Highly Reactive Organosamarium Chemistry via Metal Vapor and Sm

Feb 26, 1987 - William J. Evans. Department of Chemistry, University of California—Irvine, Irvine, CA 92717. High-Energy Processes in Organometallic...
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Chapter 17

Highly Reactive Organosamarium Chemistry via Metal Vapor and Sm(II) Syntheses William J. Evans Department of Chemistry, University of California—Irvine, Irvine, CA 92717 The reactivity of the lanthanide metals with unsaturated hydrocarbons has been studied via the metal vapor method in which lanthanide vapor at 400-1500ºC is cocondensed with an organic substrate at -196ºC. By using this high energy process on a synthetic scale, unusual types of complexes were produced which demonstrated new avenues of reactivity for the lanthanide metals and for lanthanide complexes in general. One of these processes, oxidation addition of C-H to a lanthanide metal center, was further examined using samarium vapor andC Μe Ηand generated two new highly reactive molecules, (CMe)Sm and (C Me ) Sm(THF) . These species, the first soluble organometallic com­ plexes of Sm(II), are reactive due to the large reduc­ tion potential of Sm(II) and have an extensive chem­ istry with CO and unsaturated organic substrates. 5

5

5

5 2

5

5 2

2

One of the important high energy processes which has served to ad­ vance organometallic t r a n s i t i o n metal chemistry i s the metal vapor reaction (_1_-5_). This technique involves heating a metal in an evac­ uated reaction vessel u n t i l i t starts to vaporize and then condensing the vapor at low temperature (-100 -> -196°C) with an organic reagent. The low temperature matrix which i s formed i s sometimes studied d i r e c t l y by spectroscopic means. In other cases, the matrix i s allowed to warm and the metal vapor reaction products can be isolated on a preparative scale. Metal vapor reactions with organic sub­ strates often have provided new organometallic complexes, interme­ diates, and reaction pathways which were previously inaccessible v i a t r a d i t i o n a l solution reactions. The metal vapor method also has played an important role in the development of organometallic lanthanide chemistry (6-10). This high energy technique demonstrated that the lanthanide metals had a much greater range of organometallic chemistry than had been assumed previously. The metal vapor technique applied to lanthanides ident­ i f i e d reasonable new research goals which could subsequently be pursued by solution techniques. Not only the metal vapor reactions, 0097-6156/87/0333-0278$06.00/0 © 1987 American Chemical Society

Suslick; High-Energy Processes in Organometallic Chemistry ACS Symposium Series; American Chemical Society: Washington, DC, 1987.

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Highly Reactive Organosamarium Chemistry

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but also some of their high energy products have provided access to new areas of organolanthanide chemistry. In this chapter, the u t i l i ty of metal vapor chemistry in the organolanthanide f i e l d i s d i s cussed as well as the high r e a c t i v i t y achievable from soluble Sm(II) complexes, compounds which were f i r s t isolated by metal vapor techniques. Metal Vapor Reactions One major area of organolanthanide chemistry which was advanced by the metal vapor technique involved unsaturated hydrocarbons. Prior to 1975, unsaturated hydrocarbons were not seriously considered as viable substrates/ligands for the lanthanides (11). These soft base ligands were not expected to interact strongly with the l a n thanides, which t r a d i t i o n a l l y were viewed as highly i o n i c , hard acid species. The basis for that view was the limited r a d i a l extension of the 4f valence o r b i t a l s (12). The 4f o r b i t a l s are not nearly as s p a t i a l l y available for covalent metal ligand o r b i t a l overlap as the d valence o r b i t a l s are in t r a n s i t i o n metals. Since unsaturated hydrocarbons are very important substrates in organometallic chemi s t r y (1_3), their absence in organolanthanide chemistry severely limited the scope of the f i e l d . Metal vapor chemistry showed that the lanthanides had quite an extensive chemistry with unsaturated hydrocarbons. Some of the early surveys of metal vapor reactions with unsaturated hydrocarbons i n cluded some lanthanide metals and showed that r e a c t i v i t y was present for these metals (14-18). Subsequent synthetic studies in which the products were isolated and characterized led to some of the most unusual organolanthanide complexes currently known (19-28). Reactions (1)-(4) i l l u s t r a t e some of the unusual features of these complexes (9, J J H L l , — )

Ln + H C=CH-CH=CH 2

:

+ Ln(C H )

2

4

6

3

Ln + H C=C(CH )-C(CH )=CH -> L n ( C H ) 2

3

3

2

6

Ln + CH CH CECCH CH

^

L n

3

Ln + CH CH CECCH CH

+

L n ( C

3

3

3

2

2

2

2

( C

1 Q

H

)

2

2 6 10 3 H

6 iO

)

Nd,Sm,Er

(1)

La.Nd.Sm.Er

(2)

N

d

,

E

r

(

3

)

S

m

,

Y

b

(

4

)

In each case, the metal was vaporized at temperatures ranging from 500-1600 C depending on the specific lanthanide involved and the vapor was cocondensed with the unsaturated hydrocarbon at -196 C. The product was isolated on a preparative scale in an inert atmosphere glove box and the product formula was determined by complete elemental analysis. Yields varied depending on the specific metal/ ligand combination, but as much as 2-3 g of isolated product were obtained in some of the systems. The metal vapor r e a c t i o n products d i f f e r e d from t r a d i t i o n a l organolanthanide complexes in many ways. F i r s t , the observed s t o i chiometrics had low ligand to metal r a t i o s . For example, the y t t e r bium and samarium 3-hexyne products (Reaction 4) had formal ligand to metal r a t i o s of one, whereas most organolanthanides are commonly nine or ten coordinate (6-10). Second, the stoichiometries varied in an

Suslick; High-Energy Processes in Organometallic Chemistry ACS Symposium Series; American Chemical Society: Washington, DC, 1987.

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HIGH-ENERGY PROCESSES IN ORGANOMETALLIC CHEMISTRY

unusual manner depending on ligand and metal. For example, 2 , 3 - d i methyl substitution of the butadiene ligand changed the ligand to metal r a t i o from three (Reaction 1) to two (Reaction 2). In the 3-hexyne system, changing from neodymium and erbium to ytterbium and samarium changed the r a t i o from 1.5 (Reaction 3) to one (Reaction 4). T r a d i t i o n a l l y , the stoichiometries of organolanthanide complexes are invariant to minor substitutional changes on the ligand and are similar for metals of similar size (10). Third, in contrast to t r a d i t i o n a l organolanthanides, which have pale colors (11), the metal vapor products were intensely colored materials which displayed strong charge transfer absorptions in the near infrared and v i s i b l e regions. Fourth, the room temperature magnetic moments for these complexes were often outside the range of "free ion" values p r e v i ously reported for organolanthanide compounds (11,19). Consistent with t h i s , the NMR spectra of the La, Sm, and Lu products were broad and uninformative whereas these metals, when t r i v a l e n t , provide sharp i n t e r p r é t a b l e spectra. The lanthanum butadiene product displayed an EPR absorption (La i s 4f ) . F i n a l l y , the solution behavior of these complexes was unusual. For example, the 3-hexyne product, [ErC H ] , was dimeric in arenes, i . e . n=2 (e.g. 2^ 6 .lO 3^* in concentrated solution or in THF i t was highly associated with n>10. This i s just opposite the trend found for t r a d i t i o n a l organolanthanides which are more highly associated in arenes than in THF (29,30). Unfortunately, because these metal vaporization products oligomerized rather than c r y s t a l l i z e d in concentrated solution, these species were not s t r u c t u r a l l y characterized by X-ray d i f f r a c t i o n . Although the structures of these species were not determined, t h i s metal vapor chemistry c l e a r l y showed that unsaturated hydrocarbons were viable reagents for lanthanides. Furthermore, t h i s high energy technique showed that new regimes of organolanthanide complexes were accessible under the appropriate conditions. In addit i o n , attempts to understand the synthesis of the products in reactions 1-4 led to new metal vapor syntheses and new organolanthanide chemistry. Analysis of possible structures and reaction pathways in reactions 1-4 led to various model structures for these complexes (9,25). Some of these involved C-H activation of the substituents attached to the unsaturated carbon atoms. To test the v a l i d i t y of these models, two additional types of metal vapor reactions were examined. In one case, reactions with simpler unsubstituted hydrocarbons were examined. In another case, substrates i d e a l l y set up for oxidative addition of C-H to the metal center were examined. As described in the following paragraphs, both of these approaches expanded the horizons of organolanthanide chemistry. The simple hydrocarbon substrates included ethene, 1,2-propadiene, propene and cyclopropane (22). Their r e a c t i v i t y with Sm, Yb and Er was surveyed. In contrast to the reactions discussed above, lanthanide metal vapor reactions with these smaller hydrocarbons did not provide soluble products (with the exception of the erbium propene product, Er(C H^) ) . Information on reaction pathways had to be obtained primarily* by analyzing the products of hydrolysis of the metal vapor reaction product. The a n a l y t i c a l data on these small hydrocarbon lanthanide systems indicated that a variety of reactions were occurring. Evidence was Er

C

H

Suslick; High-Energy Processes in Organometallic Chemistry ACS Symposium Series; American Chemical Society: Washington, DC, 1987.

b

U

t

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Highly Reactive Organosamariwn Chemistry

observed for alkene insertion into Ln-C bonds, polymerization, C-C bond breaking, dehydrogenation, and oxidative addition of C-H. One study (22) on this topic concluded by saying that i t had "defined a set of conditions under which a variety of hydrocarbon activation r e a c t i o n s take place i n the presence of the l a n t h a n i d e m e t a l s . Obviously, the challenge in t h i s area i s to control t h i s r e a c t i v i t y so that i t can be used s e l e c t i v e l y . " These reactions defined new goals for organolanthanide solution chemistry, which was then in the process of being developed. High r e a c t i v i t y of the type found in these metal vapor reactions has been observable in solution and, by choosing the appropriate system, some s e l e c t i v i t y can be obtained. The most prominent example of t h i s i s the chemistry of the [(C Me ) L u Z ] systems (Z=CH , H; x=1,2) (31_) which are very active polymerization i n i t i a t o r s (32,33) and which are such powerful metalation reagents that they can activate C-H bonds in methane (3J*t 35). Two unsaturated hydrocarbon substrates containing acidic hydrogen were examined by metal vapor methods to deliberately probe C-H o x i ­ dative addition r e a c t i v i t y . Terminal alkynes react with Sm, Er and Yb to form alkynide hydride species, the type of product expected from oxidative addition, but a single c r y s t a l l i n e product was not isolated (23). The reaction of pentamethylcyclopentadiene, C Μβ,-Η, with samarium provided a clearer example of oxidative addition of C-H. In this case, evidence for the d i r e c t oxidative addition pro­ duct, the divalent complex [(C Me,.)SmH(THF) ] , was obtained (24). This species was too unstable for f u l l characterization but did pro­ vide the desired information on C-H a c t i v a t i o n . In addition, t h i s species l e d , v i a i t s decomposition, to a new complex, (CJ^e^)^" Sm(THF) , which has proven to be extremely important in organolan­ thanide chemistry. (C Me ) Sm(THF) was the f i r s t soluble organosamarium(II) complex. Due to the l a r g e r e d u c t i o n p o t e n t i a l of Sm(II), t h i s compound i s a high energy species in i t s own r i g h t and i t s chemistry i s discussed in a subsequent section. Also isolated from the Sm/C Me Η reaction was the unsolvated (C Me ) Sm (27). As discussed in the Sm(II) section, t h i s molecule has a rather unusual structure. Both of these samarium(II) complexes have considerably extended the scope of organolanthanide chemistry and both were a d i r e c t result of metal vapor studies. In addition to broadening organolanthanide chemistry by demon­ s t r a t i n g new r e a c t i v i t y patterns and providing new complexes, the lanthanide metal vapor studies have demonstrated new c a t a l y t i c a c t i ­ v i t y for these metals. In the course of characterizing the lanthan­ ide metal vapor 3-hexyne products, i t was discovered that these complexes had the capacity to i n i t i a t e c a t a l y t i c h y d r o g é n a t i o n of alkynes to alkenes and alkanes (20,2J[t24). A variety of lanthanide metal vapor products were found to generate c a t a l y t i c h y d r o g é n a t i o n systems including the products of lanthanide metal cocondensations with 1-hexyne, 2,3-dimethylbutadiene, (CH ) SiC=CSi(CH ) and P(C^H ) (26). Using 3-hexyne as a substrate, trie se c a t a l y t i c systems g e n e r a l l y gave high y i e l d s of c i s - 3 - h e x e n e ; many had >95% stereospecificity. Although c a t a l y t i c h y d r o g é n a t i o n of alkynes can be accomplished in many other ways, t h i s c a t a l y t i c system was s i g n i f i c a n t because i t was the f i r s t time an f element complex had been observed to c a t a l y t i c a l l y activate hydrogen in homogeneous s o l u t i o n . The result had 2

x

2

5

2

2

2

Suslick; High-Energy Processes in Organometallic Chemistry ACS Symposium Series; American Chemical Society: Washington, DC, 1987.

HIGH-ENERGY PROCESSES IN ORGANOMETALLIC CHEMISTRY

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additional importance because the metal hydride complexes presumably involved in the catalyses provided the f i r s t evidence for the e x i s tence of discrete molecular lanthanide hydrides. The existence of lanthanide hydride complexes subsequently was demonstrated c r y s t a l l o graphically ( 3 £ ) and f u l l y characterized lanthanide hydrides were shown to have c a t a l y t i c a c t i v i t y in h y d r o g é n a t i o n reactions (37). Subsequent studies of other organolanthanide hydride systems have i d e n t i f i e d complexes with very high l e v e l s of c a t a l y t i c h y d r o g é n a t i o n a c t i v i t y (38). Organosamarium(II) Chemistry Of the three r e a d i l y accessible divalent lanthanide ions, Eu(II), Yb(II), and Sm(II), samarium i s the most strongly reducing. A reduction potential of about -1.5V vs NHE i s generally assigned to the Sm(III)/ Sm(II) couple (39). Despite t h i s high r e a c t i v i t y , organosamarium(II) chemistry had not been examined because the known systems [(C H ) S m ( T H F ) ] (40) and [(CH C H ^ S m ] (41_) were i n s o l u ble. Thi ûm/C Me H metal vapor reaction changed t h i s situation and provided (C Me^SmCTHF) (24) and (C MeJgSm (27,42) as well as t h e i r C Me^Et analogs (27). These complexes are soluble species which have an extensive, high energy reducing chemistry. Structurally, (C Me ) Sm(THF) had the bent metallocene arrangement expected (43) for a dicyclopentadienyl complex with two additional ligands (_44) (Figure 1a). In contrast, (C Me^JSm, the f i r s t structurally-characterized d i r e c t f element analog of f e r r o cene, had an unusual structure (42) (Figure 1b). Steric and simple e l e c t r o s t a t i c arguments and even a molecular o r b i t a l analysis (45) predicted that (C Me^) Sm would be s t r u c t u r a l l y similar to (C Me ) Fe (46) (Figure 1c), I . e . , i t would have p a r a l l e l cyclopentadlenyl rings^. It did not. The ring centroid-Sm-ring centroid angle of 140.1 was very close to the 1 3 6 . 5 ° value observed in (C Me,.) Sm(THF) . (C Me ) Eu (47) and (C Me ) Yb (Haaland, Α . ; Andersen? R. Α . , personal communication, 1986) are isomorphous with (CpMeJpSm in the s o l i d state and the ytterbium complex i s also bent in tne gas phase (4_8). The o r i g i n and chemical consequences of t h i s bent s t r u c ­ ture presently are under investigation. The (C Me ) Sm(THF) metal vapor product provided the f i r s t opportunity tq> see i f SmClI) complexes ( μ = 3 . 5 - 3 . 8 U g ) could be char­ acterized by H NMR spectroscopy (24). Fortunately, the paramagne­ tism doesn't cause large s h i f t i n g and broadening of the resonances and hence samarium provides the only Ln(III)/Ln(II) couple in which both partners are NMR accessible. Once the existence and identity of (C Me ) Sm(THF) was known, a solution synthesis was developed from KC^Me^ and SmI TTHF) (44). This system i s the preferred preparative route and also provides another soluble organosamarium(II) complex, [(C Me ) S m ( T H F ) ( u - I ) ] , under appropriate conditions. This is another xample of how solution studies subsequently catch up to the research targets often i d e n t i f i e d f i r s t in metal vapor reactions. One of the best examples of the high r e a c t i v i t y achievable v i a organosamariumdl ) chemistry i s the reaction of (C Me ) Sm(THF) with CO (490. This compound reacts under a variety of conditions with CO to give complex mixtures of products. Under 90 psi of CO in THF, a c r y s t a l l o g r a p h i c a l l y characterizable product separates (Reaction 5 ) . 2

n

11

ç

2

2

?

2

2

2

2

2

2

Suslick; High-Energy Processes in Organometallic Chemistry ACS Symposium Series; American Chemical Society: Washington, DC, 1987.

17.

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Highly Reactive Organosamarium Chemistry

283

The remarkable dimeric product contains four Sm(III) centers and the equivalent of six CO molecules, i . e . , six CO molecules have been (C Me ) (THF)Sm0^ 5

5

^0

2

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\

/

Τ

5

5

2

/ / 4(C,Me ) Sm(THF) + 6C0 c

5

5

0 2

0

2

•>

0

yC φ / \ (C Me ) Sm^ C 0 5

5

(5)

2

0Sm(THF)(C Me ) 5

5

2

reduced by four electrons as they are homologated into two ketenecarboxylate u n i t s . The most interesting feature of this CO reduction i s that com­ plete cleavage of one CO t r i p l e bond must have occurred to give the c e n t r a l , oxygen-free carbon of the C=C-C skeleton. Although CO cleavage i s thought to occur in heterogeneous Fischer-Tropsch systems (50-55), this r a r e l y occurs in homogeneous systems. Complete CO cleavage has not been observed in the extensive studies of CO reduc­ tion by molecular early t r a n s i t i o n metal (56,57) actinide (58), and lanthanide (59) hydride systems. The l i t e r a t u r e system most closely related to equation 5 i s the two electron reduction of two CO molecules by a l k a l i metals which i s reported to form an insoluble alkyne diolate (Equation 6) (60). The relationship between reactions 5 and 6 can be seen by comparing 2K + 2C0 + 2[K0CEC0K]

(6)

K0CC0K with the atom connectivity on the right hand (or l e f t hand) side of the ketenecarboxylate dimer, Sm0(C0)CC0Sm. Both the Κ and Sm systems contain M0CC0M units involving two electron reduction of two CO molecules. The samarium system, a two electron/three CO system, has an extra CO formally "inserted" between a C and 0 bond. The i n s o l u b i l i t y of the ΚΟΟΞΟΟΚ product may be responsible for the lack of further homologation in this system compared to the samarium system. Hence, (C M e ^ S m i T H F ) ^ although strongly reducing l i k e the a l k a l i metals, i s differentiated from those reducing agents by i t s solubility. The C^Me^ ligands provide s o l u b i l i t y to the reducing agent as w e l l as t o intermediate r e d u c t i o n products and allow (C Me ) Sm(THF) to accomplish more than i s possible with the a l k a l i metals. The r e a c t i v i t y of (C Me^JSirKTHF^ with CO can also be compared with that of (C Me ) T i . Botn organometallic reagents are soluble, strongly reducing complexes of oxophilic metals. As shown in reac­ tion 7, decamethyltitanocene forms a carbonyl complex rather than 2

2

2

Suslick; High-Energy Processes in Organometallic Chemistry ACS Symposium Series; American Chemical Society: Washington, DC, 1987.

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HIGH-ENERGY PROCESSES IN ORGANOMETALLIC CHEMISTRY

reducing the CO (61,62). Since the Uf valence orbitals of Sm(II) are not as suitable for carbonyl complex formation as those of T i ( I I ) , t h i s i s less l i k e l y for samarium and reduction occurs. ( C M e ) T i + 2C0 5

(C Me ) Ti(CO)

2

5

5

2

(7)

2

C o n s i d e r i n g the comparisons above and the f a c t that n e i t h e r (C Me ) Yb(RpO) (63,64) nor (C Me ) Eu(THF) react with CO, (C_Me^) Sm(THF) appears to be a unique reducing agent in the p e r i odic t a b l e . The combination of strong reducing power, o x o p h i l i c i t y , s o l u b i l i t y , and lack of d valence o r b i t a l s i s not duplicated by any other reducing agent presently a v a i l a b l e . (C^Me^) Sm(THF) also shows high r e a c t i v i t y in i t s reactions with C H CECC H and C H N=NC H and the subsequent reactions of these —oducts with CO. The Cp^H_CECC H_ r e a c t i o n (65), which forms 6 5 6 5 [(C Me ) Sm] C (C^H ) 8;- may have a p a r a l l e l in a l k a l i 0 5'2*'" 2 '2 '6 5 2 (Equation * metal chemistry, except that in the heterogeneous a l k a l i metal systems, polymerization or dimerization of the intermediate r a d i c a l 5

2

2

2

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5

2

2

6

2

fi

fi

fi

r

c

c

IJ 0

0

V2

VV

(C Me ) Sm(THF) 5

5

2

c

+ CgH CECCgH

2

5

2

5

5