heterometallic cluster Rh 10 C 2 (CO) 2 [AuP(C 6 H 5 ) 3 ) 4 ] is not an aurocarbon of any class even though it contains an allmetal polyhedron, ligated gold atoms, endohedral carbon atoms and a plethora of ligands.

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Probing the electronic structure and Au–C chemical bonding in AuC2− and AuC2 using high-resolution photoelectron spectroscopy

Cited by 28 publications

References 56 publications

The design and construction of a high-resolution velocity-map imaging apparatus for photoelectron spectroscopy studies of size-selected clusters

The design and construction of a high-resolution velocity-map imaging apparatus for photoelectron spectroscopy studies of size-selected clusters

Gas phase anion photoelectron spectroscopy and theoretical investigation of gold acetylide species

Aurocarbons: Binary Gold Carbides, Binary Carbon Aurides and their Derivatives

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