Luca Rocchigiani1, Julio Fernandez-Cestau1, Isabelle Chambrier1, Peter Hrobárik2,3, Manfred Bochmann1. 1. School of Chemistry , University of East Anglia , Norwich Research Park , NR4 7TJ Norwich , United Kingdom. 2. Institut für Chemie , Technische Universität Berlin , Straße des 17. Juni 135 , D-10623 Berlin , Germany. 3. Department of Inorganic Chemistry, Faculty of Natural Sciences , Comenius University , SK-84215 Bratislava , Slovakia.
Abstract
The synthesis of new families of stable or at least spectroscopically observable gold(III) hydride complexes is reported, including anionic cis-hydrido chloride, hydrido aryl, and cis-dihydride complexes. Reactions between (C^C)AuCl(PR3) and LiHBEt3 afford the first examples of gold(III) phosphino hydrides (C^C)AuH(PR3) (R = Me, Ph, p-tolyl; C^C = 4,4'-di- tert-butylbiphenyl-2,2'-diyl). The X-ray structure of (C^C)AuH(PMe3) was determined. LiHBEt3 reacts with (C^C)AuCl(py) to give [(C^C)Au(H)Cl]-, whereas (C^C)AuH(PR3) undergoes phosphine displacement, generating the dihydride [(C^C)AuH2]-. Monohydrido complexes hydroaurate dimethylacetylene dicarboxylate to give Z-vinyls. (C^N^C)Au pincer complexes give the first examples of gold(III) bridging hydrides. Stability, reactivity and bonding characteristics of Au(III)-H complexes crucially depend on the interplay between cis and trans-influence. Remarkably, these new gold(III) hydrides extend the range of observed NMR hydride shifts from δ -8.5 to +7 ppm. Relativistic DFT calculations show that the origin of this wide chemical shift variability as a function of the ligands depends on the different ordering and energy gap between "shielding" Au(dπ)-based orbitals and "deshielding" σ(Au-H)-type MOs, which are mixed to some extent upon inclusion of spin-orbit (SO) coupling. The resulting 1H hydride shifts correlate linearly with the DFT optimized Au-H distances and Au-H bond covalency. The effect of cis ligands follows a nearly inverse ordering to that of trans ligands. This study appears to be the first systematic delineation of cis ligand influence on M-H NMR shifts and provides the experimental evidence for the dramatic change of the 1H hydride shifts, including the sign change, upon mutual cis and trans ligand alternation.
The synthesis of new families of stable or at least spectroscopically observable gold(III) hydride complexes is reported, including anionic cis-hydrido chloride, hydrido aryl, and cis-dihydride complexes. Reactions between (C^C)AuCl(PR3) and LiHBEt3 afford the first examples of gold(III) phosphino hydrides (C^C)AuH(PR3) (R = Me, Ph, p-tolyl; C^C = 4,4'-di- tert-butylbiphenyl-2,2'-diyl). The X-ray structure of (C^C)AuH(PMe3) was determined. LiHBEt3 reacts with (C^C)AuCl(py) to give [(C^C)Au(H)Cl]-, whereas (C^C)AuH(PR3) undergoes phosphine displacement, generating the dihydride [(C^C)AuH2]-. Monohydrido complexes hydroaurate dimethylacetylene dicarboxylate to give Z-vinyls. (C^N^C)Au pincer complexes give the first examples of gold(III) bridging hydrides. Stability, reactivity and bonding characteristics of Au(III)-H complexes crucially depend on the interplay between cis and trans-influence. Remarkably, these new gold(III) hydrides extend the range of observed NMR hydride shifts from δ -8.5 to +7 ppm. Relativistic DFT calculations show that the origin of this wide chemical shift variability as a function of the ligands depends on the different ordering and energy gap between "shielding" Au(dπ)-based orbitals and "deshielding" σ(Au-H)-type MOs, which are mixed to some extent upon inclusion of spin-orbit (SO) coupling. The resulting 1H hydride shifts correlate linearly with the DFT optimized Au-H distances and Au-H bond covalency. The effect of cis ligands follows a nearly inverse ordering to that of trans ligands. This study appears to be the first systematic delineation of cis ligand influence on M-H NMR shifts and provides the experimental evidence for the dramatic change of the 1H hydride shifts, including the sign change, upon mutual cis and trans ligand alternation.
Transition
metal hydridesare key components of many catalytic
reactions and constitute one of the most important classes of coordination
complexes.[1] Hydrides of gold,[2] by comparison, have been conspicuous by their
absence and were long regarded as unstable or hypothetical. The first
experimental evidence for their existence was reported by Andrews
et al. in 2001, who generated binary hydrides such as AuH, (H2)AuH, (H2)AuH3, and [AuH4]− in frozen gas matrices below 5 K.[3] The first example of an isolable gold(I) hydride
was obtained in 2008, using an N-heterocycliccarbene
(NHC) as stabilizing ligand.[4] There are
only two types of structurally characterized gold(III) hydrides known
so far, both based on stabilization by C^N^C pincer ligands: (C^N^C)AuH
(Chart , structure A) first described in 2012,[5,6] and Bezuidenhout’s
cation B, generated by protonation of the corresponding
T-shaped Au(I) bis-carbene complex.[7] In
both cases the hydride ligands are trans to N-donors,
which exert a weak trans-influence and thus increase
the Au–H bond enthalpy while reducing its reactivity. The thermally
stable hydride A was subsequently detected in a number
of catalysis-relevant reactions, notably the water–gas shift
reaction.[8,9] Given that gold and hydrogen have very similar
electronegativities, Au–H bonds are highly covalent. The reactivity
of gold(III) hydrides reflects this; whereas B can be
deprotonated only by very strong bases,[7] complexes of type A undergo homolytic Au–H bond
cleavage and insertion reactions with alkenes and alkynes via bimolecular
pathways involving (C^N^C)AuII radical intermediates.[6,10]
Chart 1
Structures of Previously Reported Gold(III) Hydrides A and B and
of the Starting Materials 1–3
Gold hydrides have been postulated
numerous times as part of catalytic
cycles and a variety of coordination environments have been assumed,[11−14] although experimental evidence for the structural diversity that
is accessible to such species is as yet very limited. In square-planarAu(III) complexes the trans effect plays a fundamental
role in determining chemical behavior, and the presence of strong
electron-donating substituents trans to the hydride
can dramatically increase the reactivity of the Au–H bond.
Some examples in the recent literature showed that trans-carbondonors facilitate β-hydride elimination from gold(III)
alkyls or formate complexes. Highly reactive gold hydride intermediates
were postulated, which can undergo insertion or reductive elimination
processes.[11,14] However, until now these types
of Au(III) hydrides have not been directly observed.For this
reason, we designed
an experimental study aimed at trapping
new families of Au(III) hydrides featuring a C-donor in the form of
a cyclometalated aryl ligand in trans position, in
order to investigate analogies and differences with the previously
reported hydrides A and B. To achieve this
goal, we explored complexes with different types of ligand environments
(Chart , compounds 1–3). First, we investigated the reactivity
of the C^C^N pincer complex 1(15) toward LiHBEt3 at low temperature, with the purpose of
observing the corresponding hydride. Second, we extended this strategy
to bidentate biphenyl-based C^C chelating ligands (2),[16] where the fourth coordination position is occupied
by different, nontethered Lewis bases. Finally, we investigated the
C^N chelate complexes 3, which can be straightforwardly
obtained by reacting (C^N^C)Au species with the strong Brønsted
acid [H(OEt2)2][H2N{B(C6F5)3}2] (HAB2). In complexes
of type 3,[17] the dangling
aromatic substituent acts as a steric protection for the site trans to the cyclometalated aryl group, and this was envisaged
to offer the possibility of stabilizing the hydride against reductive
elimination.Using the starting materials 1–3, we report here several new classes of gold(III) hydrides,
including
(i) hydrido phosphine complexes, (ii) anionic hydrides, (iii) dihydrides,
and (iv) bridging gold(III) hydrides. For the first time it has been
possible to synthesize gold(III) complexes with the hydride ligand trans to a strong trans-effect C-donor
ligand. We also show that the coordination geometry has an unexpectedly
strong influence on the Au–H 1H NMR chemical shift,
which can cover a range of ∼15 ppm. Computational studies show
that the 1H NMR shifts of gold hydrides are strongly influenced
by the spin–orbit coupling as a function of the ligand environment
and depend on the nature of both cis and trans ligands. These ligand combinations also affect the
thermal stability, leading, for example, to gold(III) phosphine hydrides
suitable for crystallographic characterization. The investigation
of the reactivity of these new hydrides reveals that they differ distinctly
from compounds of type A.
Results and Discussion
(C^C^N)
Complexes
C^C^N pincer complexes are
coordination
isomers of the much more widely studied C^N^C systems[9,18] and show interesting reactivity and photophysical properties.[15] In bonding terms C^C^N is complementary to C^N^C
since strong and weak trans-effect ligands have swapped
positions and dissociation of the pyridine moiety is less constrained,
so that gold(III) hydrides with enhanced reactivity might be expected.
With this aim, we explored the reactivity of (C^C^N) gold chloride 1 with 1.0 equiv of LiHBEt3 at 198 K. The reaction
was monitored by 1H NMR spectroscopy in THF-d8 gradually raising the temperature from 203 to 243 K.
The 1H NMR spectrum recorded at this temperature showed
the clean formation of a single gold-containing species 4, which retained the typical pattern of a cyclometalated (C^C^N)
system (Scheme ).
While no precipitate was seen in THF, when the reaction was performed
in CD2Cl2, the formation of solid of LiCl was
observed and free BEt3 was detected in the reaction mixture
(δB = +85.1 ppm).
Scheme 1
Generation of Monohydride 4 and the Dihydride 5 (R = p-BuC6H4), Showing the
Numbering Scheme Used for NMR
Assignments
Multinuclear and multidimensional
NMR experiments performed at
253 K in THF-d8 were consistent with the
formulation of 4 as the gold hydride (C^C^N)AuH.[19] The 1H NMR chemical shifts of metalhydridesare subject to relativistic spin–orbit (SO) effects
(“heavy atom effect on the light-atom shielding”, HALA),[20,21] which in the case of transition metal complexes with d8 electron configuration are typically shielding,[20a] as exemplified by shifts of δH = −6.58
(CD2Cl2) and −8.34 ppm (THF-d8) for A and B, respectively.[5,7] In sharp contrast, the signal for the Au–H moiety in 4 is high-frequency shifted at δH = +6.33
ppm. An analysis of the dipolar contacts in the 1H NOESY
NMR spectrum revealed selective interactions of the hydride signal
with both ortho-protons of the coordinated pyridyl
and of the cyclometalated aryl, indicating that the pyridine coordination
remains intact upon exchange of chloride by hydride. No interactions
with BEt3 groups were observed, excluding the formation
of a gold-borohydrideAu-HBEt3 complex. This was further
confirmed by diffusion NMR experiments, which showed that 4 and BEt3 diffuse with different hydrodynamic dimensions.
The carbon atom in trans position to the hydride
is high-frequency shifted compared with the chloride complex and resonates
at δC = 184.2 ppm; this shift can be attributed to
the strong trans-influence of the H– ligand and concomitant SO-induced deshielding.[21,22] On the other hand, the second metalated carbon atom is found at
δC = 145.3 ppm, being trans to the
weaker pyridinedonor. The NMR peak assignments are also confirmed
by relativistic quantum-chemical calculations (cf. Figure S49 in Supporting Information for 13C NMR
data) and 1H hydride shifts are analyzed in detail (see
Computational analysis below).In THF solution at room temperature 4 is stable only
for a few minutes, hampering its successful crystallization. When
an NMR sample was warmed from 253 to 298 K, broadening of the Au–H
and pyridine signals was observed, likely due to pyridine decoordination
which may open decomposition pathways. Other solvents, such as benzene-d6 or CD2Cl2, can be used
for generating 4, but no improvements in stability were
observed. The 1H NMR signal of the Au–H moiety is
marginally affected by the change of solvents and resonates at δH = 6.99 and 6.09 ppm in C6D6 and CD2Cl2, respectively.Complex 4 reacts
smoothly at room temperature with
dimethyl acetylene dicarboxylate (DMAD) under trans-hydroauration to give a gold vinyl product (Z/E = 95:5). A similar vinyl product has previously been obtained
by the thermal decomposition of the gold(III) formate complex (C^C^N)AuO2CH at 100 °C in the presence of di-tert-butyl acetylenedicarboxylate, presumably via 4 as the
intermediate.[14] On the other hand, 4 proved unreactive toward unactivated alkynes such as 2-butyne
or 1-phenyl-1-propyne. This behavior contrasts with that of hydrides
of type A, which insert a wide range of alkynes stereoselectively
by a radical-mediated outer-sphere mechanism.[6]When a solution of 4 in THF-d8 is treated with 1 or more equivalents of LiHBEt3 at 263 K, the monohydride is quantitatively converted into
the unprecedented
anionic dihydride complex 5. In striking contrast with
what was observed in 4, both the hydride signals of 5 are shielded and located at δH = −0.59
(Ha) and −0.31 ppm (Hb). Ha appears as a doublet with a coupling constant 2J = 4.2 Hz, while Hb is a pseudotriplet due to the simultaneous coupling with Ha and the α proton of the cyclometalated aryl. The assignment
of the hydride signals was confirmed by 1H NOESY spectroscopy,
which shows selective dipolar interactions between Hb and
the H3/H4 pair of the dangling pyridine, while
Ha interacts specifically with H16 (Figure ). Both carbon atoms
attached to gold are high-frequency shifted due to the high trans-influence of the hydride ligands and resonate at δC = 172.3 (C trans to Hb) and 171.1
ppm (C trans to Ha). The dihydride 5 is stable in THF solution for days at room temperature but
has so far escaped crystallization. Interestingly, 5 can
also be prepared quantitatively by using an excess of LiAlH4 as hydride transfer agent, with no sign of reduction. The reaction
of 5 with DMAD gives a complex mixture, likely arising
from possible double insertions and/or vinyl elimination reactions;
it did not prove possible to isolate a clean product.
Figure 1
Left: overlay of two
sections of the 1H NMR spectra
of (a) 1 (203 K, THF-d8);
(b) 4 (253 K, THF-d8); and
(c) 5 (263 K, THF-d8). Right:
a section of the 1H NOESY NMR spectrum of 4 (top, 253 K, THF-d8) and 5 (bottom, 263 K, THF-d8).
Left: overlay of two
sections of the 1H NMR spectra
of (a) 1 (203 K, n class="Chemical">THF-d8);
(b) 4 (253 K, THF-d8); and
(c) 5 (263 K, THF-d8). Right:
a section of the 1H NOESY NMR spectrum of 4 (top, 253 K, THF-d8) and 5 (bottom, 263 K, THF-d8).
The C^C Ligand System
The formation
of 5 shows that even anionic gold(III) dihydrides can
be made supported
by a dianionic C^C chelate backbone, rather than by tridentate pincer
ligands. We therefore explored similar ligands which lack the tethered
pyridinedonor. The complex (C^C)AuCl(py) 2 (C^C = 4,4′-di-tert-butylbiphenyl-2,2′-diyl) was combined with 2.0
equiv of LiHBEt3 in THF-d8 at
198 K and the reaction was monitored by 1H NMR spectroscopy
at 223 K. Soon after mixing the reagents, the solution turned bright
yellow, and the first NMR spectrum showed the complete consumption
of the starting material to give a single clean species showing two
different sets of signals for the C^C ligand, suggesting the formation
of an asymmetric gold complex. 1H NOE and diffusion NMR
spectroscopy showed that the py → BEt3 Lewis adduct
had formed. These data are consistent with pyridine displacement by
the hydroborate and elimination of the borane-pyridine adduct, leading
to the formation of the chloro hydride anion, [(C^C)Au(H)Cl]− (6). The reaction of 2 is therefore quite
different from that of the (C^C^N) ligand system 1, where
the pyridine was not initially displaced. The Au–H moiety in 6 was identified as a broad singlet at δH = +2.43 ppm, which showed selective dipolar interactions with only
one α proton of the ligand at δH = 7.72 ppm.
As observed for 4, the two metalated carbon atoms resonate
at quite different frequencies, due to the different trans-influences of the chloride and hydride ligands, such that C trans to H resonates at δC = 174.8 ppm,
while C trans to Cl is found at 148.4 ppm. Product 6 is stable in solution for hours at 213 K, but upon raising
the temperature to 253 K it is converted to an undefined secondary
species showing a broad hydride signal at δH = +0.9
ppm. Diffusion NMR experiments in CD2Cl2 at
228 K suggested the formation of aggregates containing at least four
gold centers. This species undergoes reductive decomposition above
253 K, and its identity could not be ascertained. Since this reactivity
was likely due to the facilechloride elimination from 6, we explored more strongly coordinating bases to stabilize the hydride
products.In order to intercept a (C^C)Auhydride of a structure
comparable to 4, the chloro hydride 6 was
reacted with 1 mol equiv of p-dimethylaminopyridine
(DMAP) at 195 K and the resulting mixture was monitored by 1H NMR spectroscopy at 253 K. Although at a 1:1 stoichiometry DMAP
does not bind to gold but displaces pyridine from the py →
BEt3 adduct, with 4.0 equiv of DMAP 6 is converted
quantitatively to (C^C)AuH(DMAP) (7) (Scheme ). This complex shows a hydride
signal at δH = +3.25 ppm, which exhibits NOE interactions
with one α proton of the C^C ligand and with the ortho protons of the coordinated DMAP (δH = 8.10). 1H NOESY NMR reveals that at 253 K free and coordinated DMAPare in chemical exchange. Likely for this reason, 7 decomposes
at room temperature within about 30 min.
Scheme 2
Synthesis and Reactions
of (C^C)Gold(III) Hydrides, Showing the Atom
Numbering Scheme Used for NMR Assignments, and the Molecular Structure
of the Insertion Product 12
Synthesis and Reactions
of (C^C)Gold(III) Hydrides, Showing the Atom
Numbering Scheme Used for NMR Assignments, and the Molecular Structure
of the Insertion Product 12
Selected
bond distances [Å]
and angles [°]: Au1–C1 2.079(7), n class="Chemical">Au1–C12 2.070(6),
Au1–P1 2.353(2), Au1–C24 2.078(7), C1–Au1–C12
81.1(3), C1–Au1–P1 96.8(2), P1–Au1–C24
89.7(2), C24–Au1–C12 92.3(3), C1–Au1–C24
173.4(3), C12–Au1–P1 177.3(2), torsion C1–Au1–C24–C25
91(2), torsion C1–Au1–C24–C27–88(3).
By contrast, thermally stable
hydridesare straightforwardly obtained
by reacting the phosphine complexes (C^C)Au(Cl)PR38 (R = Me, p-tolyl) with LiHBEt3 in toluene at room temperature to give spectroscopically clean samples
of 9 and 10, respectively, which were isolated
by filtration and vacuum drying. The same complexes, as well as the
PPh3 derivative 11, are also accessible from
the chloro hydride 6 on reaction with phosphines. However,
in that case purification and crystallization of the products was
hampered by the presence of the py → BEt3 byproduct,
which displays similar solubility characteristics to 9–11 in organic solvents.The complexes 9–11 are stable
in THF solution at room temperature for several days. The 31P NMR spectra showed high-frequency shifted signals at δP = −8.2, δP = 32.6, and δP = 34.9 ppm for 9, 10, and 11, respectively, confirming phosphine coordination. The 1H NMR hydride signals at 1.53 (9), 2.33 (10), and 2.40 ppm (11) appear as doublets due
to their coupling with the phosphorus atoms. The 2JPH values (32.6 Hz for 9, 33.0
for 10 and 32.3 Hz for 11) are compatible
with H and P in cis-positions. 2JPC values are in agreement with the proposed
structures: trans couplings fall between 130 and
140 Hz, while cis2JPC constants are about 4–5 Hz.Single crystals
of 9 were obtained by the slow evaporation
of a dry diethyl ether solution under an N2 atmosphere.
The structure contains four independent molecules in the asymmetric
unit, with very similar structural parameters. Figure gives the geometric parameters of just one
of these molecules. A complete description of the structure is given
in the Supporting Information. Locating
the position of the hydride next to a heavy atom correctly by crystallography
is intrinsically difficult; however, the Fourier map for the Au coordination
plane unequivocally reveals the presence of electron density at a
distance of about 1.4 Å (see Supporting Information, Figure S45). The other structural parameters
are as expected for a square planarAu(III) complex. From the differences
between the two Au–C bonds of the C^C ligand, the hydride exerts
a larger trans influence than the phosphine (Au1–C1
2.047(4) Å vs Au1–C12 2.115(4) Å).
Figure 2
Molecular structure of
(C^C)AuH(PMe3) 9; the approximate hydride
position is indicated
by an open circle.
Selected bond distances [Å] and angles [°]: Au1–C1
2.047(4), Au1–C12 2.115(4), Au1–P1 2.325(1), C1–Au1–C12
81.5(2), C12–Au1–P1 98.7(1), C1–Au1–P1
179.6(1).
Molecular structure of
(n class="Chemical">C^C)AuH(PMe3) 9; the approximate hydride
position is indicated
by an open circle.
Selected bond distances [Å] and angles [°]: Au1–C1
2.047(4), Au1–C12 2.115(4), Au1–P1 2.325(1), C1–Au1–C12
81.5(2), C12–Au1–P1 98.7(1), C1–Au1–P1
179.6(1).
Although solid samples of 9–11 are thermally stable under ambient
conditions, crystallization attempts
of 9 in toluene also revealed that over time reductive
C–H elimination and ligand rearrangements are possible, as
indicated by the isolation of the gold(I) complex [(tBuC6H3)2(AuPMe3)2] as a byproduct (see Supporting
Information, Figure S46). Furthermore,
unlike the (C^N^C)AuH hydrides of type A which are stable
to air, moisture and weak acids, solutions of 9–11 are sensitive to exposure to air. For example, a sample
of 10 left to crystallize without a protective atmosphere
afforded the crystallographically identified hydroxide [(C^C)Au(μ–OH)]2, together with (p-tol)3P=O
(see SI, Figure S47). The formation of
these products suggests O2 insertion into the Au–H
bond[23] to give an Au(OOH)(PR3) intermediate, which decomposes to the gold hydroxide with oxidation
of the phosphine. This reactivity was also observed upon reacting 10 with dry O2.As in the case of 4, the hydrides 9 and 10 insert DMAD to
give the corresponding Z-vinyl complexes 12 and 13. However, whereas 4 reacts instantaneously
with DMAD at room temperature, the
same reaction with 9 and 10 proceeds more
slowly. When 1–2 mol equiv of DMADare used, 9 is consumed within 2 h, while the reaction of 10 takes
about 12 h, likely due to the increased steric repulsion of the phosphine
ligands. The reaction affording 12 is quantitative, whereas 13 is formed in 80% yield together with unidentified side
products.The stereochemistry of the DMAD hydroauration products
was proved
by 1H NOE NMR spectroscopy, which showed the presence of
dipolar contacts between the vinylic CH and both the methoxy groups.
No signs of Z/E isomerization were
observed after 2 days in solution. Single crystals of 12 suitable for X-ray diffraction were obtained by slow evaporation
of a toluene/dichloromethane solution. The crystal structure confirmed
the trans-orientation of the two methylcarboxylate
moieties. The vinyl group adopts a perpendicular orientation with
respect to the coordination plane of Au (torsion angle C1–Au1–C24-C27
88(3)°). The planar disposition of the C28(O)OMe carboxylate
group and the vinyl moiety is indicative of π-delocalization;
the other carboxylate residue adopts a twisted geometry. The orientation
of the carboxylate groups is stabilized in the solid state by a network
of intermolecular O···H interactions.The addition
of a second molar
equivalent of LiHBEt3to 9 and 10 leads to the substitution
of the phosphine ligand by H–, to give the anionic cis-dihydride 14 (Scheme ). For example, upon reacting 10 with 1.0 equiv LiHBEt3 at room temperature in THF-d8, 31P NMR spectroscopy revealed
the disappearance of the signal at δP = 32.6 and
the concomitant formation of free para-tolyl phosphine
(δP = −8.0). The 1H NMR spectrum
indicated a C2-symmetric C^C ligand, together
with a new signal at δH = 0.09 which accounts for
two protons and is assigned to Au–H (Supporting Information, Figures S23–S24). The hydride signal appears
as a pseudotriplet, due to coupling with the two C^C ring protons
in 2 and 2′ positions; these protons also show selective NOE
interactions with the hydride signal. In agreement with these observations,
the Au–C carbon atoms resonate at δC = 170.7
in the 13C NMR spectrum. Complex 14 can be
also generated in toluene-d8, for which
the hydride resonance of the AuH2 moiety was found at δH = 1.00 ppm. Given that for cis-(Ph3P)AuClH(Ph) and cis-(Ph3P)AuClH2 the calculated barriers for C–H reductive elimination are
only 7.5 and 6.5 kcal mol–1, respectively,[24] and considering the lack of orbital directionality
of H, the observed thermal stability of gold(III) hydrido aryls 9–11 and of the dihydride 14 is remarkable and unexpected. As was seen for 10, eventually
reductive decomposition does take place, and although 14 appears stable at room temperature for hours in THF and toluene
solutions, any isolation attempts led to reductive decomposition,
affording free biphenyl and metallic gold.Other gold cis-hydrido aryl complexes resistant
to reductive eliminationare similarly accessible, by treatment of
the pentafluorophenyl complex[NBu4][(C^C)Au(Cl)C6F5] (15) at room temperature with 1.2 equiv
LiHBEt3. The anionic hydride 16 is formed
in quantitative yield, according to 1H NMR spectroscopy
(Scheme ). The chloride-to-hydride
exchange in THF-d8 is comparatively slow
and complete within 24 h, whereas in toluene the formation of 16 is instantaneous. The Au–H signal resonates at δH = 1.15 ppm in THF-d8, partially
overlapping with a tert-butyl signal, and was identified
by means of its selective dipolar interaction with the H2 proton of the cyclometalated aryl ring at δH =
8.06 ppm. As was seen previously for neutral C^C hydrides, the cyclometalated
carbon atom trans to the hydride is high-frequency
shifted to δC = 170.3, while the one trans to C6F5 resonates at δC =
160.1 ppm. Complex 16 reacts readily with DMAD to give
the corresponding trans-vinyl complex 17. In contrast with the phosphine hydrides 9 and 10, the reaction with 16 is instantaneous at
room temperature. The stereochemistry was confirmed by 1H NOESY NMR spectroscopy and by single crystal X-ray diffraction
of 17 (Scheme ). The structural parameters of the anionic vinyl 17 are very similar to those found for 12.
Scheme 3
Synthesis
of NBu4[(C^C)AuH(C6F5)]
(16) and the Formation and Molecular Structure of the
Alkyne Insertion Product 17 (NBu4+ Omitted for Clarity)
Synthesis
of NBu4[(C^C)AuH(C6F5)]
(16) and the Formation and Molecular Structure of the
Alkyne Insertion Product 17 (NBu4+ Omitted for Clarity)
Selected bond distances
[Å]
and angles [°]: Au1–C1 2.046(8), n class="Chemical">Au1–C12 2.063(6),
Au1–C27 2.093(8), Au1–C21 2.088(6), C27–C28 1.57(2),
C27–C30 1.22(2), C1–Au1–C12 80.8(3), C1–Au1–C21
93.7(3), C21–Au1–C27 89.9(3), C27–Au1–C12
95.7(3), C1–Au1–C27 174.4(3), C12–Au1–C21
174.4(3).
While phosphine dissociation
and creation of a coordination site cis to the hydride
could in principle be considered a possible
pathway in the reactions of phosphine hydrides 9 and 10 with DMAD, the facilealkyne insertion into the Au–H
bond of 16, where no such ligand dissociation is possible,
shows that alkyne π-coordination to Au(III)–H is not
part of the insertion process. We also established that, unlike the
insertion reactions of (C^N^C)AuH (A) with alkyl and
aryl acetylenes,[6] a radical chain reaction
via Au(II) intermediates is not involved.While a detailed study
of this insertion mechanism is beyond the
scope of this work, it is apparent that only alkynes with a low reduction
potential insert into the gold hydrides described here. A similar
observation was made with the gold(I) hydride (IPr)AuH (IPr = 1,3-bis(diisopropylphenyl)imidazol-2-ylidene).[4] DMAD has a reduction potential of only −0.8
V (compared to a value of −2.1 V for diphenylacetylene).[25] It seems likely therefore that the insertion
of DMAD follows an electron transfer mechanism, which would generate
an alkyne radical anion within the solvent cage. Alkyne radical anions
are known to exhibit trans geometry,[26] and such an intermediate, followed by H abstraction and
Au–C bond formation, would explain the observed Z-vinyl stereochemistry of DMAD hydroauration (Scheme ). The reactivity of our gold(III) hydrides
seems to resemble therefore the DMAD insertion process observed for
platinum dihydridestrans-H2Pt(PR3)2 (but not for trans-PtH(Cl)(PEt3)2, which follows a coordination–cis insertion pathway).[27]
Scheme 4
Proposed Mechanism of
DMAD Hydroauration with (C^C)Au Hydrides
Reactivity of (C^C)Gold
Vinyl Complexes
As we observed
previously, (C^N^C)Au(III) vinyl complexes obtained by alkyne trans-hydroauration are thermally stable and are not protodeaurated
by strong acids.[6] This might be ascribed
to the effect of the weak pyridinedonor trans to
vinyl, which strengthens the Au–C bond. In 12, 13, and 17, the vinyl ligands are trans to anionic carbon, which exerts a much stronger trans effect and thus labilize the Au-vinyl bond. In order to investigate
whether this structural modification has an impact on the reactivity
of these complexes, we explored photoisomerization, protodeauration,
and reduction with LiHBEt3 of these gold vinyls.Photoisomerization of 12 and 17 was performed
by irradiating samples in THF-d8 at 365
nm for 2 h at room temperature. 12 does not photoisomerize
easily under these conditions and gives a thermodynamic E/Z ratio of 20:80, whereas the anionic vinyl complex 17 leads to an equilibrium E/Z ratio of 50:50.
This supports the hypothesis that the Z isomer obtained
upon hydroauration of DMAD is the kinetic product and that the structure
of the ancillary ligand has an impact on the isomer distribution in
the thermodynamic mixture.The reactivity of (C^C)Au
vinyl complexes toward acids and hydrides
was exemplified for 12. On treatment with 2.5 equiv of
LiHBEt3, 12 reacts quantitatively under selective
reduction of one of the two ester functions to give the alkoxyvinyl
product 18 (Scheme ). The identity of 18 was confirmed by
multinuclear and multidimensional NMR spectroscopy (Supporting Information). This reactivity demonstrates the
facile postsynthesis derivatization of alkyne hydroauration products
and their remarkable resistance to reducing conditions.
Scheme 5
Photoisomerization,
Ester Reduction, and Reductive C–C Bond
Formation of Gold Vinyl Complexes
Reductive elimination of a
C–C cross-coupling product can
be induced by acids. When a solution of 12 in THF-d8 was treated with the strong Brønsted
acid [H(OEt2)][H2N{B(C6F5)3}2][28] (1 equiv)
at room temperature, the orange color of the solution faded immediately
and a dark precipitate of metallic gold was observed. The 1H NMR spectrum of the supernatant revealed the formation of the 2-vinylbiphenyl 19 in about 65% yield. Protodeauration of the Au-vinyl bond
to give MeO2CH=CHCO2Me was not detected.
The appearance of an AX system at δH = 7.20 and 7.34
ppm suggests that the acid protodeaurates selectively one Au–C
bond of the cyclometalated C^C ligand, likely trans to vinyl, to give a cationic aryl-vinyl intermediate capable of
reductive C–C coupling. This Au-aryl bond cleavage kinetically
outperforms Au-vinyl protonation. The stereochemistry of the vinyl
group is retained in 19.
The C^N–CH Ligand
System
Protodeauration of
(C^N^C) Au(III) pincer complexes with HAB2 affords cleaved
(C^N–CH)Au(III) cations 3 (Scheme ), where a Et2O molecule is weakly
coordinated to gold in trans position to the remaining
cyclometalated aryl.[17] We therefore envisioned
that this particular ligand environment could offer the possibility
to intercept yet another family of Au(III) hydrides which could also
have the hydride ligand trans to a carbon atom but,
being supported by a C^N rather than a C^C chelate, would constitute
the cationic analogues of the (C^C)AuH(L) species described above.
Moreover, the presence of the dangling aryl group might offer extra
steric protection to the hydride moiety.
Scheme 6
Formation of Binuclear
C^N Bonded Gold(III) Hydrides
As a first control experiment,
we reinvestigated the reaction of
(C^N^C)AuH with HAB2 at a 1:1 molar ratio. As previously
reported, the Au–H bonds in pincer gold(III) hydridesare covalent
and do not liberate H2 upon reaction with acids. Instead,
one Au–C bond is protolytically cleaved, a process that can
be expected to enable fast reductive C–H elimination.[29] To our surprise, when the protodeauration reaction
was performed at 213 K in CD2Cl2, the starting
material was quantitatively converted to the new species 20. This complex shows two scalarly coupled hydride signals, both at
much lower frequency than the ones seen for C^C complexes, δH = −4.88 and δH = −8.39 ppm.
In the aromatic region of the 1H NMR spectrum there are
two sets of signals in a 1:1 ratio, with one set showing the typical
fingerprint of a cleaved (C^N–CH) ligand, while the second
set was that of an intact (C^N^C)Au fragment. In agreement with this,
only 50% of the added acid had in fact reacted, with the other 50%
remaining unchanged (δH = 16.7 ppm). These findings
were consistent with protodeauration of one pincer Au–C bond
to generate a cationic gold hydride, followed by coordination of a
molecule of neutral (C^N^C)AuH to the vacant coordination site on
the [(C^N–CH)AuH]+ cation to give the H-bridged
binucleardihydride 20 (Scheme ). Whereas in gold(I) chemistry H-bridged
complexes are not uncommon,[4] this is the
first example of a bridging hydride in gold(III) chemistry. In agreement
with the reaction sequence outlined above, the same product can be
generated using only 0.5 equiv of acid. The geminal coupling constants
for the dihydride was found to be 8.2 Hz, much larger than the geminal
coupling in the anionic mononucleardihydride 6 (2J = 4.2 Hz). 1H NOESY methods allowed us to assign the signals at δH = −4.88 and δH = −8.39 ppm
to the bridging and the terminal hydride, respectively. Unfortunately,
the dihydride 20 is thermally unstable and at 213 K decomposes
over a period of 1 h, hampering full 13C NMR characterization.In analogy to complex 20, the cationic gold(III) methyl
complex 3a reacts with 1 equiv of (C^N^C)AuH at 213 K
to give the bridging hydride 21 (δH =
−5.14 ppm). Product 21 proved to be rather unstable
and decomposed at low temperature within hours, in line with the low
barrier of reductive methane elimination calculated for (Ph3P)AuH(CH3)Cl (11.1 kcal mol–1).[24] Nevertheless, it seems remarkable that gold
hydrido methyl complexes are so readily accessible.In the search
for milder hydridedonors, the reactions of the cleaved
pincer complexes 3a and 3b with HSi(OMe)3 were tested. Complexes 22a (R = Me) and 22b (R = C6F5) proved to be more stable
than 20 and 21 and could be fully characterized
by multinuclear NMR at low temperature. The hydride signal appeared
as singlets at δH = −2.53 and δH = −2.21 ppm for 22a and 22b, respectively (Supporting Information, Figure S41). The 1H NMR spectra of complexes 22a,b show the presence of four different signals for the
dangling aryl substituents, suggesting that dimerization of two gold
units blocks the free rotation of the aromatic ring about the C–C
bond. 1H NOESY NMR spectroscopy revealed the presence of
selective dipolar interactions between the bridging hydride and only
one proton of the protodeaurated ring, confirming that the Au–H–Au
moiety is located in the pocket formed by the two paired cleaved pincer
complexes. In the case of complex 22a, the same interaction
was observed for the Au–Me moiety.Although complexes 22a,b are stable at
253 K, they decompose at room temperature, following reaction pathways
which depend on the substituents on gold. Warming a sample of 22b to 297 K generates C6F5H quantitatively
within minutes; in this case the reductive coupling of H with C6F5 is preferred. The methyl complex 22a is slightly more thermally stable and survives 297 K for about 30
min before decomposing. However, there is no elimination
of CH4; instead, the methyl migrates to the C^N^C ligand,
while the hydride is likely eliminated through reductive deprotonation
to give protonated pyridinium salts.[30]
Connection between Gold Hydride 1H NMR Chemical Shifts
and Electronic Structure
The gold(III) hydride complexes
described above are characterized by a spread of 1H NMR
chemical shifts covering an unexpectedly wide range of about 15 ppm. Table summarizes the relevant
structural, calculated and experimental data. Particularly striking
is the difference between the regioisomeric pincer complexes (C^N^C)AuH
and (C^C^N)AuH, which show resonances of δ −6.51 and
+6.09 ppm, respectively (both in CD2Cl2). While
the former features an upfield (low-frequency) shift often seen for
diamagnetic hydride complexes with a partially filled d-shell,[19] the latter displays a notable downfield 1H shift, resembling that in a gold(I) hydride, (IPr)AuH,[4] although both (C^N^C)AuH and (C^C^N)AuH contain
the metal center in the same +III oxidation state. To rationalize
the observed trends and to gain insight into the electronic structures
and the factors that result in these spectroscopic differences, we
turned to relativistic quantum-chemical calculations of structures
and 1H NMR hydride shifts at the two-component ZORA-SO
level, including spin–orbit coupling (see Supporting Information for computational details).[31,32]
Table 1
DFT Optimized Au–H Bond Lengths
(in Å) and Computed and Experimental 1H NMR Hydride
Chemical Shifts of Gold Hydridesa
In ppm vs TMS. All calculations
done for PBE0-D3(BJ)/ECP/def2-TZVP optimized structures (see SI).
Chemical shifts computed at the
2c-ZORA(SO)/PBE0-XC/TZ2P level; SO-induced contributions to hydride
shifts, δSO, are given in parentheses.
For comparative purposes, the hydride
shifts were also computed at the four-component, fully relativistic
4c-mDKS/PBE0/Dyall-VDZ/IGLO-II level.
Solvents used in NMR measurements
are given in parentheses.
This work.
In ppm vs TMS. All calculations
done for PBE0-D3(BJ)/ECP/def2-TZVP optimized structures (see SI).Chemical shifts computed at the
2c-ZORA(SO)/PBE0-XC/TZ2P level; SO-induced contributions to hydride
shifts, δSO, are given in parentheses.For comparative purposes, the n class="Chemical">hydride
shifts were also computed at the four-component, fully relativistic
4c-mDKS/PBE0/Dyall-VDZ/IGLO-II level.
Solvents used in NMR measurements
are given in pn class="Chemical">arentheses.
This work.All investigated
structures were optimized at the PBE0-D3(BJ)/ECP/def2-TZVP
level using a quasi-relativistic small-core pseudopotential for gold,
along with atom-pairwise corrections for dispersion forces. First,
we note an excellent agreement between X-ray and DFT optimized structures,
with differences in Au–L bond-lengths of less than 0.02 Å,
except for the Au–H bonds, where values determined by X-ray
diffraction are often much larger (by up to 0.15 Å) than found
computationally (cf. Figure S48 in Supporting
Information). The precise detection of the hydride position by X-ray
crystallography, however, suffers from weak scattering of X-rays by
light H atoms and these data should be taken with caution. The reliability
of DFT-determined Au–H bond-lengths is demonstrated by the
excellent agreement between computed and experimental 1H hydride shifts for the optimized structures, with a standard deviation
of 0.4 ppm (see Figure S50 in Supporting
Information). We also note a very good match between experimental
and calculated 2JHP coupling
constants in the hydrido phosphine complexes 9 (2Jexpt = 32.6 Hz; 2Jcalcd = 31.4 Hz) and 10 (2Jexpt = 32.3 Hz; 2Jcalcd = 30.9 Hz).The experimental 1H NMR shifts of terminal hydride atoms
are found to correlate well with DFT optimized Au–H distances
(Figure a), which
suggests the potential use of 1H NMR spectroscopy in refining
precise hydride positions and explains, inter alia, the striking downfield 1H shift in (C^C^N)AuH (4). Interestingly, complexes in Table with longer and more ionic
Au–H bonds feature high-frequency (downfield) hydride shifts,
which contrasts with organic C–H compounds.[33] To explore the generality of the linear δ(1H) vs d(Au–H) relationship (Figure ) and to understand the trends in light of
electronic structure, a more thorough analysis of 1H hydride
shifts for a larger set of Au(III) hydrides was performed (see Table and Tables S1–S4 in the SI for numeric data).
Figure 3
Dependence
of experimental (a) and computed (b) 1H NMR
chemical shifts of terminal Au–H hydride atoms
(in ppm vs TMS) on the Au–H bond-length (Å) for gold(III)
complexes with diverse ligand environments. The Au–H bond distances
were obtained computationally at the DFT (PBE0-D3(BJ)/def2-TZVP) level.
(b) contains both experimentally characterized and hypothetical Au(III)
hydride complexes (cf. Table and Tables S2–S4 in SI
for numerical data). Linear regressions: (a) δH =
149.67 d(Au–H) −240.57, R2 = 0.970; (b) δH = 155.1 d(Au–H) −249.97, R2 = 0.950.
Dependence
of experimental (a) and computed (b) 1H NMR
chemical shifts of terminal Au–H hydride atoms
(in ppm vs TMS) on the Au–H bond-length (Å) for gold(III)
complexes with diverse ligand environments. The Au–H bond distances
were obtained computationally at the DFT (PBE0-D3(BJ)/def2-TZVP) level.
(b) contains both experimentally characterized and hypothetical Au(III)
hydride complexes (cf. Table and Tables S2–S4 in SI
for numerical data). Linear regressions: (a) δH =
149.67 d(Au–H) −240.57, R2 = 0.970; (b) δH = 155.1 d(Au–H) −249.97, R2 = 0.950.Decomposition of the computed 1H shieldings into diamagnetic,
paramagnetic and spin–orbit contributions shows that the trends
in isotropic hydride shifts are dominated by the δSO term (Table and Tables S1–S4 in the SI). Artificial elongation/shortening
of Au–H bonds by a value of 0.05 Å from their optimized
values in selected gold(III) hydrides causes only a small change in 1H hydride shifts (<1 ppm, data not shown), and thus the
surprisingly good correlation between δ(1H) and d(Au–H)
has an indirect rather than direct origin.[20c] The opposite sign of the 1H hydride shifts of the coordination
isomers (C^C^N)AuH and (C^N^C)AuH should thus be attributed to different
electronic structures (cf. Figure ) and is rationalized below in terms of molecular orbitals
contributing dominantly to δSO.
Figure 4
Relevant frontier MOs
at scalar-relativistic
(SR) level and their
mixing to two-component spinors responsible for the overall differences
in the 1H hydride shifts of (C^N^C)AuH (left) and (C^C^N)AuH
(right). Only one of two degenerate spinors is shown. The corresponding
MOs are shown as isosurface plots (0.03 au), with the hydride ligand
generally being placed at the bottom. The mixing percentage of SR
MOs in spinors is indicated above the corresponding SR MOs.
Relevant frontier MOs
at scalar-relativistic
(SR) level and their
mixing to two-component spinors responsible for the overall differences
in the 1H hydride shifts of (C^N^C)AuH (left) and (C^C^N)AuH
(right). Only one of two degenerate spinors is shown. The corresponding
MOs are shown as isosurface plots (0.03 au), with the hydride ligand
generally being placed at the bottom. The mixing percentage of SR
MOs in spinors is indicated above the corresponding SR MOs.Analysis of the δSO contributions at the 2c-ZORA
level show that the hydride deshielding in (C^C^N)AuH, with the strong
C-anionic trans ligand, is dominated by two spinors,
HOMO–1 and HOMO–3, both composed from the σ(Au–H)-type
SR HOMO–1 (with an appreciable gold 6p character) and a primarily
ligand-centered π-type orbital with little metal character,
SR HOMO–3 (note that both the occupied MOs are magnetically
coupled mainly with an antibonding σ*(Au–H)-type orbital,
LUMO+3). Since “shielding” Au(dπ)-type
MOs (SR HOMO–8, SR HOMO–10) lie energetically far below
the σ(Au–H) MO (by more than 2 eV), these two types of
scalar relativistic MOs do not mix with each other upon inclusion
of SO coupling, that hinders hydride shielding and results in the
high-frequency hydride shift. In contrast, the 1H shielding
for the (C^N^C)AuH complex, bearing a weak trans N-donor
ligand, is dominated by magnetic couplings between the Au(dπ)-type occupied and σ*(Au–H) virtual MOs. The highest
σ(Au–H)-type MO is energetically close to the Au(dπ) orbitals, with ΔE ∼
0.5 eV, and the deshielding effect of the former diminishes upon SO
mixing with Au(dπ)-based MOs.[34]As the comparison between
the tethered (C^C^N) and nontethered
(C^C)(N) ligand systems in complexes 4 and 7 shows, the steric constraint imposed by the C^C^N pincer ligand
also has an important effect. In C^C^N the trans-influence
of C is increased, leading to a significant lengthening of the Au–H
bond (1.641 Å in 4 vs 1.625 Å in 7) and a further deshielding of the hydride NMR resonance by about
3 ppm.Theoretical papers relating 1H NMR hydride
shifts as
a function of the trans ligand strength have appeared
very recently.[20c,21,22b] However, the influence of ligands in cis-position
has so far not been explored. Since in square-planar complexes both cis and trans effects are operative, we
performed calculations for three series: trans-[HAu(C6H5)2L], cis-[HAu(bph)L] and cis-[HAu(ppy)L] (bph = 2,2′-biphenyl
dianion, ppy = 2-phenylpyridine anion; q = 0 or −1)
in order to study the influences of cis and trans ligands separately for a wide range of common σ-donor
and π-acceptor ligands (see SI, Tables S2–S4). The ligand effects on the 1H hydride shifts are depicted
in Figure .
Figure 5
Dependence
of the computed 1H hydride shifts (δtotal) and spin–orbit-induced shift contributions (δSO) on (a) the trans ligand L in the trans-[HAuIII(C6H5)2L]; (b) the cis-ligand in the cis-[HAuIII(bph)L]; and (c) the cis-ligand
in the cis-[HAuIII(ppy)L] series (2c-ZORA(SO)/PBE0-XC/TZ2P results; see Tables S2–S4 in SI for numerical data).
Dependence
of the computed 1H hydride shifts (δtotal) and spin–orbit-induced shift contributions (δSO) on (a) the trans ligand L in the trans-[HAuIII(C6H5)2L]; (b) the cis-ligand in the cis-[HAuIII(bph)L]; and (c) the cis-ligand
in the cis-[HAuIII(ppy)L] series (2c-ZORA(SO)/PBE0-XC/TZ2P results; see Tables S2–S4 in SI for numerical data).Trans-ligands
produce chemical shift changes that
are roughly four times larger than cis-ligand effects,
consistent with the much larger variation in Au–H distances
in the trans case and the strikingly different ordering and relative
energies of σ(Au–H)-type and Au(dπ)
orbitals. The influence of trans ligands on the 1H shift spans about 22.5 ppm, with H2O as the weakest
donor investigated here showing the highest SO shielding contribution,
and SiH3– the highest SO deshielding.
Hydride shifts and Au–H bond-lengths in gold(III) complexes
follow a trend similar to the one observed for linear LAuIH hydrides (see SI, Figure S51 and Tables S1 and S2), with the 1H shifts
in the Au(III) series being systematically shifted upfield.[35]Ligands in cis-positions
have a weaker influence
on hydride shifts (spanning about 6 ppm) but show the opposite trend:
the weakest σ-donors (and strongest π-acceptors) exhibit
the highest deshielding (the most positive 1H hydride shifts).
As demonstrated for the cis-[HAu(bph)L] series with L = NH3, PH3,
CH3 and SiH3– (cf. Figure ), the cis ligand influence has the same qualitative explanation as postulated
for the trans-influence above, but ligands with stronger trans-influence located in the cis-position
decrease the energy gap between the highest-lying σ(Au–H)
bonding MO and Au(dπ)-based MO, just the opposite
of what is seen for the trans-influence (see SI, Figures S52–S53).According to the
data for the cis-[HAu(bph)L] and cis-[HAu(ppy)L] series, the order of increasing cis ligand
influence depends also on the trans ligand. However,
in general the strongest cis-influence
(reflected in the longest Au–H bonds and the most downfield 1H shifts) is observed for neutral weak σ-donors (such
as S, N and O-based ligands) and CO, while anionic ligands exert the
weakest cis-influence, consistent with our experimental
NMR data collected in Table .To conclude, the observed
correlation between measured 1H hydrides shifts and Au–H
bond-lengths has an indirect origin,
but works surprisingly well for a wider set of studied mononuclearAu(III) hydrides (Figure ). This can be attributed to decisive SO-shift contribution
and only marginal changes in paramagnetic shielding. Since Au–H
distances correlate roughly with QTAIM delocalization indices of the
Au–H bond, a reasonable relationship is also established between 1H NMR hydrides shifts and Au–H bond covalency (see Figure ): the more ionic
the Au–H bond, the more positive is the hydride shift.[36,37] Note that the differences in Au–H bond covalency could also
explain the similar reactivities of gold(III) hydrides with C-anionic trans ligands (with δH ranging from −0.6
to +7.0 ppm) and of gold(I) hydride (IPr)AuH (δH =
3.38 ppm/CD2Cl2) toward alkynes: both these
compound types insert DMAD but not less activated alkynes, whereas
the gold(III) pincer hydride (C^N^C)AuH (δH = −6.51
ppm/CD2Cl2) with a much shorter and more covalent
Au–H bond behaves differently and adopts a different mechanism.
Figure 6
Correlation
of computed 1H NMR hydride shifts (in ppm
vs TMS) with QTAIM delocalization indices, DI(Au–H), as a measure
of the bond covalency, for a series of mononuclear Au(III) hydride
complexes (cf. SI, Tables S2–S4 for
numerical data).
Correlation
of computed 1H NMR n class="Chemical">hydride shifts (in ppm
vs TMS) with QTAIM delocalization indices, DI(Au–H), as a measure
of the bond covalency, for a series of mononuclearAu(III) hydride
complexes (cf. SI, Tables S2–S4 for
numerical data).
Conclusions
In
summary, this work shows
that a rather diverse range of gold(III)
hydride complex types is accessible using C^C chelate ligands, and
that stabilization by tridentate pincer ligands is neither a requirement
nor a guarantee for thermal stability. Suitable combinations of cis and trans donors provide access to
the first examples of stable Au(III) hydrido phosphine complexes,
as well as to anionic hydrido halide, hydrido aryl, and even dihydrido
complexes. The biphenyl-based C^C chelate imparts a remarkable stability
toward reductive elimination and successfully suppresses H–C
and even H–H coupling. C^N chelate complexes derived from protodeauration
of (C^N^C) pincer precursors proved to be a convenient platform for
intercepting the first examples of bridging gold(III) hydrides. The
chemistry of the new C^C- and C^C^N-based gold hydrides, with strong
C-donors trans to H, was found to differ significantly
from that of the C^N^C (weak trans donor) coordination
isomers; e.g., the former react only with DMAD but not less activated
alkyl or aryl acetylenes, while for the latter the opposite is found.
Chemical reactivity correlates with the hydride1H NMR
chemical shift, since both are subject to trans and cis ligand effects. On the basis of detailed quantum-chemical
calculations and analysis including relativistic spin–orbit
coupling effects, a linear relationship could be established between
the computed Au–H bond distances, the hydridic character of
the Au–H bond, and the hydride NMR chemical shifts. Strong trans effect ligands, such as C– in (C^C^N)AuH,
raise the deshielding σ(Au–H) orbital and increase the
energetic separation from orbitals with shielding Au(dπ)-type MO, resulting in deshielding (positive chemical shift), whereas
in (C^N^C)AuH σ(Au–H) and Au(dπ) are
close in energy, so that the hydride shift is dominated by the shielding
SO contribution. Whereas trans-ligand influence calculated
for a sequence of hypothetical complexes cover a range of over 22
ppm, cis-ligand influence is more limited, about
6 ppm, although both these effects are mutually interdependent. The
effect of cis-ligands follows an approximate inverse
order to trans-ligands, with the strongest cis-influence (and the longest Au–H bonds) being
observed for the weakest neutral σ-donors. This appears to be
the first systematic evaluation of cis-ligand effects
on 1H chemical shifts in square-planard8 systems.
Experimental Section
General Considerations
When required, manipulations
were performed using standard Schlenk techniques under dry argon or
using a nitrogen-filled MBraun Unilab glovebox equipped with a high
capacity recirculator (<1.0 ppm of O2 and H2O). Argon was purified by passing through columns of supported P2O5 with moisture indicator and of activated 4 Å
molecular sieves. Anhydrous solvents were freshly distilled from the
appropriate drying agents and degassed. Triphenylphosphine (99%),
tris(p-tolyl)phosphine (98%), trimethylphosphine
(1.0 M in THF), dimethylaminopyridine (DMAP, >99%), lithium triethylborohydride
(1.0 M in THF), dimethyl acetylenedicarboxylate (DMAD, 99%) trimethoxysilane
(95%), were obtained by Sigma-Aldrich and dried, when necessary. Solid
LiAlH4 was obtained by vacuum-drying a commercial solution
in THF (Sigma-Aldrich). CD2Cl2 (Apollo Scientific),
THF-d8 and toluene-d8 (Fluorochem Ltd.) were freeze–pump–thaw degassed
over CaH2, distilled and stored over activated 4 Å
molecular sieves. C6F5Ag(CH3CN),[38] [(C^C)AuCl]2,[16] (C^C)AuCl(py) (2),[16] (C^N^C)AuH,[5] (C^N^C)AuMe,[39] (C^N^C)AuC6F5,[40] [H(OEt2)2][H2N{B(C6F5)3}2][28] (HAB2) were synthesized according
to literature procedures. Protodeaurated species [(C^N–CH)AuMe][AB2] (3a) and [(C^N–CH)AuC6F5][AB2] (3b) were generated within
the glovebox, as reported previously.[17]Low-temperature in situ NMR experiments were performed under
anhydrous and anaerobic conditions by using screw cap NMR tubes equipped
with a PTFE septum. In a typical experiment, the gold precursor was
loaded into the NMR tube inside a glovebox and dissolved in the appropriate
solvent. Successively, the sample was inserted into a cold bath at
195 K and the desired reagents were injected through the septum by
using a micrometric gastight syringe. The cold sample was then inserted
into the precooled NMR probe and characterized. 1H, 1H PGSE, 1H inversion recovery, 19F, 13C{1H}, 1H COSY, 1H NOESY, 1H,13C HMQC, and 1H,13C HMBC
NMR experiments were recorded on a Bruker DPX–300 spectrometer
equipped with a 1H,BB smartprobe and Z-gradients. 1H NMR spectra were referenced to the residual protons of the
deuterated solvent. 13C NMR spectra were referenced to
the D-coupled 13C signals of the solvent. 19F NMR spectra were referenced to an external standard of CFCl3. 31P NMR spectra were referenced to an external
standard of H3PO4 85%. Photoisomerization experiments
were performed by using a Blak-Ray B-100 Series high-powered UV lamp
and by irradiating solutions contained in J-Young NMR tubes.
Synthesis
and Characterization of New Gold Precursors
[(C^C)AuCl]2 (200
mg, 0.2 mmol) was stirred inn class="Chemical">dichloromethane (30 mL) with excess
tris-para-tolylphosphine (120 mg, 0.4 mmol) until
a clear solution was obtained. The reaction mixture was filtered through
Celite and the solvent removed under reduced pressure. Hexane was
added, the mixture sonicated briefly and the white solid powder filtered
and washed with hexane. It was then recrystallized from Et2O/hexane to afford (C^C)AuCl(Ptol3) (290 mg, 90%). 1H NMR (300.13 MHz, CD2Cl2, 297 K, J values in Hz) δ 8.38 (dd, 4JHP = 9.5, 4JHH=1.8, 1H, H2), 7.53–7.59 (m, 6H, o-tol3), 7.24–7.32 (m, 8H, m-tol3+H5+H5′), 7.19 (dd, 3JHH = 8.0 4JHH = 1.6,
1H, H4), 7.03 (dd, 3JHH = 8.0 4JHH = 1.8, 1H, H4′), 6.92
(dd, 4JHP = 3.4, 4JHH = 1.8, 1H, H2′), 2.39 (s,
9H, Me), 1.31 (s, 9H, CMe3), 0.67 ppm (s, 9H, CMe3′). 31P{1H} NMR (121.49 MHz, CD2Cl2, 297 K) 40.2 ppm. 13C{1H} NMR (75.47 MHz, CD2Cl2, 297 K, J values in Hz) δ 166.1 (d, 2JCP = 129.6, C1), 154.0 (d, 2JCP = 7.3, C1′), 151.3 (d, 3JCP = 4.5, C6′), 149.7–149.6 (m, C6+C3),
149.2 (d, 4JCP = 2.7, C3), 142.3 (d, 4JCP =
2.4, CMe tol3), 135.1 (d, 2JCP = 11.5, o-tol3), 134.2 (d, 3JCP =
10.2, C2′), 130.5 (d, 3JCP = 1.8, C2), 129.4 (d, 4JCP = 11.2, m-tol3), 125.1 (d, 1JCP = 51.0, ipso–C
tol3), 124.5 (br s, C4), 123.8 (s, C4′),
120.7 (s, C5′), 120.4 (d, 4JCP = 7.6, C5), 35.3 (s, CMe3), 35.4 (s, CMe3′), 31.2 (s, CMe3), 30.4 (s, CMe3′), 21.2 ppm (s, Me tol3). Calcd
for C41H45AuClP (found) C, 61.44 (61.36); H,
5.66 (5.67) %.
(C^C)AuCl(PMe3)
[(C^C)AuCl]2 (270
mg, 0.27 mmol) was stirred inn class="Chemical">THF (10 mL) under Ar. Excess trimethylphosphine
(0.5 mL of 1 M solution in THF, 0.5 mmol) was added at 25 °C
and the mixture was stirred until a clear solution was obtained. The
reaction mixture was filtered through Celite and the solvent removed
under reduced pressure. Hexane was added, the mixture sonicated briefly
and the white solid powder filtered and washed with hexane to afford
(C^C)AuCl(PMe3) (250 mg, 81%). 1H NMR (300.13
MHz, CD2Cl2, 297 K, J values
in Hz) δ 8.29 (br d, 1H, H2), 7.43–7.13 (br m, 5H, H4+H4′+H5+H5′+H2′),
1.85 (d, 2JHP = 10.8, PMe3), 1.34 ppm (s, 18H, CMe3+CMe3′). 31P{1H} NMR (121.49 MHz, CD2Cl2, 297 K) 3.4 ppm. 13C{1H} NMR (75.47 MHz, CD2Cl2, 297 K, J values in Hz) δ
165.2 (d, 2JCP = 138.4, C1),
153.2 (br s, C1′), 151.6 (s, C6′), 149.6 (m, C3+C3′),
149.2 (s, C6), 130.0 (s, C2+C2′), 124.6 (s, C4 or C4′),
124.4 (s, C4′ or C4), 121.5 (s, C5′), 120.4 (brd, 5JCP = 6.6, C5), 35.2 (s, CMe3 or CMe3′),
31.2 (s+s, CMe3+CMe3′), 14.2 ppm (d, 1JCP = 30.4, PMe3).
Calcd for C23H33AuClP (found) C, 48.22 (48.43);
H, 5.81 (5.89) %.
(C^C)Au(C6F5)(py)
C6F5Ag(n class="Chemical">CH3CN) (93 mg, 0.3 mmol)
in Et2O (5 mL) was added to a solution
of 2 (170 mg, 0.3 mmol)
in dichloromethane (5 mL) in a centrifuge tube, with immediate formation
of AgCl. After 5 min, the tube was centrifuged. The clear solution
was decanted and the solvent removed under reduced pressure to afford
the product as a white solid (144 mg, 60%). 1H NMR (300.13
MHz, CD2Cl2, 297 K, J values
in Hz) δ 8.78 (d, 3JHH = 5.2, 2H, o-py), 8.04 (t, 3JHH = 7.8, 1H, p-py), 7.68 (t, 3JHH = 6.7, 2H, m-py), 7.37 (d, 3JHH = 8.0,
1H, H5), 7.32 (d, 3JHH = 8.0,
1H, H5′), 7.18–7.22 (m, 2H, H4+H4′), 6.84 (d, 4JHH = 1.2, 1H, H2), 6.34 (d, 4JHH = 1.2, 1H, H2′), 1.50
(s, 9H, CMe3), 1.08 ppm (s, 9H, CMe3′). 19F NMR (282 MHz, CD2Cl2, 297 K) δ
−120.8 (m, o-F), −159.6 (t, p-F), −161.9 (m, m-F) ppm. 13C{1H} NMR (75.47 MHz, CD2Cl2, 297 K) δ 151.5 (s, C1′), 150.1 (s, o-py), 149.9 (s, C1), 149.5 (s, C6+C6′), 144.5 (s, C3+C3′),
140.1 (s, p-py), 132.4 (s, C2), 127.7 (s, C2′),
127.1 (s, m-py), 124.5 (s, C5), 124.1 (s, C5′),
121.1 (s, C4′), 120.3 (s, C4), 34.6 (s, CMe3), 34.4 (s, CMe3′), 30.92
(s, CMe3), 30.89 ppm (s, CMe3′). Calcd for C31H29Au F5N (found) C, 52.6 (51.96); H, 4.13 (4.55);
N, 1.98 (2.01) %.
[Bu4N][(C^C)AuCl(C6F5)] (15)
(C^C)Au(C6F5)(py) (50 mg, 71 μmol) was
stirred inn class="Chemical">dichloromethane
(5 mL) in the presence of excess tetrabutylammonium chloride (30 mg,
0.1 mmol) for 1 h. The solvent was removed under reduced pressure.
Dichloromethane (5 mL) was added and the mix stirred again for 1 h.
The solvent was removed under reduced pressure. The residue was sonicated
in Et2O and the white powder filtered to yield 15 (45 mg,
98%). 1H NMR (300.13 MHz, CD2Cl2,
297 K, J values in Hz) δ 8.24 (d, 4JHH = 2.0, 1H, H2), 7.25 (d, 3JHH = 8.0, 1H, H5), 7.24 (d, 3JHH = 8.0, 1H, H5′), 7.12 (dd, 3JHH = 8.0, 4JHH = 1.9, 1H, H4), 7.08 (dd, 3JHH = 8.0, 4JHH = 1.9, 1H, H4′), 6.81 (d, 4JHH = 1.6, 1H, H2′), 2.99–3.06 (m, 8H, CH3(CH2)2CH2N), 1.41–1.52 (m, 8H, CH3CH2CH2CH2N), 1.33 (s, 9H, CMe3), 1.26–1.32 (m, 8H, CH3CH2(CH2)2N), 1.10 (s, 9H, CMe3′), 0.92 ppm (t, 3JHH = 7.6, 12H, CH3(CH2)3N). 19F NMR (282 MHz, CD2Cl2, 297 K) −119.6 (m, o-F), −162.3 (t, p-F), −163.2 (m, m-F) ppm. 13C{1H} NMR (75.47 MHz, CD2Cl2, 297 K) δ 151.1 (s, C2′), 150.2 (s, C2), 149.2 (s,
C5′), 148.7 (s, C5), 131.3 (s, C4′), 130.0 (s, C4),
129.9 (s, C1′), 123.4 (s, C3′), 123.1 (s, C3), 120.3
(s, C6′), 120.1 (s, C1), 119.5 (s, C6), 58.6 (s, CH3(CH2)2CH2N), 35.0
(s, CMe3′), 34.3 (s, CMe3), 31.4 (s, C8′), 30.9 (s, C8), 23.8 (s, CH3CH2CH2CH2N), 19.6 (s,
CH3CH2(CH2)2N), 13.4 ppm (s, CH3(CH2)3N). Calcd for C42H60AuClF5N (found) C, 55.64 (55.64); H, 6.68 (6.58); N, 1.55 (1.68)
%.
In Situ NMR Experiments and Data
(C^C^N)AuH
(4)
(C^C^N)n class="Chemical">AuCl (1) (15 mg, 0.0226
mmol) was loaded into a screw cap NMR within the
glovebox and approximately 0.7 mL of dry THF-d8 were added under Ar. The resultant suspension was sonicated
at room temperature for 10 s to obtain a pale-yellow solution. The
NMR tube was then inserted in a cold bath at 195 K and, using a microsyringe,
LiHBEt3 (1 equiv, 22.6 μL of a 1.0 M solution in
THF) was injected through the septum. The sample was quickly shaken
to obtain a bright yellow solution and inserted into the NMR probe
and analyzed at 253 K. 1H NMR (300.13 MHz, THF-d8, 253 K, J values in Hz) δ
8.86 (s, 1H, H1), 8.00 (d, 1H, 3JHH = 8.3, H4), 7.89 (d, 1H, 3JHH = 8.3, H3), 7.70 (s, 2H, H7+H16), 7.65 (d, 2H, 3JHH = 8.3, H19), 7.58 (s, 1H, H9), 7.50
(d, 2H, 3JHH = 8.3, H20), 7.37
(d, 1H, 3JHH = 8.1, H13), 7.17
(dd, 1H, 3JHH = 8.1 4JHH = 1.8, H14), 6.33 (s, 1H, Au–H),
2.36 (s, 3H, Me), 1.38 (s, 9H, C(21)CMe3), 1.34 ppm (s,
9H, C(15)CMe3). 13C{1H} NMR (75.47
MHz, THF-d8, 253 K) δ 184.2 (s,
C11), 165.9 (s, C5), 156.0 (s, C1), 154.9 (s, C12), 151.8 (s, C10),
150.8 (s, C15), 150.2 (s, C21), 145.3 (s, C17), 144.3 (s, C6), 141.5
(s, C3), 140.8 (s, C8), 139.9 (s, C18), 138.4 (s, C16), 136.3 (s,
C2), 127.4 (s, C19), 126.1 (s, C20), 123.8 (s, C14), 121.9 (s, C13),
120.9 (s, C7+C9), 120.8 (s, C4), 35.1 (s, C(15)CMe3), 35.0 (s, C(21)CMe3), 31.5 (s+s,
C(15)CMe3+C(21)CMe3), 17.9 ppm (s, Me). T1 (253 K, THF-d8) Au–H 1.30 s.
Li[(C^C^N)AuH2] (5)
Procedure
(a): In the glovebox under N2, 1 (10 mg, 0.015
mmol) was loaded into a screw-cap NMR tube, and approximately 0.7
mL of dry THF-d8 were added. The resultant
suspension was sonicated at room temperature for 10 s to obtain a
pale-yellow solution. The NMR tube was then inserted in a cold bath
at 195 K and 2.0 equiv LiHBEt3 (30.2 μL of a 1.0
M solution in THF) were injected through the septum by using a microsyringe.
The sample was quickly shaken to give a colorless solution and analyzed
at 263 K. Procedure (b): In the glovebox under N2, 15 mg
of 1 and 3.0 equiv of solid LiAlH4 (2.5 mg)
were loaded into a screw cap NMR tube. The NMR tube was inserted in
a cold bath at 195 K and approximately 0.7 mL of dry THF-d8 were added. The resultant dark suspension was shaken
and the NMR tube was inserted into the precooled NMR probe and analyzed
at 203 K. 1H NMR (300.13 MHz, THF-d8, 263 K, J values in Hz) δ 8.26 (s,
1H, H1), 8.08 (m, 1H, H16), 7.72 (s, 1H, H9), 7.58 (m, 4H, H3+H4+H19),
7.43 (m, 4H, H7+H13+H20), 6.98 (dd, 3JHH = 8.1 4JHH =
2.1, 1H, H14), 2.37 (s, 3H, Me), 1.35 (s, 9H, (C21) CMe3), 1.31 (s, 9H, (C15) CMe3), −0.31 (ps t, 1H, 2JHH = 4.3, Au–Hb), −0.59 ppm (d, 1H, 2JHH = 4.3, Au–Ha). 13C{1H} NMR
(75.47 MHz, THF-d8, 263 K) δ 172.3
(s, C17), 171.1 (s, C11), 167.2 (s, C5), 161.1 (s, C10), 155.4 (s,
C12), 149.6 (s, C21), 149.2 (s, C6), 148.8 (s, C15), 147.5 (s, C1),
140.7 (s, C18), 140.4 (s, C16), 138.1 (s, C8), 137.0 (s, C3), 130.7
(s, C2), 126.9 (s, C19), 126.8 (s, C4), 125.9 (s, C20), 124.3 (s,
C7), 120.7 (s, C14), 120.4 (s, C13), 118.6 (s, C9), 34.8 (s, C(15)CMe3), 34.7 (s, C(21)CMe3), 32.0 (s, C(15)CMe3), 31.6 (s,
C(21)CMe3), 18.4 ppm (s, Me). T1 (−20 °C, THF-d8) Au–Ha 0.80 s, Au–Hb 0.82 s.
Li[(C^C)Au(H)Cl]
(6)
In a glovebox under
N2, 2 (15 mg, 0.026 mmol) was loaded into
a screw-cap NMR tube and dissolved in approximately 0.7 mL of dry
THF-d8. The NMR tube was then inserted
in a cold bath at 195 K and 2.0 equiv LiHBEt3 (52.0 μL
of a 1.0 M solution in THF) were injected through the septum, using
a microsyringe. The sample was quickly shaken to obtain a bright yellow
solution and inserted into the NMR probe and analyzed at 213 K. 1H NMR (300.13 MHz, THF-d8, 213
K, J values in Hz) δ 8.01 (m, 1H, H2′),
7.72 (overlapped with py signals, 1H, H2), 7.20 (d, 1H, 3JHH = 8.2, H5), 7.17 (d, 1H, 3JHH = 8.2, H5′). 6.96 (br d, 1H, 3JHH = 8.2, H4), 6.90 (dd, 1H, 3JHH = 8.2 4JHH = 1.8, H4′), 2.43 (br s, 1H, Au–H),
1.27 (s, 9H, CMe3), 1.25 ppm (s, 9H, CMe3′). 13C{1H} NMR (75.47 MHz, THF-d8, 213 K) δ 174.8 (s, C1′), 153.0 (s, C6), 151.4
(s, C6′), 149.3 (s, C3), 148.4 (s, C1), 147.1 (s, C3′),
139.1 (s, C2), 129.9 (s, C2′), 121.9 (s, C4), 121.8 (s, C4′),
120.1 (s, C5), 118.9 (s, C5′), 34.7 (s, CMe3), 34.1 ppm (s, CMe3′),
31.2 + 31.1 (s+s, CMe3+CMe3′).
(C^C)AuH(DMAP) (7)
A sample of 6 was generated as described
above from 15 mg of 2 and
kept at 195 K. Successively, 4.0 equiv of DMAP (12.7 mg) were dissolved
in 0.3 mL of dry THF-d8 and injected through
the septum by using a gastight syringe to obtain a yellow solution.
The sample was then transferred into the precooled NMR probe and analyzed
at 253 K. 1H NMR (300.13 MHz, THF-d8, 253 K, J values in Hz) δ 8.32 (d, 3JHH = 7.1, 2H, H7), 7.74 (ps t, 4JHH = 2.0, 1H, H2), 7.27 (m, overlapped
with py signals, H5+H5′), 7.03 (dd, 3JHH = 8.1 4JHH =
2.0, 1H, H4), 6.99 (dd, 3JHH = 8.1 4JHH = 2.0, 1H, H4′),
6.92 (dd, 4JHH = 4.5 4JHH = 2.0, 1H, H2′), 6.89 (d, 3JHH = 7.1, 2H, H8), 3.25 (brs,
1H, Au–H), 3.13 (s, 6H, NMe2), 1.29 (s, 9H, CMe3), 1.17 ppm (s, 9H, CMe3′). 13C{1H} NMR (75.47 MHz, THF-d8, 253 K) δ 174.6 (s, C1′), 155.3 (s, C9), 153.3 (s,
C6), 151.8 (s, C6′), 151.1 (s, C7), 148.8 (s, C3), 148.1 (s,
C3′), 144.1 (s, C1), 139.9 (s, C2), 129.0 (s, C2′),
122.8 (s+s, C4+C4′), 119.9 (s, C5 or C5′), 119.2 (s,
C5′ or C5), 108.5 (s, C8), 39.0 (s, NMe2), 35.1
(s, CMe3′), 34.7 (s, CMe3), 31.8 ppm (s, CMe3+CMe3′).
(C^C)AuH(PMe3) (9)
Procedure
(a): A sample of 6 was generated as described above from
15 mg of 2 and kept at 195 K. Successively, 1.0 equiv
of PMe3 (26 μL of a 1.0 M solution in THF) was injected
through the septum by using a gastight syringe to obtain a pale-yellow
solution. The sample was then transferred into the precooled NMR probe
and analyzed at 253 K. Procedure (b): In the glovebox, 20 mg of (C^C)AuCl(PMe3) were loaded into a screw-cap NMR tube and dissolved in approximately
0.7 mL of toluene-d8. Outside the glovebox,
1.0 equiv LiHBEt3 (35 μL of a 1.0 M solution in THF)
were injected through the septum by a microsyringe at room temperature
to give a pale-yellow solution and a white precipitate. The solution
was filtered over Celite into a J Young NMR tube and dried under vacuum
to afford a pale-yellow powder, which was redissolved in dry toluene-d8 and analyzed at room temperature. 1H NMR (300.13 MHz, THF-d8, 253 K, J values in Hz) δ 7.94 (dt, 4JHP = 10.0 4JHH =
1.7, 1H, H2), 7.58 (m, 1H, H2′), 7.32 (d, 3JHH = 8.2, 1H, H5′), 7.28 (dd, 3JHH = 8.2 5JHP = 4.1, 1H, H5), 7.06 (dd, partially overlapped with
H4, 1H, H4′), 7.04 (dd, partially overlapped with H4′,
1H, H4), 1.89 (d, 2JHP = 10.8,
9H, PMe3), 1.53 (brd, 2JHP = 32.6, 1H, Au–H), 1.31 (s, 9H, CMe3′),
1.28 ppm (s, 9H, CMe3). 13C{1H} NMR
(75.47 MHz, THF-d8, 253 K, J values in Hz) δ 168.4 (d, 2JPC = 4.6, C1′), 160.6 (d, 2JPC = 136.2, C1), 154.8 (d, 3JPC = 5.5, C6), 154.1 (s, C6′), 149.3 (d, 4JPC = 10.0, C3), 148.4 (s, C3′),
140.8 (d, 3JPC = 5.4, C2),
133.0 (d, 3JPC = 6.6, C2′),
123.0 (s+s, C4+C4′), 120.5 (m, H5+H5′), 35.0 (s, CMe3′), 34.8 (s, CMe3), 31.7 (s+s, CMe3+CMe3′), 15.9 ppm (d, 1JCP = 32.5, PMe3). 31P{1H} NMR (121.49 MHz, THF-d8, 253 K) −8.2
ppm (s, PMe3). 1H NMR (300.13 MHz, Toluene-d8, 298 K, J values in Hz) δ
8.49 (dt, 4JHP = 10.6 4JHH = 2.0, 1H, H2), 7.58 (d, 3JHH = 8.2, 1H, H5′), 7.54
(m, 2H, H2′+H5), 7.22 (m, 2H, H4+H4′), 1.86 (dm, 2JHP = 34.7, 1H, Au–H),
1.39 (s+s, 18H, CMe3+CMe3′), 1.03 ppm
(d, 2JHP = 10.2, 9H, PMe3).
A sample of 12 was generated
in THF-d8 and treated at room temperature
with substoichiometric
portions of [H(OEt2)2][H2N{B(C6F5)3}2] until reacting a
stoichiometric ratio of acid/Au of 1.2. Upon addition of the acid,
the deep orange color of 12 faded to give a pale-yellow
solution and the formation of a dark precipitate. 1H NMR
spectroscopy revealed the complete disappearance of 12 to give 19 in 65% yield. NMR characterization is given
in mixture.1H NMR (300.13 MHz, n class="Chemical">THF-d8, 298 K, J values in Hz) δ
7.43 (dd, 3JHH = 8.1, 4JHH = 2.0, 1H, H4), 7.34 (d, 3JHH = 8.5, 2H, H4′), 7.24
(m, 2H, H5+H8),
7.20 (d, 3JHH = 8.5, 2H, H5′),
6.83 (s, H8), 3.54 (s, 3H, H12), 3.3 (s, 3H, H10), 1.34 (s, 9H, CMe3), 1.32 ppm (s, 9H, CMe3′). Partial 13C{1H} NMR (75.47 MHz, THF-d8, 298 K) δ 165.8 (s, C9), 165.4 (s, C11), 149.7 (overlapped
with AB2, C3′), 149.4 (s, C3), 138.8 (overlapped
with AB2, C6′+C6), 133.0 (s, C1), 128.9 (s, C8),
128.8 (s, C5), 128.7 (s, C5′), 127.3 (s, C8), 125.4 (s, C4),
124.5 (s, C4′), 51.2 (s, C10), 50.8 (s, C12), 34.7 (s+s, CMe3+CMe3′),
30.7 ppm (s, CMe3+CMe3′).
[(C^N–CH)AuH(μ-H)Au(C^N^C)][AB2] (20)
Within the glovebox, 15 mg
of (C^N^C)AuH were
loaded into a screw-cap NMR tube and dissolved in approximately 0.3
mL of dry CD2Cl2. One equiv [H(OEt2)2][H2N{B(C6F5)3}2] (33.1 mg, 0.028 mmol) was dissolved in 0.4 mL of dry
CD2Cl2 and loaded into a gastight syringe equipped
with a rubber stopper. Outside the glovebox, the NMR tube was inserted
into a cold bath at 198 K and the acid solution was slowly injected
through the septum at low temperature. The sample was then shaken
quickly, inserted in the precooled NMR probe and studied at 213 K.
Extensive decomposition was observed after 1 h at 213 K. 1H NMR (300.13 MHz, CD2Cl2, 213 K, J values in Hz) δ 8.23 (t, 3JHH = 8.0, 1H, H1), 8.08 (d, 3JHH = 8.0, 1H, H2), 7.79 (m, 3H, H5+H2′+H1a), 7.60 (m,
2H, H6+H8), 7.38 (m, 8H, H5′+H2a+H5a+H6a), 7.17 (m, 4H, H6′+H8a),
5.56 (br s, NH2), 1.13 (s, 9H, CMe3), 1.03 (s,
18H, CMe3a), 0.81 (s, 9H,CMe3′), −4.93
(d, 2JHH = 8.6, 1H, Hb), −8.47
ppm (br d, 2JHH = 8.6, 1H,
Ha).
[(C^N–CH)AuMe(μ-H)Au(C^N^C)][AB2] (21)
Ten mg of (C^N^C)AuMe and
1.0 equiv of [H(OEt2)2][H2N{B(C6F5)3}2] were loaded within
a screw cap NMR and
dissolved in approximately 0.5 mL of CD2Cl2.
Outside the glovebox, the NMR sample was inserted in a cold bath at
195 K and 1.0 equiv (C^N^C)AuH (9.7 mg, 0.018 mmol, dissolved in 0.3
mL of CD2Cl2) were injected through the septum
to give a bright yellow solution, which was quickly shaken and inserted
into the precooled NMR probe at 213 K. 21 was observed
in 65% yield, along with unreacted 3a. Partial 1H NMR (300.13 MHz, CD2Cl2, 243 K, J values in Hz) 8.21 (m, 2H, H1+H2), 7.89 (m, 2H, H1a+H2′),
7.72 (br d, overlapped with 3a, H5), 7.50 (br d, 3JHH = 8.1, 1H, H6), 7.43 (m, 6H, H2a+H5a+H5′),
7.34 (br s, 4H, H8a+H6′), 7.27 (s, overlapped with 3a, H8),
7.20 (d, 3JHH = 8.1, H6a),
5.62 (br s, NH2), 1.71 (s, 3H, Au–Me), 1.26 (s,
9H, CMe3), 1.08 (s, overlapped with Et2O, CMe3a), 0.76 (s, 9H, CMe3′), −5.14 ppm
(s, 1H, Au–H–Au).
[(C^N–CH)AuMe(μ-H)MeAu(C^N–CH)][AB2] (22a)
Fifteen mg of (C^N^C)AuMe
and 1.0 equiv
of n class="Chemical">[H(OEt2)2][H2N{B(C6F5)3}2] were loaded within a screw
cap NMR and dissolved in approximately 0.6 mL of CD2Cl2. Outside the glovebox, the NMR sample was inserted in a cold
bath at 195 K and 5.0 equiv of HSi(OMe)3 were injected
through the septum. The sample was quickly shaken and inserted in
the precooled NMR probe at 243 K. 1H NMR (300.13 MHz, CD2Cl2, 243 K, J values in Hz) δ
8.18 (t, 3JHH = 7.8, 2H, H1),
8.06 (d, 3JHH = 7.8, 2H, H2),
7.76 (d, 3JHH = 8.2, 2H, H5),
7.46 (d, 3JHH = 7.8, 2H, H2′),
7.42 (d, 3JHH = 8.2, 2H, H6),
7.33 (br m, 4H, H8+H6′a), 7.21 (d, 3JHH = 8.4, 2H, H5′a), 6.77
(d, 3JHH = 8.2, 2H, H6′b), 6.55 (d, 3JHH =
8.2, 2H, H5′b), 5.66 (br s, 2H, NH2),
1.35 (s, 3H, Au–Me), 1.31 (s, 18H, CMe3), 0.75 (s,
18H, CMe3′), −2.53 ppm (s, 1H, Au–H–Au). 13C{1H} NMR (75.47 MHz, CD2Cl2, 223 K, J values in Hz) δ 161.2 (s, C3),
160.3 (s, C3′), 154.9 (s, C7), 154.1 (s, C9), 153.5 (s, C7′),
147.5 (br d, 1JCF = 238.5, o–F H2N[B(C6F5)3]2–), 141.8 (s, C1), 141.2 (s,
C4), 138.9 (br d, 1JCF = 250.0, p–F H2N[B(C6F5)3]2–), 136.5 (br d, 1JCF = 250.0, m–F
H2N[B(C6F5)3]2–), 137.2 (s, C4′), 130.7 (s, C5′a), 127.2 (s, C8+C5), 126.2 (s, C6), 125.7 (s+s, C5′b+C6′a), 125.2 (s, C6′b), 124.4 (s, C2′), 118.8 (s, C2), 35.7 (s, CMe3), 34.3 (s, CMe3′),
30.9 (s, CMe3), 30.2 (s, CMe3′), 10.0 ppm (s, Au–Me).
[(C^N–CH)AuC6F5(μ-H)Au(F5C6)(C^N–CH)][AB2] (22b)
Fifteen mg of (C^N^C)AuC6F5 and
1.0 equiv n class="Chemical">[H(OEt2)2][H2N{B(C6F5)3}2] were loaded within
a screw-cap NMR and dissolved in approximately 0.6 mL of CD2Cl2. Outside the glovebox, the NMR sample was inserted
in a cold bath at 195 K and 5.0 equiv HSi(OMe)3 were injected
through the septum. The sample was quickly shaken and inserted in
the precooled NMR probe at 223 K. 1H NMR (300.13 MHz, CD2Cl2, 223 K, J values in Hz) δ
8.34 (t, 3JHH = 7.8, 2H, H1),
8.13 (d, 3JHH = 7.8, 2H, H2),
7.78 (d, 3JHH = 8.2, 2H, H5),
7.56 (d, 3JHH = 7.8, 2H, H2′),
7.50 (m, 4H, H5′a+H6′a), 7.38
(d, 3JHH = 8.2, 2H, H6), 7.07
(d, 3JHH = 8.3, 2H, H6′b), 6.33 (d, 3JHH =
8.3, 2H, H5′b), 6.07 (s, 2H, H8), 5.64 (br s, 4H,
NH2), 1.00 (s, 18H, CMe3), 0.82 (s, 18H, CMe3′), −2.21 ppm (s, 1H, Au–H–Au). 13C{1H} NMR (75.47 MHz, CD2Cl2, 223 K, J values in Hz) δ 162.2 (s, C3),
160.3 (s, C3′), 159.5 (s, C9), 156.5 (s, C7), 154.8 (s, C7′),
147.5 (br d, 1JCF = 239.8, o–F H2N[B(C6F5)3]2–), 143.3 (s, C1), 138.9 (s,
C4), 138.8 (br d, 1JCF = 250.0, p–F H2N[B(C6F5)3]2–), 136.4 (br d, 1JCF = 250.0, m–F
H2N[B(C6F5)3]2–), 134.9 (s, C4′), 130.0 (s, C5′a), 129.4 (s, C8), 128.2 (s, C5), 127.9 (s, C6′a), 127.5 (s, C6′b), 127.2 (s, C6), 126.2
(s, C2′), 125.7 (s, C5′b), 119.5 (s, C2),
35.5 (s, CMe3), 34.7 (s, CMe3′), 30.5 (s, CMe3), 29.9 ppm (s, CMe3′). 19F NMR (282.4 MHz, CD2Cl2, 223 K, J values in Hz) −118.2 (dq, 3JFF = 25.7 4JFF = 6.0,
1F, o–F Au–C6F5), −119.7 (d ps t, 3JFF = 27.7 4JFF = 6.4, 1F, o–F Au–C6F5), −133.2
(br s, 12F, o–F H2N[B(C6F5)3]2–), −154.8
(t, 3JFF = 21.0, 1F, p–F Au–C6F5), −159.4
(t, 3JFF = 21.1, 1F, p–F H2N[B(C6F5)3]2–), −160.1 (m, 1F, m–F Au–C6F5), −164.9
ppm (brm, 13F, m–F Au–C6F5 + m–F H2N[B(C6F5)3]2–).
Authors: Aleix Comas-Vives; C Gonzalez-Arellano; A Corma; M Iglesias; F Sanchez; Gregori Ujaque Journal: J Am Chem Soc Date: 2006-04-12 Impact factor: 15.419
Authors: Luca Rocchigiani; Julio Fernandez-Cestau; Gabriele Agonigi; Isabelle Chambrier; Peter H M Budzelaar; Manfred Bochmann Journal: Angew Chem Int Ed Engl Date: 2017-10-02 Impact factor: 15.336
Authors: Pavel V Kovyazin; Almira Kh Bikmeeva; Denis N Islamov; Vasiliy M Yanybin; Tatyana V Tyumkina; Lyudmila V Parfenova Journal: Molecules Date: 2021-05-08 Impact factor: 4.411