University of Groningen
Chemistry of vanadium-carbon single and double bondsBuijink, Jan Karel Frederik
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Publication date:1995
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Citation for published version (APA):Buijink, J. K. F. (1995). Chemistry of vanadium-carbon single and double bonds. s.n.
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* This work has been performed in collaboration with R. Zijlstra. Part of this work has been performed at the
California Institute of Technology under supervision of Prof. R. H. Grubbs. Part of this chapter has been
communicated: Buijink, J.-K. F.; Meetsma, A.; Teuben, J. H. Organometallics 1993, 12, 2004-2005.
49
Chapter 2__________________________________________________________
Homoleptic Alkyl Complexes of Vanadium(III)*__________________________________________________________
2.1 Introduction
Sterically demanding alkyl groups lacking ß-hydrogens (e.g. neopentyl, neophyl) have
played an important role in the development of transition metal olefin metathesis1 and ring-
opening metathesis polymerization2 (ROMP) catalysts. Transition metal complexes containing
these alkyl groups are known to decompose thermally through α-hydrogen abstraction to givemetal alkylidenes.3 A relatively small number of vanadium complexes incorporating these alkyl
groups are known,4 with V[CH(SiMe3)2]34c being the only example of a homoleptic V(III)
alkyl complex. The thermal decomposition of these compounds has been investigated only in
the case of the monocyclopentadienyl bis(neopentyl) complex CpV(CH2-t-Bu)2PMe3.4m The
vanadium alkylidene species produced in the thermal decomposition of this compound are
active as catalysts for ROMP of norbornene, although the activity of the isolated alkylidene
CpV(CH-t-Bu)dmpe is low (vide infra).
In this chapter the synthesis and reactivity of vanadium(III) complexes, containing
sterically demanding alkyl groups lacking β-hydrogens, but without stabilizingcyclopentadienyl ligands is described. A special section is reserved for the activity of these
compounds in olefin metathesis reactions.
2.2 Attempted synthesis of homoleptic alkyl complexes of vanadium(III).
Reaction of VCl3(THF)3 with three equivalents of t-BuCH2Li in diethyl ether under
nitrogen does not yield the expected homoleptic tris(neopentyl) vanadium complex, but
instead, the bridged dinitrogen complex [(t-BuCH2)3V]2(µ-N2) (1), which was isolated in
45% yield (eq 1). Compound 1 is a red-brown crystalline solid, poorly soluble in aliphatic and
aromatic hydrocarbons and extremely air sensitive (pyrophoric). To determine the molecular
structure of 1 an X-ray structure determination was carried out. The crystal structure of 1
involves the packing of 3 molecules in the hexagonal unit cell. The asymmetric unit contains
Chapter 2: Homoleptic alkyl complexes of vanadium(III).
49
one neopentyl fragment and a V and a N atom at a 3-fold axis. The molecular structure of 1 is
shown in Fig. 1. Selected bond lengths and angles are given in Table I.
(1)V N N V
t-Bu
t-But-Bu t-Bu
t-But-Bu
1
VCl3(THF)3 + 3 t-BuCH2Li - 3 LiCl, 3 THFN2, Et2O
1/2
Table I. Selected geometrical data for [(t-BuCH2)3V]2(µ-N2) (1).
Bond lengths (Å)
V(1)-N(1) 1.7248(18)
V(1)-C(1) 2.0262(16)
N(1)-N(1)c 1.250(3)
C(1)-C(2) 1.532(2)
C(2)-C(3) 1.525(2)
C(2)-C(4) 1.529(2)
C(2)-C(5) 1.531(2)
Bond angles (°)
N(1)-V(1)-C(1) 109.70(4)
C(1)-V(1)-C(1)a 109.24(6)
V(1)-N1)-N(1)c 180(-)
V(1)-C(1)-C(2) 129.57(9)The label a indicates the symmetry operation 1-y, 1+x-y, z; label c 2/3-x, 4/3-y, 1/3-z.
Molecule 1 consists of two identical tris(neopentyl) vanadium fragments linked by a
bridging dinitrogen ligand, the molecule possessing 3 symmetry. The vanadium atoms have a
tetrahedral environment, three of the coordination sites are occupied by neopentyl groups, the
remaining position by the µ-N2 ligand. The orientation of the two tris(neopentyl) vanadium
fragments is staggered, with all the t-Bu groups pointing inward, an effect that might be due
to crystal packing or could result from maximalization of dispersion forces. The closest
contacts between the t-Bu hydrogens of the two tris(neopentyl) vanadium units are in the
order of 3 Å, similar to those found in liquid apolar solvents. The V-C bond distances, all
2.0262 (16) Å, are among the shortest reported for V-C single bonds: for comparison, the
vanadium-carbon distances in Mes3VO5 are in the range 2.022(4)-2.079(3) Å, those in Li[( t-
Bu3SiN)2VMe24j are 2.043(5) and 2.057(8) Å. The V-N distances [1.7248(18) Å] are shorter
than those found in the V(II)-(µ-N2) complex (µ-N2){[( o-Me2NCH2)C6H4]2V(Py)}2(THF)2[1.833(3)/ 1.832(3) Å].6 These V-N bond lengths come close to V=N bond lengths observed
in imido complexes of V(IV) and V(V) (usually 1.60-1.68 Å).7
Chapter 2: Homoleptic alkyl complexes of vanadium(III).
50
Figure 1. Molecular structure of [(t-BuCH2)3V]2(µ-N2) (1), with adopted numbering scheme, front view (top)
and side view (bottom).
Chapter 2: Homoleptic alkyl complexes of vanadium(III).
51
This observation is in agreement with the perfectly linear arrangement of the V-(µ-
N2)-V unit and the rather long N-N distance [1.250(3) Å], which is comparable to the mean
nitrogen-nitrogen bond length of 1.24 Å observed for several diazo compounds RN=NR (R =
F, Me, Ph).8
Like for other transition metals, the isolable molecular nitrogen complexes for
vanadium can be divided into two classes on the basis of the oxidation state of the metal. In
low oxidation state complexes like [Na(THF)][V(N2)2(Ph2PCH2CH2PPh2)2]9 [V(-I)] the
dinitrogen ligands have bond orders of ~3 and bond distances only slightly longer than that in
free N2 (1.0976 Å).10 The high oxidation state complexes (µ-N2){[( o-
Me2NCH2)C6H4]2V(Py)}2(THF)26 [V(II)] and {Na[O(CH2CH2OMe)2]2}[Na(VMes3)2(µ-
N2)]11 [V(II)] contain bridging dinitrogen ligands in which the bond order is more reduced
(~2) as evidenced by the relatively long N-N distance of 1.228(4) Å and 1.280(21) Å,
respectively. Complex 1 represents the first example of a V(III) molecular dinitrogen complex
and is in that sense comparable to the bridging dinitrogen complexes of Nb(III) and
Ta(III).12,13
The bonding between metal and nitrogen in µ-dinitrogen transition metal complexeshas been evaluated mainly with the help of the simple qualitative molecular orbital scheme
pictured in Fig. 2.
MM N N
MM N N
MM N N
MM N N 1e
2e
3e
4e
Figure 2. Qualitative four center molecular orbital scheme for binuclear dinitrogen complexes.
This scheme describes the four center M-N-N-M interactions in an idealized four-fold
symmetry.14 The molecular orbitals arise from linear combinations of Mdxz and Npx orbitals.
Because of the presence of an equivalent set of molecular orbitals arising from combinations
Chapter 2: Homoleptic alkyl complexes of vanadium(III).
52
of Mdyz and Npy the energy levels of the molecular orbitals are degenerate. The model has
been used to explain the differences between N-N bond lengths in µ-N2 complexes. In
complexes possessing a high number of d-electrons available for M-N bonding, such as
{[Ru(NH3)5]2(µ-N2)} 4+, the first µ-N2 complex that was characterized by X-ray
crystallography,15 the 3e MO, which is bonding in respect to N2, is filled, leading to a short N-
N bond (1.124 Å). This N-N bond is only slightly longer than the N-N bond in free
dinitrogen.10 In complexes with fewer d-electrons available for M-N bonding, such as the
niobium and tantalum bridging dinitrogen complexes [M(PMe3)(CH-t-Bu)(CH2-t-Bu)]2(µ-
N2),12,13 only the 2e MO, which is anti-bonding in respect to N2, is filled. In these complexes
the N-N bond distance is increased to approximately 1.30 Å. Although no bonding scheme is
available for the present vanadium µ-N2 complex, which has a three-fold symmetry, the
bonding is expected to be similar to that in the niobium and tantalum complexes. The low
number of d-electrons available for M-N bonding in 1 would allow only filling of a molecular
orbital which is similar to the 2e MO in Fig. 2, thus explaining the observed elongated N-N
bond in 1. Molecular orbital calculations, which could provide a more quantitative insight in
the bonding in µ-N2 complex 1, are in progress. The niobium and tantalum µ-N2 complexes
of Schrock et al. have been the subject of both crystallographic studies13 and Fenske-Hall
molecular orbital calculations.16 The MO calculations show that the actual bonding in these µ-
N2 complexes is more complicated than assumed above, whereas on the basis of the X-ray
data a simple, easily understood description of the bonding was devised by Schrock and
Churchill.12,13 In this description, the four d-electrons available for M-N bonding in the
complexes [M(PMe3)(CH-t-Bu)(CH2-t-Bu)]2(µ-N2), are fully transferred from the metal to
the more electronegative element nitrogen. The bonding is then discussed in terms of d0 metal
centers and the bridging N2 ligand formally acting as a hydrazido N24- (or diimido) group. The
bond order in the N-N linkage of an N24- group should be 1, with an estimated bond length of
1.45 Å, explaining the elongated N-N bonds observed in the niobium and tantalum µ-N2complexes. For vanadium, which is more difficult to oxidize than the heavier group 5
members, this description seems less appropriate.
1 is diamagnetic (by NMR spectroscopy), displaying a simple 1H NMR spectrum with
one resonance for the hydrogens of the methyl groups and one resonance for the methylene
protons, which is broadened (∆ν1/2 = 33) by a combination of unresolved coupling to the I =7/2 vanadium nucleus and quadrupolar relaxation effects.4e,f The broadening is even more
pronounced for the methylene carbon resonance in the 13C NMR spectrum, which is observed
as a plateau-form resonance with a half-width of approximately 3000 Hz. Tetrahedral
vanadium complexes tend to be high-spin and therefore paramagnetic. However,
delocalization of unpaired d-electrons on the tetrahedral vanadium centers in 1 through the
Chapter 2: Homoleptic alkyl complexes of vanadium(III).
53
bridging dinitrogen ligand might reduce the barrier for spin-pairing, thus allowing the complex
to become diamagnetic.
The 51V NMR spectrum of 1 shows a moderately-resolved quintet at 1237 ppm. The
low field chemical shift reflects the electron deficiency of the metal atom.4i The quintet results
from coupling of vanadium to both 14N (I = 1) atoms, with the one- and two-bond coupling
constants appearing to be equal (48 Hz), although the width of the resonances precludes
accurate determination. For the labelled complex [(t-BuCH2)3V]2(µ-15N2) (1-15N2) (vide
infra) a moderately resolved triplet (15N; I = 1/2) with an apparent V-15N coupling constant
of 76 Hz is obtained. Nearly equal one- and two-bond coupling constants of metal to 15N in
µ-N2 complexes have been observed before by Schrock et al. for [C5Me5WMe3](µ-15N2).17
This behavior is in agreement with a significant degree of delocalization throughout the
MNNM system.
In agreement with observations made by Schrock et al. on M-(µ-N2)-M systems (M =
Mo, W)17,18 an absorption of medium intensity at 858 cm-1 in the IR spectrum of 1 is
tentatively assigned to a V=N stretch. It shows the expected shift to lower energy when 14N2is replaced by 15N2 (839 cm-1 in 1-15N2). Due to the fact that 1 is centrosymmetric, the N-N
stretching vibration is not IR active.
Reaction of VCl3(THF)3 with three equivalents of PhMe2CCH2Li in diethyl ether
afforded the tetrahydrofuran adduct of tris(neophyl) vanadium(III), (PhMe2CCH2)3V.THF
(2), which could be isolated in 20% yield (eq 2).
(2)VCl3(THF)3 + 3 PhMe2CCH2Li V THF
Me2CPh
Me2CPhMe2CPh
Et2O
- 3 LiCl, 2 THF
2
2 is a dark-blue, crystalline paramagnetic (by NMR spectroscopy) complex, readily
soluble in aliphatic and aromatic hydrocarbons. The compound decomposes rapidly (hours) at
ambient temperatures in solution and slowly (days) in the solid state, but can be kept
indefinitely at -20 °C.An X-ray structure determination of 2 was carried out. The crystal structure of 2
involves the packing of 4 molecules in the unit cell. The molecular structure of 2 is depicted in
Fig. 3, selected geometrical data are given in Table II.
Chapter 2: Homoleptic alkyl complexes of vanadium(III).
54
Figure 3. Molecular structure of (PhMe2CCH2)3V.THF (2), with adopted numbering scheme.
Table II. Selected geometrical data for (PhMe2CCH2)3V.THF (2).
Bond lengths (Å)
V-C(1) 2.103(4)
V-C(11) 2.080(4)
V-C(21) 2.080(5)
V-O 2.025(3)
C(1)-C(2) 1.556(6)
C(11)-C(12) 1.540(6)
C(21)-C(22) 1.546(6)
Bond angles (°)
O-V-C(1) 109.6(1)
O-V-C(11) 108.1(1)
O-V-C(21) 113.7(1)
C(1)-V-C(11) 109.8(2)
C(1)-V-C(21) 109.0(2)
C(11)-V-C(21) 106.5(2)
V-C(1)-C(2) 129.4(3)
V-C(11)-C(12) 130.1(3)
V-C(21)-C(22) 128.0(3)
The molecular structure of 2 shows a tetrahedral arrangement of the three neophyl
groups and the THF ligand around the vanadium atom, with bond angles varying between
106.5(2)° and 113.7(1)°. The three V-C bond distances are identical within experimentalorder and range from 2.080(5) to 2.103(4) Å. They compare well to those found in the
isostructural VMes3.THF19 (2.099(6)-2.116(7) Å), while they are significantly longer than
those found in the dinitrogen bridged vanadium(III) tris(neopentyl) dimer (1) (vide supra). In
Chapter 2: Homoleptic alkyl complexes of vanadium(III).
55
this molecule the size of vanadium is reduced by partial donation of electrons to the nitrogen
ligand. Another interesting feature of 2 is the way in which the phenyl groups of the neophyl
ligands are arranged. They are all positioned at the same side of the molecule and seem to
form a pocket in which the THF molecule lies. Two of the phenyl rings are arranged parallel
to the THF ring, one is arranged perpendicular. The same behavior is found in the neopentyl
compound 1 where all the t-Bu groups point to the center of the molecule, thereby shielding
the dinitrogen ligand. It is unclear whether this situation exists only in the solid state, as a
result of crystal packing, or is also present in solution, possibly due to London dispersion
forces.
The reaction leading to 2 can be performed both under argon and nitrogen. In the last
case, the formation of a bridging dinitrogen complex as observed for the corresponding
neopentyl derivative, is not observed. Cooling of pentane solutions of 1 under nitrogen to -80
°C did not lead to the formation of a bridging dinitrogen complex, contrasting the behaviorobserved for the tris(neopentyl) species (t-BuCH2)3V.THF (vide infra) where upon cooling
THF is readily displaced by dinitrogen even in THF solutions. It is likely that the stability of
the dinitrogen complex 1 depends largely on the shielding of the dinitrogen moiety by the
neopentyl ligands, thus precluding easy displacement of the dinitrogen ligand by stronger
Lewis bases. The structure of 2 indicates that the neophyl groups also tend to shield the
remaining coordination site on vanadium. However, given the short inter atomic distances
between the t-Bu groups of the two tris(neopentyl)vanadium centers in 1, replacing neopentyl
by neophyl to give [(PhMe2CCH2)3V]2(µ-N2) would lead to increased steric strain in thishypothetical molecule compared to 1. The steric strain would probably induce a more open
structure, thereby making the dinitrogen ligand more susceptible to displacement by Lewis
bases and preventing isolation of a stable dinitrogen complex in the neophyl case.
2.3 Reactivity of the dinitrogen complex [(t-BuCH2)3V]2(µ-N2) (1).
Dinitrogen activation by early transition metals has become a well-studied subject over
the past decades.20 This research has mainly been initiated by the discovery of early transition
metal containing nitrogenases (V,21 Mo,22 W23) in dinitrogen-fixing bacteria such as Azobacter
and Anabaena. A number of dinitrogen-fixing model systems based on vanadium have been
published,6,9,11,24,25 varying from V(II) catechol systems which catalytically reduce dinitrogen
to ammonia in the pH range 9-11,24b to the V(-I) system [V(N2)2(Me2PCH2CH2PMe2)2]-
which produces approximately 4/3 mol of ammonia upon protonation with HCl.25 The
composition of the products (NH3, N2H4) of dinitrogen reduction by these systems seems to
be largely dependent on the number of electrons26 that can be released by the metal:20 in the
latter system 4 electrons are involved and the metal is oxidized from V(-I) to V(III), whereas
Chapter 2: Homoleptic alkyl complexes of vanadium(III).
56
protonation of (µ-N2){[( o-Me2NCH2)C6H4]2V(Py)}2(THF)2 produces 2/3 mol of ammonia
with the involvement of 1 electron per V [V(II) → V(III)]. 27 Leigh analyzed these and otherresults in a thermodynamic context by assuming that the availability of electrons from a metal
atom is an expression of the redox potential exhibited for oxidation states selected.20 His
conclusions support the observed product formation of the V(II) and V(-I) dinitrogen systems
upon protonation.
Neither ammonia nor hydrazine is produced when 1 is treated with excess HCl in
diethyl ether under inert atmosphere. Instead neopentane is produced while the complexed
dinitrogen is liberated quantitatively (Töpler pump determination) (eq 3).
(3)V N N V
t-Bu
t-But-Bu t-Bu
t-But-Bu
1
HCl, Et2O 2 VCl3 + 6 CMe4 + N2
It appears that, despite the fact that the dinitrogen ligand in 1 is considerably reduced
and therefore expected to be readily protonated, proton attack occurs only at the peripheral
methylene groups of the neopentyl ligands. This phenomenon might be explained by assuming
that the molecular structure in the solid state of 1 is also the dominant structure in solution. In
this case, the HOMO of 1, which is likely to be localized mainly on the VNNV moiety, is
shielded by the neopentyl ligands. Therefore, the HOMO is less susceptible to attack by
electrophiles, and electrophilic attack is likely to occur at the next best site of electron density,
the V-C bonding orbitals. Because of the bending of the neopentyl ligands these molecular
orbitals are easily accessible for small electrophiles such as H+.
An extension of Leigh's analysis for the higher oxidation states of group 5 metals also
predicts that dinitrogen is not reduced by V(III), but that Nb(III) and Ta(III) should be able
to reduce N2 to ammonia. Indeed, the M(III) dinitrogen-bridged complexes
[{M(S 2CNEt2)3} 2N2] [M = Nb (N-N = 1.252(16) Å), Ta) produce hydrazine quantitatively
upon protonation.28 It is, however, questionable to what extent Leigh's approach, which is
based upon the comparison of oxidation potentials for a series of redox couples in aqueous
acid solution, can be extended to organometallic compounds such as 1. The approach would
be more meaningful if oxidation potentials of organometallic systems in non-aqueous
solutions could be used, but these are available only for a limited number of redox couples.
Chapter 2: Homoleptic alkyl complexes of vanadium(III).
57
The rest of the reactivity of 1 is dominated by loss of dinitrogen. With Lewis bases L 1
reacts to give dinitrogen and the corresponding V(III) adducts (Me3CCH2)3V.L [3, L = PMe3(a), pyridine (b), t-BuCN (c)] (eq 4).
t-But-Bu
t-But-But-Bu
t-Bu
V N N V
t-Bu
t-But-Bu
2 L2 V L (4)
3 a: L = PMe3 b: L = pyridine c: L = t-BuCN
- N2
1
The adducts 3 are paramagnetic oils, which are very soluble in pentane. They have
colors typical for V(III) species,19 varying from blue-green (3a) to purple (3b), and are
characterized by their shifted, broad resonances for the methyl protons of the neopentyl
ligands. No loss of dinitrogen is observed when 1 is dissolved in diethyl ether, a weak Lewis
base. Reversible coordination of dinitrogen is observed in tetrahydrofuran (Scheme 1).
t-But-Bu
t-But-But-Bu
t-Bu
V N N V
1
2 THF- N2
t-Bu
t-But-Bu
2 V THFN2
15
cooling
t-But-Bu
t-But-But-Bu
t-Bu
V N N V 1515
1- N215
-2 THF
Scheme 1. Reversible coordination of dinitrogen by 1.
Upon dissolving 1 in THF dinitrogen is liberated quantitatively (Töpler pump
determination) over a period of several minutes, while the color of the solution changes from
Chapter 2: Homoleptic alkyl complexes of vanadium(III).
58
red-brown via green to intense blue. Cooling of tetrahydrofuran solutions of (t-
BuCH2)3V.THF (3d) under dinitrogen to -80 °C shows the reverse color change and theformation of crystalline 1. This behavior can be used to produce [(t-BuCH2)3V]2(µ-15N2) (1-15N2) when the nitrogen atmosphere is replaced by 15N2. Similar color changes are observed
in the salt metathesis reaction producing 1. The initial blue color of the reaction product in
diethyl ether (3d) changes to green upon replacement of the solvent by pentane and then to
red-brown with the formation of 1 upon cooling. The green color is thought to arise from the
mixing of the red-brown color of 1, which might be partially formed, and the blue color of
3d.
2.4 Oxidation and insertion reactions with 1 and 2.
As described in chapter 1, two electron oxidation provides a valuable tool in the
characterization of paramagnetic V(III) complexes, since it produces diamagnetic V(V)
complexes which can be analyzed by a range of NMR spectroscopical techniques. For the
complexes 1 and 2 two electron oxidation would yield rare V(V) tris(alkyl) species.
Attempted synthesis of these species by alkylation of vanadium(V) precursors was successful
only in two cases,4i,l due to the easy reduction of vanadium(V) to lower oxidation states by
the alkylating reagent. On the other hand, oxidation of homoleptic V(III) complexes to V(V)
might be hampered by the fact that in this kind of complexes the metal-carbon σ bond isnormally the most reactive center, thus leading to insertion of the oxidizing agent in a metal-
carbon bond instead of oxidation. Direct oxidation of the metal center by oxidizing agents like
oxygen or oxygen transfer reagents has thus far been reported only for alkyl/aryl chromium29
and aryl vanadium5,30 complexes.
Reaction of 1 (eq 5) and 2 (eq 6) with styrene oxide produces yellow, crystalline
OV(CH2CMe2R)3 (4a, R = Me; 4b, R = Ph), rare examples of vanadium(V) oxo complexes
OVR3 (R = CH2SiMe3,4a R = Mes5,30).
(5)V N N V
t-Bu
t-But-Bu t-Bu
t-But-Bu
1
O
Ph- N2, 2
Ph
2
t-But-Bu
t-Bu
V O
4a
Chapter 2: Homoleptic alkyl complexes of vanadium(III).
59
(6)V THF
Me2CPh
Me2CPhMe2CPh
2
O
Ph- THF,
Ph
Me2CPhMe2CPh
Me2CPh
V O
4b
The complexes 4 a and b are very soluble in all common organic solvents, and are
also observed to be the major products of air oxidation of 1 and 2. They crystallize in the
form of very long and thin needles, which prevented their analysis by X-ray diffraction. Their
thermal stability is low, both in solution and in the solid state, but they can be stored for
indefinite time at -25 °C.The complexes 4a and 4b are characterized by their infrared spectra, showing strong
absorptions for the V=O bonds at 984 and 1001 cm-1, respectively. These absorptions are
found on the high energy end of the range reported for monooxo vanadium complexes (1035-
875 cm-1),7 implicating relatively strong vanadium-oxo bonds in 4a and 4b. The 1H and 13C
NMR spectra of diamagnetic 4 show broad, plateau-form resonances for both the methylene
protons and the methylene carbons, characteristic for vanadium(V) alkyl complexes.4j The
resonances of 4 in the 51V NMR spectra are found at the low field end of the 51V chemical
shift range.4i A very common feature in metal NMR spectroscopy of transition metal
complexes in the d0 configuration is an increase of shielding with increasing electronegativity
χ of the ligands attached to the coordination center.31 This trend, the "inverse" χ dependenceof metal shielding has been observed, among others, in a number of vanadium systems like
OVX3 (X = Br, Cl, F),32 t-BuNVX3 (X = Cl, Br, OR),
33 and p-tolylNVX 3 (X = Cl, OR,
CH2SiMe3),4i and seems to be determined mainly by the difference in energy between the
HOMO and LUMO orbitals. The energy difference increases with increasing electronegativity
of the ligand X, thus leading to a decrease in the overall paramagnetic shielding experienced
by the vanadium atom, and resulting in a high-field shift for the 51V NMR resonances.4i,34
Comparing the 51V chemical shifts within a series of OVR3 complexes could provide
information upon the relative electronegativities of the R groups. Unfortunately, the number
of OVR3 complexes, other than those reported here, for which 51V NMR data are available is
limited to one (e.i. OV(CH2SiMe3)3).35 Nevertheless, the shielding in OVR3 complexes is
observed to increase in the order OV(CH2-t-Bu)3 (δ 1212) < OV(CH2SiMe3)3 (δ 1205) <OV(CH2CMe2Ph)3 (δ 1191), thus suggesting the electronegativity of the alkyl group R toincrease in the same order.
Reaction of 1 with the substituted diazomethane Ph2CN2 also proceeds through
liberation of nitrogen and oxidation of (t-BuCH2)3V(III) to vanadium(V), but in this case
Chapter 2: Homoleptic alkyl complexes of vanadium(III).
60
insertion of the diazomethane in V-C bonds is an important side reaction. The reactions that
occur are shown in Scheme 2.
V N N V
t-Bu
t-But-Bu t-Bu
t-But-Bu
1
1/2Ph2CN2- 1/2 N2
Ph2CN2
Ph2CN2
t-But-Bu
t-Bu
V NN CPh2
CPh2NN
t-But-Bu
Vt-Bu
N
NCPh2
t-Bu
N
NCPh2
CPh2NN
t-But-Bu
V
N
N CPh2
56
Scheme 2. Reaction of 1 with diphenyldiazomethane.
The first step in this reaction is thought to be coordination of diphenyldiazomethane to
1, similar to the reactions of 1 with Lewis bases discussed above, followed by a break-up of
the dimeric structure and the formation of two molecules of (t-BuCH2)3V=N-N=CPh2. This
molecule is believed to be a vanadium(V) tris(neopentyl) imido complex. Two electron
oxidation of V(III) to form V(V) imido complexes upon reaction with diazomethanes has
been observed before by Schrock et al. in the reaction of V[N(CH2CH2NSiMe3)3] with
(trimethylsilyl)diazomethane.36 In general, early transition metals not in their highest oxidation
state form complexes that contain metal-nitrogen multiple bonds with substituted
diazomethanes,37 whereas late transition metals tend to produce complexes containing metal-
carbon double bonds under evolution of nitrogen.1a The imido vanadium(V) tris(neopentyl)
complex could neither be isolated nor observed by 1H NMR spectroscopy during low-
temperature studies, due to its fast reaction with diphenyldiazomethane to form the mono and
bis insertion products (t-BuCH2)2V(N(CH2-t-Bu)N=CPh2)NNCPh2 (5) and (t-
BuCH2)V(N(CH2-t-Bu)N=CPh2)2NNCPh2 (6), respectively. Complexes 5 and 6 are both
crystalline materials, but only 6 could be obtained reproducibly in good yield. The mono
insertion product 5 was obtained pure on one occasion in a poor yield from the reaction of 1
Chapter 2: Homoleptic alkyl complexes of vanadium(III).
61
with two equivalents of diphenyldiazomethane (V:N = 1:1). All other attempts at varying
temperatures and with varying stoichiometries led to mixtures of either 1 and 5 (V:N < 1) or
5 and 6 (V:N > 1), the latter presumably due to fast insertion of diphenyldiazomethane in 5.
Insertion of diphenyldiazomethane in 6 was not observed.
Complexes 5 and 6 are diamagnetic (by NMR spectroscopy) and are characterized as
vanadium(V) imido complexes by the low-field 13C resonances (δ 163.0 and 158.2 ppm,respectively) for the imine-like, sp2-hybridized carbon of the non-inserted diazomethane
molecule. The inserted diazomethane molecules form amido ligands N(CH2-t-Bu)NCPh2,
with the CH2 group displaying characteristic low-field shifted triplets (JCH = 135 Hz) in the13C NMR spectra. The vanadium-bound CH2 groups in 5 give rise to a broad resonance at δ100 ppm in the 13C NMR spectrum, and two doublets in the 1H NMR spectrum. It is assumed
that both 5 and 6 have a tetrahedral structure about vanadium and that the imido-
diazomethane lies in plane with the inserted diazomethane in 5 and with the remaining
neopentyl group in 6. This would render the vanadium-bound CH2 groups in 5 diastereotopic,
and the nitrogen-bound CH2 groups in 6 as well. The 1H NMR spectrum of 6 displays the
expected two doublets for the nitrogen-bound CH2 groups and a singlet for the vanadium-
bound CH2 group. Furthermore, in each 1H NMR spectrum two resonances for the neopentyl
methyl groups can be found, in a 2:1 ratio. The 51V NMR spectra of the two complexes show
resonances which are too broad to detect any V-N coupling, consistent with a highly
unsymmetrical environment.4i The resonance for 5 at δ 541 ppm shows the expected high-field chemical shift upon replacement of a neopentyl group by a more electronegative amido
ligand (6, δ -176 ppm).4i Moderate to strong resonances in the IR spectra of 5 and 6 at 972cm-1 are tentatively assigned to V=N stretches.17
Attempts to verify the proposed and rather unique structures of 5 and 6 by means of
X-ray diffraction failed because no single crystals of sufficient quality could be obtained.
Structures in which the second nitrogen of the inserted diazomethane is interacting with
vanadium, a bonding situation similar to those observed for early transition metal acyls,
cannot be excluded a priori on the basis of the present spectroscopic data.
Exploratory experiments, performed on micromolar scale in benzene-d6 at 25 °C,suggest that 1 and 2 also undergo two electron oxidation in reaction with 2-methylaziridine
(giving R3V=NH) and sulfur (R3V=S), albeit that the reactions are not clean. Research in this
field is still in progress. No reactions of 1 and 2 were observed with Se, Me3SiN3,
PhCH=PPh3 or PhN=PPh3 (one equivalent per V, benzene-d6, 25 °C).
2.5 Olefin metathesis reactions.
Chapter 2: Homoleptic alkyl complexes of vanadium(III).
62
Until now no reports have appeared on olefin metathesis chemistry of d0 vanadium
complexes. This might be mainly due to the absence of d0 alkylidene species for vanadium,
although several suitable precursors for d0 vanadium alkylidenes have been reported.4a,i,j,l To
get a better understanding of the activity of d0 vanadium in olefin metathesis reactions, the
activity of two possible precursors for d0 vanadium alkylidenes was examined in an
exploratory fashion. As possible precursors were taken the bridged dinitrogen complex [(t-
BuCH2)3V]2(µ-N2) (1) and the oxo-vanadium complex OV(CH2-t-Bu)3 (4a).
The thermal decomposition of these two high-valent vanadium tris(neopentyl)
compounds was studied first, in order to establish their suitability as precursors for d0
vanadium alkylidenes. The products of α-hydrogen abstraction, the assumed pathway for theformation of metal alkylidenes, should be neopentane (CMe4).
Thermal decomposition of 1 (benzene, 25 °C, 16 h) produces large amounts of CMe4(> 2 equivalents) but no dinitrogen (Töpler pump experiment). Therefore, it is likely that 1
decomposes through one or more α-hydrogen abstractions (Fig. 4), leading to vanadiumalkylidenes and/or alkylidynes as dimers which still contain the bridging N2-ligand, and are
therefore likely to be d0 compounds.
V N N V
t-Bu
t-But-Bu t-Bu
t-But-Bu
α-H abstr.
- CMe4
α-H abstr.
- CMe4
α-H abstr.
- CMe4
t-But-But-Bu
t-Bu
V N N V
t-Bu
t-Bu
V N N V
t-Bu
t-Bu
t-Bu t-Bu
t-Bu
t-Bu
V N N V
Figure 4. Possible α-hydrogen abstractions in 1.
Attempts to stabilize these species by performing the thermal decomposition in the
presence of Lewis-bases (L) like PMe3 or THF lead only to loss of dinitrogen and formation
of relatively stable vanadium(III) Lewis-base adducts (t-BuCH2)3V.L (vide infra). The
organometallic products of the consequent thermolysis of these adducts are virtually
Chapter 2: Homoleptic alkyl complexes of vanadium(III).
63
insoluble, black materials, which give no NMR signals, probably as a result of the low
solubility.
Like 1, 4a is thermally not stable at room temperature, decomposing in solution with a
half-live time of 4-6 hours at 25 °C. Thermal decomposition gives CMe4 and intractable,insoluble black materials, tentatively formulated as vanadium(V) alkylidenes/alkylidynes.
Thermolysis of 4a in the presence of Lewis-bases yielded neopentane and soluble
decomposition products, but these compounds are NMR silent, suggesting homolytic splitting
of vanadium-carbon bonds and the formation of lower valent vanadium species.
In the presence of norbornene, thermal decomposition of 1 and 4a induces the ring-
opening metathesis polymerization of norbornene, but not of less strained cyclic olefins such
as cyclopentene and cyclooctene. Likewise, no metathesis of acyclic olefins was observed by
thermal decomposition products of 1 and 4a. Activity in olefin metathesis was checked by
studying the isomerization of cis-3-hexene to the thermodynamically more stable trans-3-
hexene, which is catalyzed by metal-alkylidenes (eq 7). The isomerization can easily be
followed by 1H NMR spectroscopy (olefinic protons).
Et Et Et
Et
M=CHR(7)
The polymerization of norbornene by thermal decomposition products of 1 and 4a was
studied in more detail. The polymerizations were first performed on a small scale and studied
by 1H NMR spectroscopy to get a qualitative idea about the rate of polymerization, then on a
larger scale to be able to isolate and study the physical properties of the polymers.
At room temperature polymerization was found to be slow, with conversions after 24
h not higher than 20%. At 60 °C higher conversions were obtained, ranging from 65% for 1to 98% for 4a after 24 h. After 4-5 h at 60 °C about 80% of the final conversion is reached,and the rate of polymerization begins to slow down, probably due to thermal inactivation of
the catalyst. An effort was made to see the propagating species in the NMR spectrum by
looking at the nucleophilic alkylidene hydrogen region (δ ≈ 15-10 ppm), but no resonanceswere found, not even at very high concentrations of catalyst precursor (up to the solubility
limits). This could mean that the propagating species is only present in very low
concentrations, or is a paramagnetic V(III) or V(IV) species.
For the polymer obtained from the polymerization experiment of 1 with norbornene at
25 °C it was first established that the polymer was indeed polynorbornene formed by ROMPof norbornene by comparison of its 1H NMR spectrum with that of an authentic sample. Then
the cis- and trans-content was calculated from the integrations of the 13C and 1H NMR
spectra.38 In both cases values of 27% cis and 73% trans were obtained. The values for Mn,
Chapter 2: Homoleptic alkyl complexes of vanadium(III).
64
Mw and the polydispersity as obtained by gel permeation chromatography (GPC) can be
found in Table III (see Experimental). The values given are corrected for the differences in
physical properties between polynorbornene and polystyrene.39 From the value for Mn(81000) it can be concluded that the average number of norbornene units in a polymer is
about 900. Since the ratio of olefin/1 was 100 at the start of the polymerization, this must
mean that no more than about 10% of the catalyst precursor produces an active catalyst,
assuming that all polymer chains grow at a similar rate. The calculated polydispersity of 2.14
is high. A value close to unity would mean a polymer with a very narrow molecular weight
distribution, and therefore well defined physical properties.40 The molecular weight
distribution observed here reflects the formation of catalytically active species in the
thermolysis of 1.
The cis:trans ratio of the polymers obtained from ROMP of norbornene induced by 4a
at 25 °C and 1 and 4a at 60 °C does not deviate dramatically from the statistical 1:1 in any ofthe experiments. The GPC data for these polymers show several (2 to 3) overlapping broad
curves (estimated polydispersities higher than 2.5). This so-called multimodal behavior can be
explained by assuming that several catalytic species producing polymers with different
molecular weight distributions are active at the same time. Since the catalyst precursors are
multi-alkyl species repeated α-hydrogen abstractions could account for the formation ofseveral catalytically active species.
2.6 Concluding remarks.
Salt metathesis of VCl3(THF)3 with three equivalents of t-BuCH2Li or PhMe2CCH2Li
produces homoleptic vanadium(III) alkyl fragments VR3 (R = t-BuCH2, PhMe2CCH2), which
can be isolated as the dinitrogen complex [(t-BuCH2)3V]2(µ-N2) and the THF adduct
(PhMe2CCH2)3V.THF, respectively. The dinitrogen complex represents the first dinitrogen
complex of vanadium(III). Based upon the molecular structure the dinitrogen ligand can
considered to be highly reduced, but this is not reflected in the reaction with HCl, where
dinitrogen is liberated quantitatively instead of being reduced to hydrazine or ammonia.
Reaction with Lewis bases L also proceeds with loss of dinitrogen to produce the Lewis base
stabilized complexes (t-BuCH2)3V.L.
Oxidation of the VR3 fragments provides in some cases routes to vanadium(V)
tris(alkyl) complexes. Oxygen transfer from styrene oxide produces the oxo vanadium(V)
complexes R3VO, whereas the dinitrogen complex reacts with diphenyldiazomethane through
oxidation and insertion in V-C bonds to form vanadium(V) imido amido alkyl complexes.
The thermal decomposition of two of the high-valent vanadium alkyl complexes
presented here, and the activity of the decomposition products in olefin metathesis reactions
Chapter 2: Homoleptic alkyl complexes of vanadium(III).
65
were investigated. Although the dinitrogen complex and the tris(neopentyl) oxo complex are
rather poor catalyst precursors for ring-opening metathesis polymerization of norbornene, and
are not active in the polymerization of less strained cyclic olefins or the metathesis of non-
cyclic olefins, it can be concluded from these investigations that the thermal decomposition of
these alkyl complexes produces high-valent vanadium alkylidenes, which are active as
catalysts for ROMP of norbornene. The activity of these alkylidenes prepared in situ is
markedly higher than the activity of the only isolated nucleophilic alkylidene for vanadium
CpV(CH-t-Bu)dmpe (chapter 1), which is a d2 alkylidene. On the basis of these results it can
therefore be expected that well-defined, d0 vanadium alkylidenes are active in ROMP of
strained cyclic olefins.
2.7 Experimental.
General details. All manipulations were performed under nitrogen or argon (when stated)
using Schlenk techniques or a glove box, or using vacuum line techniques. Solvents [diethyl
ether, tetrahydrofuran (THF), pentane (mixed isomers), benzene, and deuterated solvents]
were distilled from Na/K alloy before use. NMR spectra were recorded on a Varian VXR-300
(1H, 300 MHz; 13C, 75.4 MHz; 51V, 78.9 MHz) spectrometer in benzene-d6 at 20 °C (unless
stated otherwise), chemical shifts in ppm, downfield from TMS (δ 0.00, 1H, 13C) or VOCl3 (δ0.00, 51V) positive. Half-width values and coupling constants are reported in Hz. IR spectra
were recorded on a Mattson-4020 Galaxy FT-IR spectrophotometer from Nujol mulls
between KBr discs (unless stated otherwise), wave numbers in cm-1. Gel permeation
chromatography was performed on a Waters GPC-120C instrument, molecular weights are
reported relative to narrow molecular weight polystyrene. Elemental analyses were performed
at the Microanalytical Department of the University of Groningen. Values given are the
average of at least two independent determinations.
Materials. VCl3(THF)341 and Ph2CN2
42 were prepared according to published procedures. t-
BuCH2Li and PhMe2CCH2Li were prepared from the corresponding alkyl chloride by
refluxing with two equivalents of lithium in hexane, followed by filtration and crystallization
at -25 °C. Styrene oxide (Janssen) was dried over molecular sieves (4 Å) and distilled beforeuse. Norbornene, cyclooctadiene and cyclopentene (Aldrich) were dried over sodium,
distilled and stored under nitrogen. Cis-3-hexene (Trans World), t-BuCN, pyridine (Janssen)
were used as received. PMe3 was prepared according to an adapted literature procedure,43
using MeMgI instead of MeMgBr.
[(t-BuCH2)3V]2(µ-N2) (1). Onto a mixture of VCl3(THF)3 (2.67 g, 7.14 mmol) and t-
BuCH2Li (1.67 g, 21.44 mmol), 40 mL of diethyl ether was condensed at -196 °C. The
Chapter 2: Homoleptic alkyl complexes of vanadium(III).
66
mixture was thawed out and warmed to 20 °C while being stirred. After 1 h the solvent was
removed in vacuo. The residue was extracted twice with 25 mL of pentane. Concentrating
and cooling the combined extracts to -25 °C yielded 0.90 g (45 % based on V) of red-brown
crystals: 1H NMR δ 2.13 (∆ν1/2 = 33, 12H, CH2), 1.21 (s, 54H, CMe3); 13C NMR δ 118-108(CH2), 37.6 (CMe3), 34.0 (CMe3); 51V NMR δ 1237 (quintet, average 51V-14N couplingconstant 48); IR 2775(w), 2688(w), 2681(w), 1363(m), 1257(w), 1234(s), 1076(m),
1058(m), 931(w), 858(m), 752(m), 563(m), 490(m). Anal. Calcd for C30H66V2N2: C, 64.72;
H, 11.95; V, 18.29. Found: C, 62.49; H, 11.51; V, 18.49. Carbon and hydrogen data are low
due to explosive burning of the compound with oxygen.
(PhMe2CCH2)3V.THF (2). Onto a mixture of VCl3(THF)3 (1.66 g, 4.44 mmol) and
PhMe2CCH2Li (1.87 g, 13.33 mmol), 40 mL of diethyl ether was condensed at -196 °C. Themixture was thawed out and allowed to warm up to 25 °C while being stirred. After 1 h thesolvent was removed in vacuo. The residue was extracted twice with 20 mL of pentane.
Concentrating and cooling of the combined blue extracts to -25 °C yielded 0.47 g (0.90mmol, 20%) of dark-blue crystals: 1H NMR δ 18 (∆ν1/2 = 800), 8.4 (∆ν1/2 = 600), 7.5 (∆ν1/2= 50), 6.9 (∆ν1/2 = 50), 5.6 (∆ν1/2 = 300), -3.4 (∆ν1/2 = 650). IR 1792(w), 1690(w),1597(m), 1493(m), 1358(m), 1300(w), 1269(m), 1207(w), 1184(m), 1167(m), 1109(w),
1078(w), 1030(m), 1010(m), 918(w), 902(w), 856(s), 763(s), 721(m), 700(s), 594(m),
567(w), 532(m). Anal. Calcd for C34H47VO: C, 78.13; H, 9.06; V, 9.75. Found: C, 77.80; H,
9.02; V, 9.92.
Protonation of [(t-BuCH2)3V]2(µ-N2) (1). Under argon, 1 (129 mg, 0.23 mmol) was
dissolved in 30 mL of diethyl ether. To the clear solution 6.8 mL of a 0.68 M solution of HCl
in diethyl ether (4.6 mmol) was added. For the determination of hydrazine 25,0 mL of
distilled water was added. No hydrazine could be detected by a spectrophotometric method.44
In a second run the organic volatiles were removed in vacuo, and a modified Kjehldahl
distillation was performed.45 No ammonia could be detected in the distillate by a
spectrophotometric method using Nessler's reagent.46
(t-BuCH2)3V.L (3a-d). For 3a-c 2 equivalents of L were added with a syringe to 0.1-0.2
mmol of 1 in 0.4 mL of benzene-d6. For 3d 0.1 mmol of 1 was dissolved in 0.4 mL of THF-
d8. 1H NMR spectra were recorded after 15 minutes at 25 °C over the range +100 to -100
ppm: 3a (L = PMe3, blue-green) δ 0.1 (∆ν1/2 = 120, 27H, t-Bu), -1.5 (∆ν1/2 = 600, 9H,PMe3); 3b (L = pyridine, blue-purple) δ -2.6 (∆ν1/2 = 300, t-Bu); 3c (L = t-BuCN, green) δ3.9 (∆ν1/2 = 120, 27H, t-Bu), -1.5 (∆ν1/2 = 410, 9H, t-BuCN); 3d (L = THF, dark-blue) δ3.0 (∆ν1/2 = 360, t-Bu).
Chapter 2: Homoleptic alkyl complexes of vanadium(III).
67
[(t-BuCH2)3V]2(µ-15N2) (1-15N2). Onto 1 (31 mg, 0.055 mmol) was condensed
approximately 4 mL of THF at -196 °C in a 60 mL Schlenk vessel connected to a vacuum
line equipped with a Töpler pump. After thawing out, the mixture was stirred for 15 minutes
at 25 °C, yielding a blue solution, from which 0.037 mmol of N2 (68%) could be pumped off
in 2 freeze/thaw cycles. 15N2 was added (1 atm.), and the vessel was kept at -80 °C for 16 h,
causing a color change to red-brown and the deposit of a small amount of red-brown
microcrystalline material: 51V NMR δ 1237 (triplet, average 51V-14N coupling constant 76);IR 2775(w), 2688(w), 2681(w), 1363(m), 1257(w), 1234(s), 1076(m), 1058(m), 931(w),
839(m), 752(m), 563(m), 490(m).
(t-BuCH2)3VO (4a). Styrene oxide (0.24 g, 2.01 mmol) was added to a solution of 1 (0.56
g, 1.00 mmol) in 20 mL of benzene. After stirring for 3/4 h at 20 °C the solvent was removed
in vacuo and the residue extracted with 40 mL of pentane. Cooling the extract to -25 °C
yielded 0.38 g (1.36 mmol, 68 % based on V) of yellow crystals: 1H NMR (toluene-d8): δ1.73 (∆ν1/2 = 92, 6H, CH2), 1.08 (s, 27H, CMe3); 13C NMR δ 120-107 (CH2), 37.6 (CMe3),34.0 (CMe3); 51V NMR δ 1212 (∆ν1/2 = 50); IR 2737(vw), 2702(vw), 1361(vs), 1255(m),1234(s), 1170(vw), 1121(vw), 1076(m), 1062(s), 1016(m), 984(vs), 933(m), 912(m), 748(s),
594(s), 573(m), 509(s). Anal. Calcd for C15H33VO: C, 64.26; H, 11.86; V, 18.17. Found: C,
63.39; H, 11.63; V, 18.57. Carbon and hydrogen data are low due to explosive burning of the
compound with oxygen.
(PhMe2CCH2)3VO (4b). To a blue solution of 2 (0.19 g, 0.36 mmol) in 10 mL of benzene
was added styrene oxide (41 µL, 0.36 mmol) at 25 °C. After stirring for 15 minutes at thistemperature the organic volatiles were removed in vacuo and the oily residue was extracted
with 20 mL of pentane. Concentrating and cooling of the yellow extract to -80 °C gave 0.10g (0.21 mmol, 50 %) of yellow needles in two crops: 1H NMR δ 7.2 (m, Ar H), 7.05 (m, ArH), 1.64 (CH2, ∆ν1/2 = 80), 1.38 (s, CMe2); 13C NMR (toluene-d8, -10 °C) δ 151.0 (Ar C),128.5 (Ar C), 125.9 (Ar C), 125.7 (Ar C), 120-108 (CH2), 41.6 (CMe2Ph), 31.1 (CMe2Ph);51V NMR δ 1191 (∆ν1/2 = 63). IR 1784(w), 1599(w), 1493(m), 1304(w), 1269(w), 1207(w),1186(m), 1111(w), 1080(m), 1028(w), 1014(w), 1001(s), 763(s), 723(m), 696(s), 594(w),
542(w). Anal. Calcd for C30H39VO: C, 77.23; H, 8.43; V, 10.92. Found: C, 76.77; H, 8.46;
V, 11.27.
(t-BuCH2)2V(N(CH2-t-Bu)N=CPh2)NNCPh2 (5). Diphenyldiazomethane (0.25 g, 1.30
mmol) was added to a solution of 1 (0.36 g, 0.65 mmol) in 20 mL of benzene at 25 °C. Afterthe evolution of N2 had ceased (10 min) the organic volatiles were removed in vacuo. The
brown oily residue was extracted with 30 mL of pentane. Concentrating and cooling of the
extract to -25 °C gave 69 mg (0.106 mmol, 8%) of shiny brown-green crystals: 1H NMR δ
Chapter 2: Homoleptic alkyl complexes of vanadium(III).
68
8.1, 7.8, 7.1 (3 m, 20H, Ar H), 2.91 (s, 2H, NCH2), 2.53 (d, 2H, JHH = 9, CHH), 1.71 (d,
2H, JHH = 9, CHH), 1.10 (s, 18H, CMe3), 0.89 (s, 9H, NCH2CMe3); 13C NMR δ 163.0(NN=CPh2), 140.4, 139.4, 137.6, 137.5, 137.1, 130.8, 130.5, 130.1, 129.3, 128.8, 128.6,
128.5, 128.3, 128.1, 127.9, 127.5 (Ar C), 100 (∆ν1/2 = 400, VCH2), 70.6 (t, JCH = 135,NCH2), 38.5 (CMe3), 33.8 (CMe3), 33.2 (NCH2CMe3), 28.0 (NCH2CMe3); 51V NMR δ 541(∆ν1/2 = 1000). IR 1263(m), 1232(w), 1199(w), 1153(m), 1126(w), 1074(m), 1026(m),972(m), 935(w), 918(w), 891(w), 763(s), 723(s), 702(s).
(t-BuCH2)V(N(CH 2-t-Bu)N=CPh2)2NNCPh2 (6). Diphenyldiazomethane (0.39 g, 2.01
mmol) was added to a solution of 1 (0.28 g, 0.50 mmol) in 15 mL of benzene at 25 °C. Afterthe evolution of N2 had ceased (10 min) the solution was stirred for 10 minutes. Removal of
the organic volatiles in vacuo gave a brown oily residue that was extracted with two times 20
mL of pentane. Concentrating and cooling of the combined extracts to -25 °C gave 0.32 g(0.37 mmol, 56% based on Ph2CN2) of orange needles: 1H NMR δ 8.1, 7.9, 7.6, 7.3, 7.1 (5m, 30H, Ar H), 2.63 (s, 2H, CH2), 3.31 (d, 2H, JHH = 14, NCHH), 2.85 (d, 2H, JHH = 14,
NCHH), 1.23 (s, 9H, CMe3), 1.12 (s, 18H, NCH2CMe3); 13C NMR δ 158.2 (NNCPh2),140.4, 139.4, 137.6, 137.5, 137.1, 130.8, 130.5, 130.1, 129.3, 128.8, 128.6, 128.5, 128.3,
128.1, 127.9, 127.5 (Ar C), VCH2 not observed, 70.0 (t, JCH = 135, NCH2), 37.7 (CMe3),
33.8 (CMe3), 32.5 (NCH2CMe3), 28.9 (NCH2CMe3); 51V NMR δ -176 (∆ν1/2 = 1060). IR1305(w), 1263(m), 1230(w), 1201(w), 1174(w), 1151(m), 1130(w), 1074(m), 1028(m),
1001(w), 972(s), 916(w), 889(w), 763(s), 723(s), 698(s), 677(w), 650(w), 603(m), 570(w),
536(w), 482(m). Anal. Calcd for C54H63N6V: C, 76.57; H, 7.50; V, 6.01. Found: C, 75.93;
H, 7.43; V, 6.32.
Thermal decomposition of 1 and 4a. NMR: Solutions of 1 (10 mg, 0.018 mmol) and 4a (15
mg, 0.054 mmol) in 0.4 mL of benzene-d6 were monitored by 1H NMR periodically over a
period of 24, both at 25 °C, and in a second run at 60 °C. The resonances due to the staringmaterial disappeared, and the formation of a dark precipitate was observed. The only new
resonance was due to neopentane (δ 0.90 ppm). Töpler pump: Under high-vacuum conditionsapproximately 4 mL of benzene was condensed onto 1 (38 mg, 0.068 mmol) at -196 °C in avessel equipped with a Young valve. The valve was closed and the vessel allowed to warm up
to 25 °C. After 24 h of stirring at 25 °C the gaseous products produced (0.148 mmol) werepumped off with a Töpler pump by repeated freeze(-80 °C)/thaw cycles. In a secondexperiment with 1 (40 mg, 0.072 mmol) 0.186 mmol of gas was obtained. In both cases, all of
the gas could be condensed at -196 °C, indicating that no N2 had formed.ROMP of cyclic olefins with 1. In a dry box 100-400 equivalents of a cyclic olefin (see
Table III) were added to a 0.01 mM solution of 1 (13 mg, 2.3 x 10-5 mol) in benzene (1.47
g) in a 10 mL vial. After mixing the vial was closed and left standing for 17-100 h (see Table
Chapter 2: Homoleptic alkyl complexes of vanadium(III).
69
III) at 25 °C with occasional shaking. The resulting mixtures were worked up according tothe general workup procedure for polynorbornene (see below).
Table III. Survey of the activity of 1 in ROMP of strained cyclic olefins ([1] = 0.01 mmol/L).________________________________________________________________________________________
cyclic olefin ratio olefin:1 reaction time polymera GPC-datab
________________________________________________________________________________________
norbornene 100 17 h 20 % Mn = 81000Mw = 170000PDI = 2.14
cyclooctadiene 100 100 h 0 % -cyclopentene 400 100 h 0 % -________________________________________________________________________________________
a percentage of recovered cyclic olefin as a polymer after isolation (vide infra) is given. b Gel permeation
chromatography data recorded in CH2Cl2, PDI is polydispersity (Mw/Mn).
Attempted metathesis of cis-3-hexene with 1 and 4a. A typical experiment using 4a as a
catalyst precursor is described. In a dry box a solution of 4a (2.4 mg, 8.7 µmol) in 0.5 mL ofbenzene-d6 was placed in an NMR tube fitted with a septum. Cis-3-hexene (10 µL, 80 µmol)was added with a syringe. No isomerization of cis-3-hexene (olefinic protons at 5.37 ppm) to
trans-3-hexene (olefinic protons at 5.47 ppm) at room temperature was observed over a 24 h
period.
ROMP of norbornene with 1 and 4a. NMR: Solutions of 1 (2 mg, 3.6 µmol) and 4a (1.6mg, 5.7 µmol) were dissolved in 0.4 mL of benzene-d6 together with a 50-100 fold excess ofnorbornene. The solutions were kept at 25 °C, and in a second run at 60 °C. The reactionswere monitored periodically by 1H NMR spectroscopy over a period of 24 h. The formation
of polynorbornene and decomposition of the organometallic starting materials were observed,
but no vanadium alkylidene species could be detected. The conversions of norbornene were
estimated on the basis of the integrals of the resonances in the olefinic region. Preparative
scale: In a dry box 100 equivalents of norbornene were added to a 0.01 mM solution of
catalyst precursor in benzene in a reagent tube. After mixing, the tube was closed with a
septum. The tubes were placed in a 60 °C oil bath outside the dry box for 15 h and thenworked up according to the general procedure for polynorbornene (see below).
Isolation of polynorbornene. The polymer/catalyst/solvent gel was dissolved in CH2Cl2containing 5 weight percent of butylated hydroxytoluene (BHT) and a few drops of methanol
(for quenching any still active catalyst). The amount of solvent required was about 0.5 mL for
20 mg of expected polynorbornene. The obtained solution was filtered through glasswool to
remove any precipitate and through silica to remove decomposition products of the catalyst.
The silica column was eluted with more CH2Cl2/BHT solution to make sure that all
Chapter 2: Homoleptic alkyl complexes of vanadium(III).
70
polynorbornene had come off. For small amounts of polynorbornene these filtrations can
conveniently be performed in Pasteur pipettes. The now clear and colorless polynorbornene
solution was added dropwise to about ten times its volume of methanol under rapid stirring.
The finely divided white polynorbornene obtained in this manner was isolated by
centrifugation. After the solvent had been decanted, the solid polynorbornene was dried
immediately in vacuo and handled under inert atmosphere to prevent cross linking of the
polymer induced by oxygen.
Table IV. Crystallographic Data for 1 and 2.
1 2
formula
fw
cryst syst
space group
a, Å
b, Å
c, Å
β, deg
V, Å3
Z
dcalcd, g cm-3
F(000), e
µ (Mo Kα), cm-1
cryst size, mm
T, K
θ limits, deg
no. of data collcd
no. unique data
no. reflns obsd
no of params refined
R(F)
Rw(F)
w
C30H66N2V2
556.75
trigonal
R3
10.072(1)
29.494(1)
2591.2(4)
3
1.0703(2)
918.0
5.4
0.22x0.22x0.12
130
1.00 < θ < 27.0
2033
1264
1131
97
0.027
0.030
1/σ2(F0)
C34H47OV
522.7
monoclinic
P21/n
8.845(5)
29.496(4)
12.289(4)
110.28(3)
3007(2)
4
1.15
1128
3.40
0.30x0.30x0.30
172
2.5 < θ < 25
5411
2512
325
0.043
0.049
1/σ2(F0)
References and notes.
Chapter 2: Homoleptic alkyl complexes of vanadium(III).
71
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