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Electron velocity map imaging and theoretical study on CuXH (X = O and S) anions
Accepted Manuscript Electron velocity map imaging and theoretical study on CuXH (X=O and S) anions
Zhengbo Qin, Hui Wang, Yangdi Ren, Xianfeng Zheng, Zhifeng Cui, Zichao Tang PII: DOI: Reference:
S1386-1425(17)30516-4 doi: 10.1016/j.saa.2017.06.039 SAA 15255
To appear in:
Spectrochimica Acta Part A: Molecular and Biomolecular Spectroscopy
Received date: Revised date: Accepted date:
15 February 2017 27 June 2017 30 June 2017
Please cite this article as: Zhengbo Qin, Hui Wang, Yangdi Ren, Xianfeng Zheng, Zhifeng Cui, Zichao Tang , Electron velocity map imaging and theoretical study on CuXH (X=O and S) anions, Spectrochimica Acta Part A: Molecular and Biomolecular Spectroscopy (2017), doi: 10.1016/j.saa.2017.06.039
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ACCEPTED MANUSCRIPT Electron velocity map imaging and theoretical study on CuXH (X=O and S) anions
Zhengbo Qina,, Hui Wanga, Yangdi Rena, Xianfeng Zhenga, and Zhifeng Cuia, and
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a
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Zichao Tangb,,
Anhui Province Key Laboratory of Optoelectric Materials Science and Technology,
b
NU
SC
Department of Physics, Anhui Normal University, Wuhu, Anhui 241000, China
State Key Laboratory of Physical Chemistry of Solid Surfaces, Department of
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Chemistry, College of Chemistry and Chemical Engineering, Xiamen University,
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CE
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Xiamen 361005, China
*
Corresponding authors: Email: [email protected] (Z.B.Q.), [email protected]
(Z.C.T.)
1
ACCEPTED MANUSCRIPT ABSTRACT Vibrationally resolved photoelectron spectra of CuOH– and CuSH– have been determined via velocity map imaging method to investigate the transitions of X1A'← X2A' at 532 nm. Adiabatic detachment energies of CuOH– and CuSH– are assigned to 0.995(12) and 1.098(12) eV, respectively. Combined theoretical calculations with
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Franck-Condon simulations, it allows extracting the vibrational frequencies in neutral,
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which yields 629(32) cm-1 with Cu-O stretching mode and 387(24) cm-1 with Cu-S
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stretching mode for CuXH (X = O and S). Parallel transition properties of photoelectron angular distributions (PADs) for both species are correlated to the
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photodetachment of SOMO orbitals, which mainly involved in the Cu atom s orbital and partial s orbital in other atoms. Based on chemical bonding analyses (Wiberg,
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NAO, Mayer, NRT, and ELF), it is suggested that a trend is observed with a subtle variation of covalent component from weak covalent behavior between Cu-O in
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CuOH–1/0 to stronger covalent bonding between Cu-S in CuSH–1/0 (especially for
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non-ignorable covalent component in CuSH species) though ionic bonding dominates
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both in Cu-O and Cu-S bonds for the two systems.
2
ACCEPTED MANUSCRIPT I. INTRODUCTION There are many studies on the noble metal catalysis on water to produce hydrogen and hydroxyl groups [1]. One process possibly includes dissociated OH fragment binding or migrating on surface. In copper surface catalysis process, H2O (or H2S) adsorption on the surface may become to dissociative chemical adsorption [2-5].
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OH or SH fragments may be bonding or migrating on a specific active site. Studying
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the chemical binding capabilities between copper and those functional groups is
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significant for understanding surface chemical reaction for copper atom interacting with H2O and H2S etc. solvent molecules. In the gas phase, the bond properties
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between the basic unit Cu atom and these functional groups are less well known. The interaction of the thiols with noble metal surfaces and interfaces (especially
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for gold) is of considerable interest for the design of new functional materials in molecular electronics, surface modification and heterogeneous catalysis [6, 7].
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Recently, quite large covalence is revealed for the Au-S bond in varies
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thiolate-protected gold nanoparticles and self-assembled monolayers [8]. However, little concerns are given to the copper-sulfur interactions study. One possible reason is
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that copper is more activated than gold in ambient conditions. From another point of view, activated copper has more application in real life and catalytic reactions, which
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should be concerned more in detailed copper-sulfur complexes in the gas phase. The interactions of noble metal atom with H2O have been extensively studied [9-20]. Both theoretical and experimental evidences suggest that M–(H2O) (M = Cu, Ag, Au) belong to a planar structure with the hydrogen atoms oriented toward the metal anion, whereas the neutral counterparts have the structure features of the oxygen atom oriented toward the metal atoms [10-15, 18]. Some spectroscopic and computational work has also been reported for CuOH–1/0 [11, 21-23]. Both neutral and 3
ACCEPTED MANUSCRIPT anion were characterized as obtuse bond angles [11, 21, 22]. Previous reported results about AuOH and AgOH have suggested that there are quite large geometric changes upon photodetachment with a displacement of ~0.15 Å in the AuOH– → AuOH and AgOH– → AgOH transitions [17, 20, 24]. The vibrational frequencies obtained in the experiment are mainly involved in M-O stretching mode (M = Au and Ag). For the
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completely understanding the geometric evolution trend upon photodetachment for
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the noble metal-OH complexes family, and for the comparison of bond nature
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difference between Cu and XH functional group (X = O and S), we have conducted anion photoelectron imaging experiment and theoretical investigation on CuXH (X=O
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and S) anions and neutral counterparts.
II. EXPERIMENTAL AND THEORETICAL METHODS
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The photoelectron velocity-map imaging system has been described in detail elsewhere and we only give a brief description here [25]. A small amount of CuOH–
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and CuSH– anions under current study are likely the products of secondary reactions
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through collision induced dissociation (CID) process in the reaction of copper anion with trace methanethiol or water in the presence of a supersonic beam of helium
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(99.999%) carrier gas. The anions were introduced to a McLaren-Wiley time-of-flight, mass selected, and crossed with a laser beam (Nd:YAG laser). The resulting
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photoelectrons were extracted by a velocity map imaging photoelectron spectrometer and recorded by a charge-coupled device camera. Each image was accumulated with 10 000–50 000 laser shots at 10 Hz repetition rate. The final raw image stood for the projection of the photoelectron density in the 3D laboratory frame onto the 2D imaging detector. The original 3D distribution was reconstructed using the Basis Set Expansion (BASEX) inverse Abel transform method [26], and the photoelectron spectrum was acquired. The photoelectron kinetic energy spectra were calibrated by 4
ACCEPTED MANUSCRIPT the known spectra of Cu– and S–. The photoelectron spectra (PES) were plotted against electron binding energy eBE = hν - eKE, where hν is the photon energy. The typical energy resolution was about 25 meV full width at half maximum (FWHM) at electron kinetic energy (eKE) of 1 eV (~2.5%). The photoelectron angular distribution (PAD) is obtained by integrating the
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intensity of the Abel-inverted image. The PADs in the one-photon process with
(1)
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I(θ) = k[1+ βP2(θ)]
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linearly polarized light are generally described by the function: [27, 28]
where θ is the angle between the electron velocity vector and the laser
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polarization direction in the laboratory frame, k is a normalization constant proportional to the total photodetachment cross-section, and P2 is the second-order
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Legendre polynomials. The angular dependence is completely defined by β, the anisotropy parameter, which can be determined by fitting eq. (1) to the experimental
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PAD.
The
augmented
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All theoretical calculations were carried out using the Gaussian09 package [29]. correlation-consistent
polarized
valence
triple-ζ
basis
set
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aug-cc-pVTZ-pp [30-32] with the relativistic effective small core pseudopotentials was used for the copper, silver, and gold atom, and aug-cc-pVTZ [33] for other atoms.
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The double-hybrid density functional theory (mPW2PLYP) and CCSD(T) methods are used to predict the geometric structures of anionic and neutral complexes [34], which has been successfully examined for benchmark study in similar systems [35]. Vibrational analysis was employed at the harmonic level to check it out whether the optimized structures were the true local minima or not. All the energies of the optimized structures were reevaluated at the level of coupled cluster CCSD(T) including zero-point vibrational energy (ZPVE) corrections [36]. The adiabatic 5
ACCEPTED MANUSCRIPT detachment energy (ADE) was defined as the energy of the origin transition between the ground state of the anion and the neutral, which also represents the electron affinity of neutral species. The vertical detachment energy (VDE) was defined as the energy difference between the ground state of the anion and the neutral at the anionic geometry. Natural resonance theory (NRT) [37-39] based on natural bond orbitals
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(NBO) method [40] and electron localization function (ELF) analyses [41] were
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performed to further understand the nature of the chemical bonding in CuXH–1/0 (X = O and S). For comparison in the ELF analyses, mPW2PLYP method is used to predict
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the geometric structures for MXH–1/0 (M=Cu, Ag, and Au; X = O and S) complexes.
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III. RESULTS AND DISCUSSIONS _
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a)CuOH
0.4
0.8
1.2
1.6
2.0
1.2
1.6
2.0
b)CuSH
0.4
0.8
Electron Binding Energy (eV)
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_
Fig. 1. Photoelectron images (left columns) and spectra (right columns) for (a) CuOH–
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and (b) CuSH– obtained at 532 nm. The left side shows the raw photoelectron image (left) and the reconstructed one (right) after inverse Abel transformation. Each photoelectron velocity-image consists of raw image (left part) and the reconstructed image (right part) after inverse Abel transformation. The double arrow shows the direction of the laser polarization.
6
ACCEPTED MANUSCRIPT The photoelectron velocity map imaging of CuOH– and CuSH– are displayed in Fig. 1 and exhibit clear-cut vibrational structure. Based on the averaged peak-spacing, the vibrational frequencies are measured to be 629(32) cm-1 and 387(24) cm-1 for CuOH and CuSH, respectively. From 0-0 vibrational transitions, we deduced the ADE of each anion, to be 0.995(12) and 1.098(12) eV for CuOH– and CuSH–, respectively.
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The corresponding VDEs, determined from each band maximum, are 0.995(12) and
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1.145(12) eV for CuOH– and CuSH–, respectively (Table 1). The single sequence of
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vibrational peaks possibly implies that only one vibrational mode is activated for each species upon photodetachment as will be evidenced in the following Franck-Condon
Anion
Neutral
(0.419)
1A'
(0.445)
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2A'
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simulations and borne out from ab initio calculations.
1. 758 (0.778)1. 766 (-1.224)
1. 846 (-0.151)1. 788 (-1.268)
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(0.099)
1A'
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2A'
(0.123)
2.092 (0.601) 2.120 (-0.724)
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2.188 (-0.232) 2.216 (-0.867)
Fig. 2. Optimized structures of CuOH– and CuSH– as well as their neutral
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counterparts. Selected bond lengths (in Å) calculated at the level of mPW2PLYP/aug-cc-pVTZ(-pp) are indicated in black, while the bond lengths calculated
at the level of CCSD(T)/aug-cc-pVTZ(-pp) for CuOH–1/0 and CCSD(T)/aug-cc-pVDZ(-pp) –1/0
for CuSH
are indicated in italic and red. The NPA charges are labeled in
parentheses on Cu, O or S, and H atoms (blue) (See text for details).
7
ACCEPTED MANUSCRIPT _
a)CuOH
Exp. FC fit Stick
ν3
* 1.0
1.2
1.4
ν3
_
* 1.0
1.2
SC
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b)CuSH
0.8
1.6
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0.8
1.4
1.6
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Electron Binding Energy (eV)
Fig. 3. Franck–Condon (FC) simulation for the photodetachment of (a) CuOH─ and (b) 0.98 SCALE CuOH:260K 0.032ev
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0.030ev CuSH─. Black curve stands for CuSH:175K the experimental data, blue curves for Franck–Condon
(FC) simulated results, and red sticks for simulated vibronic transitions. An asterisk in
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each spectrum designates hot band transitions.
Theoretical calculations were carried out to elucidate the geometric and
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electronic properties of CuOH–1/0 and CuSH–1/0 species. All of them possess Cs symmetry and detailed geometric parameters are demonstrated in Fig. 2. When
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different methods (mPW2PLYP and CCSD(T)) are used, the Cu-X bond length is the predominant structure variation over the X-H bond length and ∠Cu-X-H (X = O and S), especially for anions. Compared the Cu-X bond calculated at the level of mPW2PLYP, CCSD(T) results show the significant decrease of the Cu-O bond length by 0.058 Å in CuOH–1 and increment of the Cu-S bond length by 0.028 Å in CuSH–1/0, respectively. The natural charge population analyses (NPA) are labeled in parentheses in Fig. 2. It indicates that the vast majority of charge (~93% for CuOH– and ~83% for 8
ACCEPTED MANUSCRIPT CuSH–) is removed from the Cu atom (-0.15 → 0.78 e in CuOH– → CuOH and -0.23 → 0.60 e in CuSH– → CuSH). This scenario is in accordance with molecular orbital analysis which reveals that the excess electron in CuOH– and CuSH– is detached from a singly occupied molecular orbital (SOMO). As shown in Fig. 4, this SOMO has a significant s-orbital (60% Cu(s) + 2% O(s) + 2% H(s) in CuOH– and 54%
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Cu(s) + 15% S(s) + 5% H(s) in CuSH–). Also the original orbital nature of detached
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electrons is borne out in anisotropy parameter, β. More concretely, the electron ejected
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from s orbital forms P wave, which corresponds to a positive β value [42] (herein, β ~
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1.7 for CuOH– and β ~ 1.0 for CuSH–).
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CuOH–
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SOMO
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CuSH–
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Fig. 4. The contour plots of the highest occupied molecular orbitals of the ground state of CuOH– and CuSH– calculated at the level of mPW2PLYP/aug-cc-pVTZ(-pp) (iso = 0.04 a.u.). (Blue and red colors stand for different phases of molecular orbital).
9
ACCEPTED MANUSCRIPT Table 1. Observed and Calculated adiabatic detachment energies (ADEs) and vertical detachment energies (VDEs) for the ground state of anionic and neutral CuXH─ (X=O and S) including ZPVEs (Unit: eV). Cal.
Expt.a State
A'
CuOH
1
A'
CuSH─
2
A'
CuSH
1
A'
VDE
ADE
VDE
0.995(12)
0.995(12)
0.960
1.011
1.098(12)
1.145(12)
1.071
ADE
1.117
VDE
0.504c
0.513c
1.070d
1.142d
Numbers in the parentheses are experimental uncertainties in the last digit.
b
mPW2PLYP
represents
the
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a
ADE
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2
CCSD(T)
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CuOH─
mPW2PLYPb
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Species
method
calculated
at
the
level
of
c
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CCSD(T)/aug-cc-pVTZ(-pp)//mPW2PLYP/aug-cc-pVTZ(-pp).
Both single point energy calculation and geometries optimization calculated at the level of
CCSD(T)/aug-cc-pVTZ(-pp). d
AC
CE
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D
CCSD(T)/aug-cc-pVTZ(-pp)//CCSD(T)/aug-cc-pVDZ(-pp)
10
ACCEPTED MANUSCRIPT Table 2. Calculated vibrational frequencies (scaled by 0.98) of CuXH (X=O and S) anions using the aug-cc-pVTZ-(pp) basis sets compared to experimental observations (cm-1). ν1, ν2, and ν3 represent X-H stretching, Cu-X-H bending, and Cu-X stretching modes, respectively. Numbers in the parentheses are experimental uncertainties in the last digit.
ν2
3733 643
Exp.
600
ν1
ν2
3757 780
580(32)
mPW2PLYP
2621
475
306
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CuSH
ν3
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CuOH mPW2PLYP
ν1
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Species/Method
Neutral
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Anion
305(32)
631 629(32) 395 387(24)
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Exp.
2639 607
ν3
To aid in the spectral assignment, we conducted Franck-Condon simulations on
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both cases with the PESCAL program which is based on harmonic oscillator
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approximation including Duschinsky rotation via the Rosenstock-Chen method to calculate Franck-Condon factors [43] and present the results in Fig. 3. The individual
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vibrational band contours are generated using Gaussian line shapes with a full width at half maxima (FWHM) of 32 meV for CuOH─ and 30 meV for for CuSH─.
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Simulations were run including all normal modes and the simulated vibrational temperature of the anion was obtained at ∼260 K for CuOH─ and ∼180 K for CuSH─ to yield a best match between the simulated and experimental spectra. Theoretical harmonic frequencies of neutrals were scaled to match the experimental frequencies, with scaling factors of 0.98, and the origin of the simulated spectrum was shifted to the experimental band origin. For qualitatively evaluating vibrational frequencies, we adjust the normal mode displacement vectors to fit the experimental spectra on the 11
ACCEPTED MANUSCRIPT basis of theoretical Franck-Condon simulations. As revealed by simulation, Cu-X (X=O and S) stretching mode ν3 has the dominant effect on the spectra and vibrational frequencies of anion are extracted (580(32) cm-1 with Cu-O stretching mode in CuOH─ and 305(32) cm-1 with Cu-S stretching mode in CuSH─). In term of simulation, the adiabatic electron affinities are obtained to be 0.995(12) eV for
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CuOH─ and 1.098(12) eV for CuSH─, which are in excellent agreement with the
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theoretical values of 0.960 eV for CuOH─ and 1.071 eV for CuSH─ calculated at the level of CCSD(T)/aug-cc-pVTZ(-pp)//mPW2PLYP/aug-cc-pVTZ(-pp), respectively (Table 1).
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However, one exception is CuOH─, of which the ADE and VDE using CCSD(T)
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method are in poor agreement with the experimental ones, respectively. The vibrational frequencies in the photoelectron spectra of neutral counterparts are
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dominated by the Cu-O or Cu-S stretching mode (ν3), which are determined to be 629(32) cm-1 for CuOH and 387(24) cm-1 for CuSH. This situation is consistent with
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relatively large bond length displacement as shown in Fig. 2 (0.088 Å for the Cu-O
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bond and 0.096 Å for the Cu-S bond upon detachment of the excess electron). All the
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theoretical vibrational frequencies and experimental ones are displayed in Table 2.
Table 3. Calculated singly occupied molecular orbital (SOMO) compositions at the
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level of mPW2PLYP/aug-cc-pVTZ(-pp) level of CuOH– and CuSH–.
MO
MO energy level (eV)
MO pop. analysis: % M character Cu
X=O or S
H
2(s)+5(p)
5(s)
CuOH– SOMO
0.11
60(s)+27(p)+1(d) CuSH–
SOMO
-0.01
54(s)+12(p)+1(d) 15(s)+12(p) 12
5(s)
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Chemical bonding nature in the CuOH– and CuSH– complexes can be qualitatively inferred from molecular orbital (MO) contours as depicted in Fig. 4. Strong covalent character of Cu-S bond in CuSH–1 in contrast to Cu-O bond in CuOH–1 are borne out in SOMO profile (Fig. 4 and Table 3), where Cu s and p
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orbitals (66% s and p orbitals) more greatly overlap with S s and p orbitals (27% s and
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p orbitals) to form antibonding σ* in contrast to the formation of antibonding σ*
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bonding in CuOH–1 (87% Cu s and p orbitals and 7% O s and p orbitals).
NAO
Mayer
0.370
0.621
0.455
1.006
0.574
0.642
0.718
1.202
Table 4. Theoretical Cu-X (X = O and S) bond orders at the level of mPW2PLYP. Wiberg
anion
0.248
neutral
0.427
anion
0.404
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Bond order
0.706
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neutral
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Cu-SH
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Cu-OH
To gain more insights into the chemical bonding difference between the CuOH–
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and CuSH–, we employed bond orders calculation based on various theoretical schemes. As listed in Table 4, three methods give a larger Cu–S bond order in CuSH– relative to CuOH–. These results also give strong evidence that Cu-S or Cu-O bond orders in neutrals is nearly 2 times of that in anions (Wiberg and Mayer bond orders), which is in accordance with the classic chemical bond order trend that excess an electron in σ* bonding reduces the bond order. Natural resonance theory (NRT) is a theoretical method based on quantum chemical calculations to describe molecules 13
ACCEPTED MANUSCRIPT with significant resonance structures in terms of classic valence-bond concepts. It provides detailed covalent and ionic electrovalent contributions for CuOH–1/0 or CuSH–1/0 complexes. As shown in Table 5, it is found that the covalent contributions to the Cu–O bond in CuOH– and Cu-S bond in CuSH– are 0.20 and 0.26, respectively, while it increases to 0.35 for Cu-S bond in CuSH. Thus, excess electron largely
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influences the covalent contributions in CuSH– in contrast to CuOH– where nearly no
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change occurs. The chemical bonding can be further glimpsed from the electron
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localization functions (ELFs), which is a visual tool to estimate the probability of finding electron pairs in space, and an ELF analysis can show the difference among
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covalent bonds, ionic bonds, and lone pairs [44, 45]. As displayed in Fig. 5a-d, a subtle increase of electron pairing density between the Cu and S atoms exists in
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CuSH– compared to CuOH–, whereas more stronger electron pairing density is found in Fig. 5d for CuSH. The covalent interaction between Cu and X ligand (X = O and S)
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is more clearly illustrated in the one-dimensional projections of electron localization
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functions along the Cu-X bond axis (X = O and S) presented in Fig. 5e and Fig. 5f (i.e. electron pairing density: 0.110 and 0.135 a.u. for CuOH─ and CuOH, respectively;
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electron pairing density: 0.143 and 0.173 a.u. for CuSH─ and CuSH, respectively). The observations are in consistent with the evolutions analyzed from MO contours
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and chemical bond orders. It is interesting to fully understanding the covalent feature of CuXH-1/0 (X = O and S) and its Ag and Au analogs. As displayed in Fig. 6 (also compared with that in Fig. 5), it reveals that M-S (M = Cu, Ag, Au) bond has more covalent characters than the M-O (M = Cu, Ag, Au) bond both in anions and neutrals, and considerable electron pairing density exists between M-S (M = Cu, Ag, Au) bonds with the strongest covalent character in AuSH. 14
ACCEPTED MANUSCRIPT Table 5. Summary of natural resonance theory (NRT) and covalent and ionic electrovalent contributions of the optimized structures of [CuXH]─ (X = O and S)
NRT bond order
% covalent
% ionic
[Cu-OH]−
0.5011
0.1006c + 0.4006i
20.08
79.92
[Cu-OH]
1.0000
0.1958c + 0.8042i
19.58
80.42
[Cu-SH]−
0.5017
0.1315c + 0.3702i
26.21
73.79
[Cu-SH]
1.0031
0.3478c + 0.6554i
34.67
65.33
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RI
T(NRT)a
Total NRT bond order is the sum of covalent (c) plus ionic (i) bond order.
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a
Species
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species.
a) CuOH–
c) CuSH–
H
O
b) CuOH
Cu
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H Cu
S
d) CuSH H
D
H
Cu
PT E (a.u.) Value(a.u.) Value
CE
1.0 1.0 e) CuOH-1/0 0.8 0.8
S
anion neutral
0.6 0.6 0.4 0.4 0.2 0.2 0.0 0.0
1.0 1.0 (a.u.) Value(a.u.) Value
AC
Cu
O
0.8 0.8
0.135 0.1100.135 0.110
Position O Cu Position (Bohr) (Bohr) f)
CuSH-1/0
anion neutral
0.6 0.6 0.4 0.4 0.2 0.2 0.0 0.0
Cu
0.143 0.143
0.173 0.173
S
Position Position (Bohr) (Bohr)
Fig. 5. The electron localization functions (ELF) for (a) CuOH−, (b) CuOH, (c) CuSH−, and (d) CuSH. And one-dimensional projections between Cu-O or Cu-S bond for CuOH–1/0 or CuSH–1/0 are illustrated in (e) and (f) figures, respectively (Unit: a.u.). 15
ACCEPTED MANUSCRIPT
a) AgOH–
H
H O
Ag
H
H O
Au
c) AgOH
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g) AgSH
H
H O
Ag
S
h) AuSH
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d) AuOH H O
H
Au
S
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D
Au
S
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Ag
PT
f) AuSH–
b) AuOH–
Au
S
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Ag
e) AgSH–
Fig. 6. The electron localization functions (ELF) for (a) AgOH−, (b) AuOH−, (c)
AC
CE
AgOH, (d) AuOH, (e) AgSH−, (f) AuSH−, (g) AgSH, and (h) AuSH (Unit: a.u.).
IV. CONCLUSIONS We have investigated spectral and chemical bonding properties of basic unit of CuOH−1/0 and CuSH−1/0 via a joint of high-resolution velocity-map imaging photoelectron spectroscopy and theoretical model. The ADEs of these anionic complexes have been measured to be 0.995(12) eV and 1.098(12) eV for CuOH─ and CuSH─, respectively. In addition, analysis of experimental spectra yields the ν3 of 629(32) and 387(24) for CuOH and CuSH, respectively. Extensively chemical 16
ACCEPTED MANUSCRIPT bonding analyses indicate that subtle evolution of covalent properties are affected by the coordinate atoms (O or S atom in this work) with copper and charge state. More covalent bond nature is found in Cu-S bond and neutral state (CuSH).
ACKNOWLEDGMENTS
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This work is supported by the National Science Foundation of China (Grant No.
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21273233 11674003, 61475001, and 21503003), the Ministry of Science and
SC
Technology of China (Grant No. 2011YQ09000505), Anhui Natural Science Foundation (Grant No. 1608085QA10), Anhui University Natural Science Foundation
NU
(Grant No. KJ2015A032), and Startup Foundation for doctors in Anhui Normal University. We also acknowledge additional support from Special Program for
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Applied Research on Super Computation of the NSFC-Guangdong Joint Fund (the
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CE
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D
second phase) and Super Computation center of Shenzhen.
17
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ACCEPTED MANUSCRIPT [18] D.-Y. Wu, S. Duan, X.-M. Liu, Y.-C. Xu, Y.-X. Jiang, B. Ren, X. Xu, S.H. Lin, Z.-Q. Tian, J. Phys. Chem. A, 112 (2008) 1313-1321. [19] Y. Gao, W. Huang, J. Woodford, L.-S. Wang, X.C. Zeng, J. Am. Chem. Soc., 131 (2009) 9484-9485. [20] C.X. Chi, H. Xie, Y.Z. Li, R. Cong, M.F. Zhou, Z.C. Tang, J. Phys. Chem. A, 115
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Lawrance, G.F. Metha, Chem. Phys. Lett., 625 (2015) 164-167. [25] Z. Qin, X. Wu, Z. Tang, Rev. Sci. Instrum., 84 (2013) 066108.
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[29] M.J. Frisch, G.W. Trucks, H.B. Schlegel and e. al., Gaussian 09, revision D.01.
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ACCEPTED MANUSCRIPT [34] T. Schwabe, S. Grimme, Phys. Chem. Chem. Phys., 8 (2006) 4398. [35] Z. Qin, Z. Liu, R. Cong, H. Xie, Z. Tang, H. Fan, J. Chem. Phys., 140 (2014) 114307. [36] G.E. Scuseria, C.L. Janssen, H.F. Schaefer Iii, J. Chem. Phys., 89 (1988) 7382-7387.
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[40] A.E. Reed, L.A. Curtiss, F. Weinhold, Chem. Rev., 88 (1988) 899-926. [41] T. Lu, F. Chen, J. Comput. Chem., 33 (2012) 580-592.
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Angew. Chem., Int. Ed., 31 (1992) 187-188.
20
ACCEPTED MANUSCRIPT _
a)CuOH
Exp. FC fit Stick
ν3
*Graphical abstract 0.8 a)CuOH
0.8
1.0
1.2
1.4
1.6 0.8
1.0
1.2
1.4
Electron Binding Energy (eV) 0.98 SCALE CuOH:260K 0.032ev CuSH:175K 0.030ev
1.0
1.2
1.4
1.6
Electron Binding Energy (eV)
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D
MA
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0.98 SCALE CuOH:260K 0.032ev CuSH:175K 0.030ev
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0.8
21
1.6
ν3
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b)CuSH
1.4
b)CuSH
ν3
_
1.2
_
Exp. FC fit Stick
ν3
1.0
1.6
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_
ACCEPTED MANUSCRIPT *Highlights
Electron affinities and vibrational frequencies of neutral CuOH and CuSH were accurately measured and assigned by combining the electron velocity map imaging spectroscopy and theoretical calculations.
Parallel transition properties of photoelectron angular distributions (PADs) for
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both species are correlated to the Cu atom s orbital and partial s orbital in other
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Chemical bonding analyses indicate that a trend of weak covalent behavior is
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D
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investigated in CuOH–1/0 and CuSH–1/0 systems.
AC
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atoms.
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Zhengbo Qin, Hui Wang, Yangdi Ren, Xianfeng Zheng, Zhifeng Cui, Zichao Tang PII: DOI: Reference:
S1386-1425(17)30516-4 doi: 10.1016/j.saa.2017.06.039 SAA 15255
To appear in:
Spectrochimica Acta Part A: Molecular and Biomolecular Spectroscopy
Received date: Revised date: Accepted date:
15 February 2017 27 June 2017 30 June 2017
Please cite this article as: Zhengbo Qin, Hui Wang, Yangdi Ren, Xianfeng Zheng, Zhifeng Cui, Zichao Tang , Electron velocity map imaging and theoretical study on CuXH (X=O and S) anions, Spectrochimica Acta Part A: Molecular and Biomolecular Spectroscopy (2017), doi: 10.1016/j.saa.2017.06.039
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ACCEPTED MANUSCRIPT Electron velocity map imaging and theoretical study on CuXH (X=O and S) anions
Zhengbo Qina,, Hui Wanga, Yangdi Rena, Xianfeng Zhenga, and Zhifeng Cuia, and
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a
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Zichao Tangb,,
Anhui Province Key Laboratory of Optoelectric Materials Science and Technology,
b
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Department of Physics, Anhui Normal University, Wuhu, Anhui 241000, China
State Key Laboratory of Physical Chemistry of Solid Surfaces, Department of
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Chemistry, College of Chemistry and Chemical Engineering, Xiamen University,
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Xiamen 361005, China
*
Corresponding authors: Email: [email protected] (Z.B.Q.), [email protected]
(Z.C.T.)
1
ACCEPTED MANUSCRIPT ABSTRACT Vibrationally resolved photoelectron spectra of CuOH– and CuSH– have been determined via velocity map imaging method to investigate the transitions of X1A'← X2A' at 532 nm. Adiabatic detachment energies of CuOH– and CuSH– are assigned to 0.995(12) and 1.098(12) eV, respectively. Combined theoretical calculations with
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Franck-Condon simulations, it allows extracting the vibrational frequencies in neutral,
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which yields 629(32) cm-1 with Cu-O stretching mode and 387(24) cm-1 with Cu-S
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stretching mode for CuXH (X = O and S). Parallel transition properties of photoelectron angular distributions (PADs) for both species are correlated to the
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photodetachment of SOMO orbitals, which mainly involved in the Cu atom s orbital and partial s orbital in other atoms. Based on chemical bonding analyses (Wiberg,
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NAO, Mayer, NRT, and ELF), it is suggested that a trend is observed with a subtle variation of covalent component from weak covalent behavior between Cu-O in
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CuOH–1/0 to stronger covalent bonding between Cu-S in CuSH–1/0 (especially for
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non-ignorable covalent component in CuSH species) though ionic bonding dominates
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both in Cu-O and Cu-S bonds for the two systems.
2
ACCEPTED MANUSCRIPT I. INTRODUCTION There are many studies on the noble metal catalysis on water to produce hydrogen and hydroxyl groups [1]. One process possibly includes dissociated OH fragment binding or migrating on surface. In copper surface catalysis process, H2O (or H2S) adsorption on the surface may become to dissociative chemical adsorption [2-5].
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OH or SH fragments may be bonding or migrating on a specific active site. Studying
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the chemical binding capabilities between copper and those functional groups is
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significant for understanding surface chemical reaction for copper atom interacting with H2O and H2S etc. solvent molecules. In the gas phase, the bond properties
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between the basic unit Cu atom and these functional groups are less well known. The interaction of the thiols with noble metal surfaces and interfaces (especially
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for gold) is of considerable interest for the design of new functional materials in molecular electronics, surface modification and heterogeneous catalysis [6, 7].
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Recently, quite large covalence is revealed for the Au-S bond in varies
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thiolate-protected gold nanoparticles and self-assembled monolayers [8]. However, little concerns are given to the copper-sulfur interactions study. One possible reason is
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that copper is more activated than gold in ambient conditions. From another point of view, activated copper has more application in real life and catalytic reactions, which
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should be concerned more in detailed copper-sulfur complexes in the gas phase. The interactions of noble metal atom with H2O have been extensively studied [9-20]. Both theoretical and experimental evidences suggest that M–(H2O) (M = Cu, Ag, Au) belong to a planar structure with the hydrogen atoms oriented toward the metal anion, whereas the neutral counterparts have the structure features of the oxygen atom oriented toward the metal atoms [10-15, 18]. Some spectroscopic and computational work has also been reported for CuOH–1/0 [11, 21-23]. Both neutral and 3
ACCEPTED MANUSCRIPT anion were characterized as obtuse bond angles [11, 21, 22]. Previous reported results about AuOH and AgOH have suggested that there are quite large geometric changes upon photodetachment with a displacement of ~0.15 Å in the AuOH– → AuOH and AgOH– → AgOH transitions [17, 20, 24]. The vibrational frequencies obtained in the experiment are mainly involved in M-O stretching mode (M = Au and Ag). For the
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completely understanding the geometric evolution trend upon photodetachment for
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the noble metal-OH complexes family, and for the comparison of bond nature
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difference between Cu and XH functional group (X = O and S), we have conducted anion photoelectron imaging experiment and theoretical investigation on CuXH (X=O
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and S) anions and neutral counterparts.
II. EXPERIMENTAL AND THEORETICAL METHODS
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The photoelectron velocity-map imaging system has been described in detail elsewhere and we only give a brief description here [25]. A small amount of CuOH–
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and CuSH– anions under current study are likely the products of secondary reactions
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through collision induced dissociation (CID) process in the reaction of copper anion with trace methanethiol or water in the presence of a supersonic beam of helium
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(99.999%) carrier gas. The anions were introduced to a McLaren-Wiley time-of-flight, mass selected, and crossed with a laser beam (Nd:YAG laser). The resulting
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photoelectrons were extracted by a velocity map imaging photoelectron spectrometer and recorded by a charge-coupled device camera. Each image was accumulated with 10 000–50 000 laser shots at 10 Hz repetition rate. The final raw image stood for the projection of the photoelectron density in the 3D laboratory frame onto the 2D imaging detector. The original 3D distribution was reconstructed using the Basis Set Expansion (BASEX) inverse Abel transform method [26], and the photoelectron spectrum was acquired. The photoelectron kinetic energy spectra were calibrated by 4
ACCEPTED MANUSCRIPT the known spectra of Cu– and S–. The photoelectron spectra (PES) were plotted against electron binding energy eBE = hν - eKE, where hν is the photon energy. The typical energy resolution was about 25 meV full width at half maximum (FWHM) at electron kinetic energy (eKE) of 1 eV (~2.5%). The photoelectron angular distribution (PAD) is obtained by integrating the
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intensity of the Abel-inverted image. The PADs in the one-photon process with
(1)
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I(θ) = k[1+ βP2(θ)]
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linearly polarized light are generally described by the function: [27, 28]
where θ is the angle between the electron velocity vector and the laser
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polarization direction in the laboratory frame, k is a normalization constant proportional to the total photodetachment cross-section, and P2 is the second-order
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Legendre polynomials. The angular dependence is completely defined by β, the anisotropy parameter, which can be determined by fitting eq. (1) to the experimental
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PAD.
The
augmented
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All theoretical calculations were carried out using the Gaussian09 package [29]. correlation-consistent
polarized
valence
triple-ζ
basis
set
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aug-cc-pVTZ-pp [30-32] with the relativistic effective small core pseudopotentials was used for the copper, silver, and gold atom, and aug-cc-pVTZ [33] for other atoms.
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The double-hybrid density functional theory (mPW2PLYP) and CCSD(T) methods are used to predict the geometric structures of anionic and neutral complexes [34], which has been successfully examined for benchmark study in similar systems [35]. Vibrational analysis was employed at the harmonic level to check it out whether the optimized structures were the true local minima or not. All the energies of the optimized structures were reevaluated at the level of coupled cluster CCSD(T) including zero-point vibrational energy (ZPVE) corrections [36]. The adiabatic 5
ACCEPTED MANUSCRIPT detachment energy (ADE) was defined as the energy of the origin transition between the ground state of the anion and the neutral, which also represents the electron affinity of neutral species. The vertical detachment energy (VDE) was defined as the energy difference between the ground state of the anion and the neutral at the anionic geometry. Natural resonance theory (NRT) [37-39] based on natural bond orbitals
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(NBO) method [40] and electron localization function (ELF) analyses [41] were
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performed to further understand the nature of the chemical bonding in CuXH–1/0 (X = O and S). For comparison in the ELF analyses, mPW2PLYP method is used to predict
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the geometric structures for MXH–1/0 (M=Cu, Ag, and Au; X = O and S) complexes.
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III. RESULTS AND DISCUSSIONS _
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a)CuOH
0.4
0.8
1.2
1.6
2.0
1.2
1.6
2.0
b)CuSH
0.4
0.8
Electron Binding Energy (eV)
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_
Fig. 1. Photoelectron images (left columns) and spectra (right columns) for (a) CuOH–
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and (b) CuSH– obtained at 532 nm. The left side shows the raw photoelectron image (left) and the reconstructed one (right) after inverse Abel transformation. Each photoelectron velocity-image consists of raw image (left part) and the reconstructed image (right part) after inverse Abel transformation. The double arrow shows the direction of the laser polarization.
6
ACCEPTED MANUSCRIPT The photoelectron velocity map imaging of CuOH– and CuSH– are displayed in Fig. 1 and exhibit clear-cut vibrational structure. Based on the averaged peak-spacing, the vibrational frequencies are measured to be 629(32) cm-1 and 387(24) cm-1 for CuOH and CuSH, respectively. From 0-0 vibrational transitions, we deduced the ADE of each anion, to be 0.995(12) and 1.098(12) eV for CuOH– and CuSH–, respectively.
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The corresponding VDEs, determined from each band maximum, are 0.995(12) and
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1.145(12) eV for CuOH– and CuSH–, respectively (Table 1). The single sequence of
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vibrational peaks possibly implies that only one vibrational mode is activated for each species upon photodetachment as will be evidenced in the following Franck-Condon
Anion
Neutral
(0.419)
1A'
(0.445)
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2A'
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simulations and borne out from ab initio calculations.
1. 758 (0.778)1. 766 (-1.224)
1. 846 (-0.151)1. 788 (-1.268)
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(0.099)
1A'
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2A'
(0.123)
2.092 (0.601) 2.120 (-0.724)
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2.188 (-0.232) 2.216 (-0.867)
Fig. 2. Optimized structures of CuOH– and CuSH– as well as their neutral
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counterparts. Selected bond lengths (in Å) calculated at the level of mPW2PLYP/aug-cc-pVTZ(-pp) are indicated in black, while the bond lengths calculated
at the level of CCSD(T)/aug-cc-pVTZ(-pp) for CuOH–1/0 and CCSD(T)/aug-cc-pVDZ(-pp) –1/0
for CuSH
are indicated in italic and red. The NPA charges are labeled in
parentheses on Cu, O or S, and H atoms (blue) (See text for details).
7
ACCEPTED MANUSCRIPT _
a)CuOH
Exp. FC fit Stick
ν3
* 1.0
1.2
1.4
ν3
_
* 1.0
1.2
SC
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b)CuSH
0.8
1.6
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0.8
1.4
1.6
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Electron Binding Energy (eV)
Fig. 3. Franck–Condon (FC) simulation for the photodetachment of (a) CuOH─ and (b) 0.98 SCALE CuOH:260K 0.032ev
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0.030ev CuSH─. Black curve stands for CuSH:175K the experimental data, blue curves for Franck–Condon
(FC) simulated results, and red sticks for simulated vibronic transitions. An asterisk in
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each spectrum designates hot band transitions.
Theoretical calculations were carried out to elucidate the geometric and
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electronic properties of CuOH–1/0 and CuSH–1/0 species. All of them possess Cs symmetry and detailed geometric parameters are demonstrated in Fig. 2. When
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different methods (mPW2PLYP and CCSD(T)) are used, the Cu-X bond length is the predominant structure variation over the X-H bond length and ∠Cu-X-H (X = O and S), especially for anions. Compared the Cu-X bond calculated at the level of mPW2PLYP, CCSD(T) results show the significant decrease of the Cu-O bond length by 0.058 Å in CuOH–1 and increment of the Cu-S bond length by 0.028 Å in CuSH–1/0, respectively. The natural charge population analyses (NPA) are labeled in parentheses in Fig. 2. It indicates that the vast majority of charge (~93% for CuOH– and ~83% for 8
ACCEPTED MANUSCRIPT CuSH–) is removed from the Cu atom (-0.15 → 0.78 e in CuOH– → CuOH and -0.23 → 0.60 e in CuSH– → CuSH). This scenario is in accordance with molecular orbital analysis which reveals that the excess electron in CuOH– and CuSH– is detached from a singly occupied molecular orbital (SOMO). As shown in Fig. 4, this SOMO has a significant s-orbital (60% Cu(s) + 2% O(s) + 2% H(s) in CuOH– and 54%
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Cu(s) + 15% S(s) + 5% H(s) in CuSH–). Also the original orbital nature of detached
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electrons is borne out in anisotropy parameter, β. More concretely, the electron ejected
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from s orbital forms P wave, which corresponds to a positive β value [42] (herein, β ~
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1.7 for CuOH– and β ~ 1.0 for CuSH–).
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CuOH–
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SOMO
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CuSH–
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Fig. 4. The contour plots of the highest occupied molecular orbitals of the ground state of CuOH– and CuSH– calculated at the level of mPW2PLYP/aug-cc-pVTZ(-pp) (iso = 0.04 a.u.). (Blue and red colors stand for different phases of molecular orbital).
9
ACCEPTED MANUSCRIPT Table 1. Observed and Calculated adiabatic detachment energies (ADEs) and vertical detachment energies (VDEs) for the ground state of anionic and neutral CuXH─ (X=O and S) including ZPVEs (Unit: eV). Cal.
Expt.a State
A'
CuOH
1
A'
CuSH─
2
A'
CuSH
1
A'
VDE
ADE
VDE
0.995(12)
0.995(12)
0.960
1.011
1.098(12)
1.145(12)
1.071
ADE
1.117
VDE
0.504c
0.513c
1.070d
1.142d
Numbers in the parentheses are experimental uncertainties in the last digit.
b
mPW2PLYP
represents
the
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a
ADE
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2
CCSD(T)
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CuOH─
mPW2PLYPb
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Species
method
calculated
at
the
level
of
c
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CCSD(T)/aug-cc-pVTZ(-pp)//mPW2PLYP/aug-cc-pVTZ(-pp).
Both single point energy calculation and geometries optimization calculated at the level of
CCSD(T)/aug-cc-pVTZ(-pp). d
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CCSD(T)/aug-cc-pVTZ(-pp)//CCSD(T)/aug-cc-pVDZ(-pp)
10
ACCEPTED MANUSCRIPT Table 2. Calculated vibrational frequencies (scaled by 0.98) of CuXH (X=O and S) anions using the aug-cc-pVTZ-(pp) basis sets compared to experimental observations (cm-1). ν1, ν2, and ν3 represent X-H stretching, Cu-X-H bending, and Cu-X stretching modes, respectively. Numbers in the parentheses are experimental uncertainties in the last digit.
ν2
3733 643
Exp.
600
ν1
ν2
3757 780
580(32)
mPW2PLYP
2621
475
306
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CuSH
ν3
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CuOH mPW2PLYP
ν1
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Species/Method
Neutral
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Anion
305(32)
631 629(32) 395 387(24)
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Exp.
2639 607
ν3
To aid in the spectral assignment, we conducted Franck-Condon simulations on
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both cases with the PESCAL program which is based on harmonic oscillator
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approximation including Duschinsky rotation via the Rosenstock-Chen method to calculate Franck-Condon factors [43] and present the results in Fig. 3. The individual
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vibrational band contours are generated using Gaussian line shapes with a full width at half maxima (FWHM) of 32 meV for CuOH─ and 30 meV for for CuSH─.
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Simulations were run including all normal modes and the simulated vibrational temperature of the anion was obtained at ∼260 K for CuOH─ and ∼180 K for CuSH─ to yield a best match between the simulated and experimental spectra. Theoretical harmonic frequencies of neutrals were scaled to match the experimental frequencies, with scaling factors of 0.98, and the origin of the simulated spectrum was shifted to the experimental band origin. For qualitatively evaluating vibrational frequencies, we adjust the normal mode displacement vectors to fit the experimental spectra on the 11
ACCEPTED MANUSCRIPT basis of theoretical Franck-Condon simulations. As revealed by simulation, Cu-X (X=O and S) stretching mode ν3 has the dominant effect on the spectra and vibrational frequencies of anion are extracted (580(32) cm-1 with Cu-O stretching mode in CuOH─ and 305(32) cm-1 with Cu-S stretching mode in CuSH─). In term of simulation, the adiabatic electron affinities are obtained to be 0.995(12) eV for
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CuOH─ and 1.098(12) eV for CuSH─, which are in excellent agreement with the
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theoretical values of 0.960 eV for CuOH─ and 1.071 eV for CuSH─ calculated at the level of CCSD(T)/aug-cc-pVTZ(-pp)//mPW2PLYP/aug-cc-pVTZ(-pp), respectively (Table 1).
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However, one exception is CuOH─, of which the ADE and VDE using CCSD(T)
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method are in poor agreement with the experimental ones, respectively. The vibrational frequencies in the photoelectron spectra of neutral counterparts are
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dominated by the Cu-O or Cu-S stretching mode (ν3), which are determined to be 629(32) cm-1 for CuOH and 387(24) cm-1 for CuSH. This situation is consistent with
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relatively large bond length displacement as shown in Fig. 2 (0.088 Å for the Cu-O
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bond and 0.096 Å for the Cu-S bond upon detachment of the excess electron). All the
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theoretical vibrational frequencies and experimental ones are displayed in Table 2.
Table 3. Calculated singly occupied molecular orbital (SOMO) compositions at the
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level of mPW2PLYP/aug-cc-pVTZ(-pp) level of CuOH– and CuSH–.
MO
MO energy level (eV)
MO pop. analysis: % M character Cu
X=O or S
H
2(s)+5(p)
5(s)
CuOH– SOMO
0.11
60(s)+27(p)+1(d) CuSH–
SOMO
-0.01
54(s)+12(p)+1(d) 15(s)+12(p) 12
5(s)
ACCEPTED MANUSCRIPT
Chemical bonding nature in the CuOH– and CuSH– complexes can be qualitatively inferred from molecular orbital (MO) contours as depicted in Fig. 4. Strong covalent character of Cu-S bond in CuSH–1 in contrast to Cu-O bond in CuOH–1 are borne out in SOMO profile (Fig. 4 and Table 3), where Cu s and p
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orbitals (66% s and p orbitals) more greatly overlap with S s and p orbitals (27% s and
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p orbitals) to form antibonding σ* in contrast to the formation of antibonding σ*
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bonding in CuOH–1 (87% Cu s and p orbitals and 7% O s and p orbitals).
NAO
Mayer
0.370
0.621
0.455
1.006
0.574
0.642
0.718
1.202
Table 4. Theoretical Cu-X (X = O and S) bond orders at the level of mPW2PLYP. Wiberg
anion
0.248
neutral
0.427
anion
0.404
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Bond order
0.706
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neutral
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Cu-SH
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Cu-OH
To gain more insights into the chemical bonding difference between the CuOH–
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and CuSH–, we employed bond orders calculation based on various theoretical schemes. As listed in Table 4, three methods give a larger Cu–S bond order in CuSH– relative to CuOH–. These results also give strong evidence that Cu-S or Cu-O bond orders in neutrals is nearly 2 times of that in anions (Wiberg and Mayer bond orders), which is in accordance with the classic chemical bond order trend that excess an electron in σ* bonding reduces the bond order. Natural resonance theory (NRT) is a theoretical method based on quantum chemical calculations to describe molecules 13
ACCEPTED MANUSCRIPT with significant resonance structures in terms of classic valence-bond concepts. It provides detailed covalent and ionic electrovalent contributions for CuOH–1/0 or CuSH–1/0 complexes. As shown in Table 5, it is found that the covalent contributions to the Cu–O bond in CuOH– and Cu-S bond in CuSH– are 0.20 and 0.26, respectively, while it increases to 0.35 for Cu-S bond in CuSH. Thus, excess electron largely
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influences the covalent contributions in CuSH– in contrast to CuOH– where nearly no
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change occurs. The chemical bonding can be further glimpsed from the electron
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localization functions (ELFs), which is a visual tool to estimate the probability of finding electron pairs in space, and an ELF analysis can show the difference among
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covalent bonds, ionic bonds, and lone pairs [44, 45]. As displayed in Fig. 5a-d, a subtle increase of electron pairing density between the Cu and S atoms exists in
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CuSH– compared to CuOH–, whereas more stronger electron pairing density is found in Fig. 5d for CuSH. The covalent interaction between Cu and X ligand (X = O and S)
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is more clearly illustrated in the one-dimensional projections of electron localization
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functions along the Cu-X bond axis (X = O and S) presented in Fig. 5e and Fig. 5f (i.e. electron pairing density: 0.110 and 0.135 a.u. for CuOH─ and CuOH, respectively;
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electron pairing density: 0.143 and 0.173 a.u. for CuSH─ and CuSH, respectively). The observations are in consistent with the evolutions analyzed from MO contours
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and chemical bond orders. It is interesting to fully understanding the covalent feature of CuXH-1/0 (X = O and S) and its Ag and Au analogs. As displayed in Fig. 6 (also compared with that in Fig. 5), it reveals that M-S (M = Cu, Ag, Au) bond has more covalent characters than the M-O (M = Cu, Ag, Au) bond both in anions and neutrals, and considerable electron pairing density exists between M-S (M = Cu, Ag, Au) bonds with the strongest covalent character in AuSH. 14
ACCEPTED MANUSCRIPT Table 5. Summary of natural resonance theory (NRT) and covalent and ionic electrovalent contributions of the optimized structures of [CuXH]─ (X = O and S)
NRT bond order
% covalent
% ionic
[Cu-OH]−
0.5011
0.1006c + 0.4006i
20.08
79.92
[Cu-OH]
1.0000
0.1958c + 0.8042i
19.58
80.42
[Cu-SH]−
0.5017
0.1315c + 0.3702i
26.21
73.79
[Cu-SH]
1.0031
0.3478c + 0.6554i
34.67
65.33
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T(NRT)a
Total NRT bond order is the sum of covalent (c) plus ionic (i) bond order.
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a
Species
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species.
a) CuOH–
c) CuSH–
H
O
b) CuOH
Cu
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H Cu
S
d) CuSH H
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H
Cu
PT E (a.u.) Value(a.u.) Value
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1.0 1.0 e) CuOH-1/0 0.8 0.8
S
anion neutral
0.6 0.6 0.4 0.4 0.2 0.2 0.0 0.0
1.0 1.0 (a.u.) Value(a.u.) Value
AC
Cu
O
0.8 0.8
0.135 0.1100.135 0.110
Position O Cu Position (Bohr) (Bohr) f)
CuSH-1/0
anion neutral
0.6 0.6 0.4 0.4 0.2 0.2 0.0 0.0
Cu
0.143 0.143
0.173 0.173
S
Position Position (Bohr) (Bohr)
Fig. 5. The electron localization functions (ELF) for (a) CuOH−, (b) CuOH, (c) CuSH−, and (d) CuSH. And one-dimensional projections between Cu-O or Cu-S bond for CuOH–1/0 or CuSH–1/0 are illustrated in (e) and (f) figures, respectively (Unit: a.u.). 15
ACCEPTED MANUSCRIPT
a) AgOH–
H
H O
Ag
H
H O
Au
c) AgOH
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g) AgSH
H
H O
Ag
S
h) AuSH
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d) AuOH H O
H
Au
S
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Au
S
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Ag
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f) AuSH–
b) AuOH–
Au
S
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Ag
e) AgSH–
Fig. 6. The electron localization functions (ELF) for (a) AgOH−, (b) AuOH−, (c)
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AgOH, (d) AuOH, (e) AgSH−, (f) AuSH−, (g) AgSH, and (h) AuSH (Unit: a.u.).
IV. CONCLUSIONS We have investigated spectral and chemical bonding properties of basic unit of CuOH−1/0 and CuSH−1/0 via a joint of high-resolution velocity-map imaging photoelectron spectroscopy and theoretical model. The ADEs of these anionic complexes have been measured to be 0.995(12) eV and 1.098(12) eV for CuOH─ and CuSH─, respectively. In addition, analysis of experimental spectra yields the ν3 of 629(32) and 387(24) for CuOH and CuSH, respectively. Extensively chemical 16
ACCEPTED MANUSCRIPT bonding analyses indicate that subtle evolution of covalent properties are affected by the coordinate atoms (O or S atom in this work) with copper and charge state. More covalent bond nature is found in Cu-S bond and neutral state (CuSH).
ACKNOWLEDGMENTS
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This work is supported by the National Science Foundation of China (Grant No.
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21273233 11674003, 61475001, and 21503003), the Ministry of Science and
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Technology of China (Grant No. 2011YQ09000505), Anhui Natural Science Foundation (Grant No. 1608085QA10), Anhui University Natural Science Foundation
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(Grant No. KJ2015A032), and Startup Foundation for doctors in Anhui Normal University. We also acknowledge additional support from Special Program for
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Applied Research on Super Computation of the NSFC-Guangdong Joint Fund (the
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D
second phase) and Super Computation center of Shenzhen.
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ACCEPTED MANUSCRIPT _
a)CuOH
Exp. FC fit Stick
ν3
*Graphical abstract 0.8 a)CuOH
0.8
1.0
1.2
1.4
1.6 0.8
1.0
1.2
1.4
Electron Binding Energy (eV) 0.98 SCALE CuOH:260K 0.032ev CuSH:175K 0.030ev
1.0
1.2
1.4
1.6
Electron Binding Energy (eV)
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CE
PT E
D
MA
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0.98 SCALE CuOH:260K 0.032ev CuSH:175K 0.030ev
SC
0.8
21
1.6
ν3
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b)CuSH
1.4
b)CuSH
ν3
_
1.2
_
Exp. FC fit Stick
ν3
1.0
1.6
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_
ACCEPTED MANUSCRIPT *Highlights
Electron affinities and vibrational frequencies of neutral CuOH and CuSH were accurately measured and assigned by combining the electron velocity map imaging spectroscopy and theoretical calculations.
Parallel transition properties of photoelectron angular distributions (PADs) for
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both species are correlated to the Cu atom s orbital and partial s orbital in other
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Chemical bonding analyses indicate that a trend of weak covalent behavior is
CE
PT E
D
MA
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investigated in CuOH–1/0 and CuSH–1/0 systems.
AC
RI
atoms.
22