11. Palladium 1993

Coordination Chemistry Reviews 144 (1995)

ELSEVIER

11.

Peter

409-429

Palladium

1993

K. Byers

CONTENTS INTRODUCTION .................................................................................................... 409 11.l PALLADIUM(IV) ............................................................................................ 409 11.2 PALLADIUM(I1) ............................................................................................. 410 11.2.1 Complexes with phosphine donor ligands ................................. 410 11.2.2 Complexes with nitrogen donor ligands .................................... 417 11.2.3 Cyclometallation complexes ......................................................420 Complexes with sulfur donor ligands ....................................... 422 11.2.4 Complexes with mixed donor ligands ....................................... 423 11.2.5 11.3 PALLADIUM(I) .............................................................................................. 425 11.4 PALLADIUM(O) .............................................................................................. 426 REFERENCES .......................................................................................................... 427

INTRODUCTION

The coordination chemistry of palladium reported during the year 1993 has been reviewed. Although this account does not intend or claim to be comprehensive, examples have been selected to represent important features. Only the primary journals are covered and were searched for both palladium (and related) as a keyword and being present in the title. The review covers the chemistry of palladium in its 0 + +4 oxidation states, but does not include the catalytic activity of palladium complexes or complexes containing only Pd-C bonds. Classification of the complexes is according to the oxidation state and donor atom. For complexes containing mixed donor sets the priority ordering P>N>S applies, and neutral donors have priority over charged donor atoms; mixed donor didentate ligands are treated separately. 11.1

PALJADIUM(IV)

The new palladium(W)

complex

(1) has been prepared by oxidative

addition of

p-nitrobenzyl bromide to the corresponding parent di-organ0 species. In solution, benzyl group migration to the aromatic site slowly occurs with complete regioselectivity, and with a concomitant decrease in the palladium oxidation state [ 11. OOIO-8545/95/$09.500 1995 Elsevier Science S.A. All rights nxerved SXN OOlO-8545(95)01205-5

410

P.K. Byers/Coordin&m

Palladium(IV)

complexes

subjected to Electrospray

Chemistry Reviews 146 (1995) 409-429

containing

Mass Spectrometry.

ligands such as those displayed

in (2) have been

In the majority of cases, the intact ion was observed

as the base peak at low ion source energies. At higher source energies the palladium(IV) compounds all underwent facile reductive elimination of two methyl groups, as expected [2].

11.2

PALLADIUM(IIJ

11.2.1

Complexes withphosphine

Reaction of [PdX2(PR3)2] EBtt$Itt]

donor ligands

(X = Cl, I; PR3 = PPh3, PMePh2, PMe2Ph) with the nido-[7-

CE=Se, Te) anions has been reported [3]. In thf at ambient temperature twelve vertex [2,2-

(PR3)2-cZoso-2,1-PdEBl~l0]

(3) is obtained, whilst in refluxing toluene reaction produces only

[2-X-2-(PPh3)-cZoso-2,1-PdTeBlgHg(PPh3)]

(4). Further reaction of (4) (X = I) with HgII salts

affords [2-X-2-(PPh3)-cZoso-2,1-PdTeBt&(PPh3)]

(X = Cl, Br, CN, SCN or 02CMe) complexes

(4). The solid state structure of (3; PR3 = PMe2Ph) and (4; X = 02CMe) were determined X-ray diffraction

(H20)-2-(PPh3)-cZoso-2,l-PdTeBtoHg(PPh3)][BF4] determined

using

methods [4]. Further, (4; X = I) when treated with AgBF4 in toluene gave [2(S), whose solid state structure has been

by single crystal X-ray diffraction.

The Hz0 molecule of (5) can be replaced by a

variety of ligands to produce cationic complexes

[2-L-2-(PR3)-closo-2,1-PdTeB$-I9(PPh3)l[BF4l

(L = e.g. CO, CNBu’, NCMe, OC4H8. SC4Hg) (5). In the case of (5; L = CO) the solid state structure of the molecule has been determined by X-ray crystallography In a related report, [PdClz(PMe2Ph)2] dianions to produce the bis(phosphine)palladium

reacted with the nido-[7,8-E2BgHg]2diheteroboranes

(6) were obtained, and their solid structures subsequently

t51.

[4]. (E = As, Sb)

(6). Crystals of the complexes

determined

by X-ray diffraction

studies

P.K. Byers/Coordination

Chemistry Reviews 146 (1995) 409-429

w+

(4)

(3)

. = B-H

. =B-H E=As,Sb

PhMep P The preparation has been reported, derivatives

/‘“\

PMe ,Ph

of [Pd(p-Br)2&][NBu&

and these complexes

(6)

and [PdR2(NCMe)21 (R = p-MeCeH602CH2)

have subsequently

of general formula [PdBrR2L][NBu4]

been used to prepare

convenient procedure for the synthesis of the dinuclear methylpalladium(I1) CI)(PR3)2]

(PR3 = PEt3, PBu3, PMezPh,

complexes

PMePh2 and PPh3) (7) has appeared.

involves reaction of [PdCl&-C1)2(PR3)2]

with SnMe4 in benzene at room temperature.

(7) react with pyrazoles

of base to give the pyrazolato-bridged

in the presence

Both (7) and (8) adopt a trans-configuration

u3P\A jMe M ,/‘“\,

a series of

and [PdRzLT] (L = e.g. PR3, 4-Mepy)

[PdzMeZ(pThe method The dimers

compounds

[7].

6

R3P

1

/N-N\

Me /

‘Y PR3

PR3

(7)

(8)

[7]. A

(8).

P.K. Byers/Coordination

412

Thermolysis

Chemisrv

Reviews

of the dimer [Pd$12( ~-tBu2P(CH2)sPtBu2)2]

X = Cl) containing the P,C,P’-tridentate

protonated

with [HNMe3][BF4]

complex is readily displaced by coordinating [Pd(H20)L][BPb]

409-429

readily affords the complex (9;

ligand (L). Metathesis of this complex with MeLi or LiAELt

produces the analogous methyl and hydride complexes can be selectively

146 (1995)

solvents.

(9; X = H, Me), and complex (9; X = Me) to yield [Pd(BFd)L];

the BF4 ligand in the

The solid state structures of [PdMe(L)] and

were determined using X-ray diffraction methods [8].

Pd-P PBu t2 I

But2

x

X=Cl,H,Me (9)

Treatment with base of n-allylpalladium 2-position

complexes bearing a methoxymethoxy

has been reported to give the corresponding

contrast to the formation of 2-hydroxy-substituted

oxodimethylenemethane

group at the

complex (10) in

tt-alkyl complexes (11) via acidic hydrolysis [9].

0

(10)

(11)

A series of cyclopentadienyl

complexes

of the type [Pd(tl5-C5H5)(CH2Z)(PPh3)]

COPh, COMe, COCH2C1, CN, SMe) (12) have been prepared and characterised. all react with dry HCl to give [Pd(q%sHs)Cl(PPh3)] [PdC12(PPh3)]2

[ 101. The palladium

triflate complexes

and finally dimeric

[Pd(OTF)z(P-P)]

(P-P = dppm, dppe,

characterised

(13); the solid state structure of (13;

using X-ray diffraction methods [ 111. Cyclopentadienylpalladium(I1)

complexes have also been obtained by with [Pd2Ph2(FL-OH)2L2]

The complexes

as an intermediate,

dppp) react with Tl(CsHs) to produce the cationic complexes P-P = dppe) was determined

(Z =

direct

reaction of cyclopentadiene

(L = PPh3, PCy3). The complex

by single crystal X-ray diffraction [12].

or methylcyclopentadiene

(14; L = PPh3) was structurally

P.K. Byers/Coordination

Chemistry

I

square planar cis-alkyl(carbony1)

spectroscopy complexes

(14)

[13]. The insertion

was

(15) has been described.

prepared

((S,S)-BDPP

by halide

of CO, and was identified

of isocyanides

affords new (metallovinyl)ketenimine

transition metal complex containing a chelating

[Pd(Me)(CO)((S,S)-BDPP]][BF4]

(2S,4S)-2,4_bis(diphenylphosphino)pentane] in the presence

413

PhAPd\L

(13)

has been reported. The complex,

[PdMeCl((S,S)-BDPP)]

409-429

I

p/pd\p

PPh 3

(12)

Thejirst

146 (1995)

I

ZH 2CApd\

diphosphine

Reviews

abstraction

=

from

using high pressure

NMR

into the M-C bond of (o-allenyl)palladium(II)

When the R groups on the allenyl ligand are small, insertion compounds

rrans-[PdX[

C(CRR’)(CH=C=NR”))

(PPh3)2]

(16) 1141.

-

The complex PhCOCH2Cl palladium.

Ph3P

[Pd(CH2COPh)(Cl)(PPh3)2]

to [Pd(PPh&],

has been prepared

and X-ray analysis has revealed

X

by oxidative

addition of

the enolate to be C-bonded

to

The complex inserts a tBuNC molecule into the Pd-C bond to form trans-[Pd(-C(NH-

tBu)=CH-C(O)Ph)Cl(PPh3)2]

(17), and reacts with Ag[CF$03]

cis-[Pd2(lt-CH2COPh)2(PPh3)41*2[CF3S031 were obtained using crystallographic

in acetonitrile

to give the dimer

(18). The solid state structure of both (17) and (18)

methods [ 151. Ph

Ph3P\

/ Pd

Ph 3 Pip”\

07)

/\ c\ Hz

//O

c Ph (18)

PPh 3

414

P. K. Byers/Coordinution

Treatment of the compounds with excess

norbornadiene,

[Pd(Ar)I(PPhg)Z] (Ar = Ph, p-MeO-Ph, p-Me-Ph, m-MeO-Ph)

or reaction

reported to give the complexes

Chemistry Reviews 146 (1995) 409-429

of [Pd(PPh3)4]

[Pd(QHSAr)I(PPh3)2]

with ArI and norbornadiene

[16]. Reaction of truns-[Pd(Me)I(PPh&l

with 2,6-xylyl isocyanide in a 1: 1 molar ratio led to a spontaneous

insertion of isocyanides

the tris-imino product (19) which was structurally characterised by X-ray crystallography H ‘BuNC, ‘\

i

/

of

/N\

H

Al = p-C6H4X X=H, Me, MeO, Cl-, Br(20)

(19)

dinuclear

p-amid0

[(Pd(C&)(PPh3)]2(p-OH)(p-NIR&~X-p)l have been prepared.

,785

Apd\CNtB” Ar

NR

4

series

lAr

,N\

/‘“\ CEFS NR

Two

\

to give

[17].

-CMe

/‘” Ph 3P

has been

palladium(I1)

complexes

of

the

and [(Pd(C&)(‘BuNC)(lt-NHC&tX-p)]z]

form (20)

The solid state structure of (20; X = H) has been established

using X-ray

diffraction [ 181. Reaction of [Pd(PPh3)4] with 2,6-bis(chloromethyl)pyridine two oxidative addition products: Ca,Wbridging

dinuclear (21) and Cafl,Ca

palladium(I1) compounds 1191.

;ga


I

I

PPh 3

PPh 3

PhN

(21) The reaction LiPhN(Y)NPh monodentate

-bridging tetranuclear

:\:;ph

clq&cl Cl-Pd

in toluene at 1OO’C afforded

(22)

of [PdX2L2] (X = Cl, Br, mesityl;

(Y = N, C(Ph)] (22), didentate

JAN

has been studied.

(23 )

L = PEt3, PMezPh,

PPh3, PEt3) with

For Y = N, the triazendio

(23) and bridging (24) complexes,

ligand forms

whilst for Y = C(Ph) complexes

containing the bridging amidino group (25) were obtained [20]. Resolution of the chiral didentate bis(phosphine) crystallisation

of a pair of diastereomeric

an orthometallated

ligand (26) has been achieved by fractional

palhadium(II) complexes containing the racemic ligand and

(S)-dimethyl(l-phenylethyl)amine

(27). The absolute configuration

enantiomer of the ligand was assigned by a X-ray crystal structure determination

of the (S)-

of (R,S)-(27) 1211.

P.K. Ryers/Coordination

415

Chemistry Reviews 146 (1995) 409-429

Ph (25 )

(24 ) Me?

Ph

Me

+ (26)

dimethylpalladium(I1)

The dimethylpalladium

species

crystallography

complex

complexes,

also reacted

rrans-[PdMe(OCOOR)L2]

of the dimeric

carbamate complexes

R, R’= H, alkyl, phenyl) have been reported.

from the corresponding compounds

I

(w-(27

A series of mm- and cis-methylpalladium = tertiary phosphine;

Ph,

[PdMe(OCONRR’)L2]

The complexes

(L

were prepared

a primary or secondary amine and CO2.

with alcohols

and CO2 to afford alkyl carbonate

(R = Me, SBu; L = PMe3, PPh3). The solid state structure

[Pd2Me2(It-OCONEt2)2(PMe3)2]

(28) was determined

by X-ray

[22]. Et2 N 0

/+-0 “;<

0

\

I Pd I\

Pd

PMe 3

Me

I\ Me,P

Me (28 1

Treatment

of [PdC12(dppe)] with PhSH in the presence of BtqN, or oxidative addition of

PhzSe2 to [Pd(QH4)(dppe)] report, complexes synthesised

gave the complexes

[Pd(EPh)2(dppe)]

of the general formula cis-[M(SCgFg)2L2]

from cis-[MC12L2] and T&SC&)

The p-hydroxo-complexes from reaction of NBqOH

(E = S, Se) [23]. In a similar

(L2 = dppm, dppe, 2PPh3) were

[24].

[ (PdR(PPh$(F-OH))21

with the corresponding

bridged species with pyrazole or 3,5dimethylpyrazole

(R = C6F5, C&15) have been prepared

l,t-chloro compounds.

Reaction of the hydroxo

afforded the new compounds

(29) and (30),

P.K. B.yers/Coordination

416

whilst reaction with oxalic &Ox)

Chemistry Reviews 146 (1995) 409-429

and acetic (HOAc) acids gave dinuclear [(PdR(PPh$)z(p-Ox)1

and [(Pd(C6F5)(PPh3)(~-oAc)l21 WI.

Ph,P

Ph JP

CsFs \

/N-N\

/

C,F5 1

/N-N\

/

/Pd\,lPd\

PPh,

C,F5

(29)

(30)

The solid states of the complexes monothioacetylacetonate) the new compounds phosphinoethane)

[PdMe@dik)(PPhg)]

(31) have been determined [Pd(H2-dmsucc-S,S’)(L-L)]

(L-L = dppe,

into the Pd-H bond,

(Me2NCS2)(PEt3)]

1-diphenylarsino-2-diphenyl-

with LiHBEt3 at low temperature

e.g. reaction

[28]. In a related

with CHz=CHCN

report,

affords in situ the

(33). This species readily inserts alkenes and preparation

(X = Cl, Br) from hydrogenolysis

gives

[Pd(CH(CN)CH3}-

of the hydride

complexes

of trans-[PdX(COPh)(PPh3)2]

x=o,s

(32)

E=P,As

trunk-

was described

WI.

(31)

or

1261, and

(32) have been reported [27].

Reaction of [Pd(Me2NC$)(Cl)(PEt3)]

[PdH(X)(PPh3)2]

(P-dik = acetylacetonate

by single crystal X-ray diffraction

unstable hydrido species [Pd(H)(Me2NCS2)(PEt$] alkynes

PPh 3

H

(33 )

P.K. Byers/Coordination

Treatment of the diphosphine Na2[PdCl4] gave the macrocyclic

Chemistry Reviews 146 (1995) 409-429

417

ligand bis[4- (2-(diphenylphosphino)ethyl)phenyl]ether

compound

(34), apparently

process [30]. Reaction of the anions [Ph2P(Y)PPh2]-

from a spontaneous

with

self assembly

(Y = CH, N) with [PdX2L2] (X = Cl, Br; L =

PPh3, PMezPh, PEt3) complexes has been reported to give a variety of products. Thus, with Y = CH derivatives

[PdCl(Ph2PCHPPh$L]

and [Pd(Ph2PNPPh2)2] the corresponding potentially

cationic complexes

tridentate

afford complexes

were obtained, whilst with Y = N, [PdX(Ph2PNPPh2)(PEt3)]

were isolated. Subsequent treatment of these complexes containing

ligand HC(PPh2)3 coordinates

with HBF4 yielded

the neutral ligand Ph2P(YH)PPh2 to palladium(B)

of the form [PdXX’(t$-(PPh&CH]]

[31]. The

via two of its PPh2 sites to

(X = X’= Cl, Br, C&F5: X = Cl, x’ = CgF5)

t321.

I\

(H ,C=HC)Ph

2P

,I,

,PPh

,(CH=CH

*)

/‘“\,/‘“\,

(35 ) The unexpected product (35) was obtained upon oxidative addition of 12 to the palladium(I) complex

[(Ph2PCH2CH2)&-q3-Ph2PCH$ZH2)Pd]2[BF4]2,

established low-ligated

by X-ray crystallography palladium(O)

[33]. The mechanism

and its solid state structure

was

of oxidative addition of arylhalides to

species, PdOL2 (L = e.g. PPh3). formed by reduction

of their divalent

precursors has been reported 1341. 11.2.2

Complexes with nitrogen donor ligands

Rapid successive,

stoichiometric

the Pd-C bonds of [PdMeClL]

insertions of CO and norbomadiene

(R’CH=CHR”) into

(36) leading to stable products of the type [PdC(O)CH(R’)CH(R”)-

C(O)Me] (37) have been reported [35]. In a similar report, insertion of CO and norbomene Pd-C bond of [Pd[C(O)Me)I(bpy)]

has been described [36].

(361

(37 )

Reaction of [PdC12(bpy)] with LiOMe under a CO atmosphere compound

[Pd(C02Me)2(bpy)].

[Pd(OMeh(bpy)], [Pd(QF5&2)]+

Evidence

for the apparent

was obtained in situ by NMR spectroscopy complexes

into the

gave the bis(carbomethoxy)

precursor

to this complex,

i.e.

[37]. The reactivity of cis- and tray

towards dienes has been reported. The c&complex

[Pd(C&F5)(bpy)]+

P.K. Byers/Coordinarion

418

reacts with dienes [Pd(C&)L2]+,

Chemisrty Reviews 146 (IY95) 409-429

to afford (CgFg-allyl)palladium

derivatives,

e.g. (38). However,

trans-

under similar conditions, failed to give analogous products [38].

N = 2,2’-bipyridine N

Ws Me

(3’3)

A series of (r13-C3Hg)palladium(II) didentate,

bis(chiral-pyrazolyl)

second series of (rlx-allyl)paIladium(II) (40), were investigated dimers

with

complexes,

[Pd(t13-C3Hs)(L2)][PF6],

ligands, e.g. (39), have been prepared complexes containing

using IH NMR spectroscopy

di-2-pyridylsulfide

(dps)

[Pd(~3-allyl)(dps)][Pd(r13-allyl)C12]

containing

[39]. In a related article, a

chiral, bis-(oxazoline)

ligands, e.g.

[40]. Reaction of ($-allyl)palladium

afforded

the

series

of

ionic

in which the dps ligand adopted an N,N’-binding

solid state structure of the complex with ally1 = 2-propenyl was determined

chloride

compounds mode. The

using single crystal X-

ray diffraction [41].

(39 ) Oxidative afforded

(40 )

addition of 2-(2-bromophenyl)ethanol

+ ) ) PI

the arylpalladium(I1)

subject of an X-ray diffraction [Pd( C6H4(CH2CH20H):2) [Pd{C&I&H$TH20))(tmen)]

to [Pd(dba)z]

complex

study.

in the presence

[PdBr[ C~HJ(CH~CH~OH)-~)(~~~~)],

Halide abstraction

(tmen)]N03

(41), which was deprotonated

/N

OJd\ H

(41)

N

= tmen

N

N

which was the

using AgN03 gave the ionic complex

[42].

0

of tmen

using KOMe to yield

P.K. Byers/Coordinarion

NC

CN

NC

CN

419

Chemistry Reviews 146 (1995) 409-429

N\

/

NC

NC

= en

N

(Y3)

(42 )

The neutral, planar complex [PdL2] (42) has been described, along with the crystal structure of its 1,2_dimethoxyethane

adduct [43]. Treatment of 1,2-bis(4-pyridyl)ethane

in a 1:l molar ratio gave the macrocyclic, confirmed by X-ray crystallography The formation

complex (43), the structure of which was

[44].

of palladium(H)

been studied by microcalorimetry

dipalladium

with [Pd(en)][N03]2

complexes

of [18]aneNg,

[2l]aneN7

and tH and 13C NMR spectroscopy.

and [24]aneNg has

Crystals of the dinuclear

Pd2+ complex of [24]aneNg were obtained, and were the subject of an Xray diffraction The synthesis

and structural

characterisation

of [PdL][PF&

reported [46]. The preparation of (terpyridine)palladium(II)

containing

study [45].

cation (44) has been

complexes of phenylcyanamide

anion

ligands, e.g. (45), has been reported, and for (45) the solid state structure has been determined X-ray crystallography

by

[47].

(44 ) The palladium(H)

complex (46) has been reported.

The NMR spectral data indicated that

the complex possessed a weak Pd----Fe dative bond, and this was supported by an X-ray analysis of the complex [48].

420

P.K. &ws/Coordination

Chemistry

Reviews146(1995)409-429

(46 )

Treatment of [PdMe(Cl)(cod)] with the ligands (47) afforded compounds of the type [PdMe(Cl)(N,N’-47)]+, e.g. (48), while ionic compounds of the form [PdMe(N,N’,N”-47)]+, e.g. (49), were obtained by halide abstraction of the chlorides using silver(I) salts [49]. The tridentate and didentate coordination behaviour of N-(2_hydroxyethyl)- 1,2-ethanediamine, L, with PdX2 (X = Cl, Br), and their N,N’,O to N,N’ isomerisation behaviour, has been studied using a variety of techniques. One of the isomers, [PdC12(L)J, has been characterised by single crystal X-ray analysis where the palladium was shown to possess the N2C12donor set [50]. The synthesis and solid state structures of [PdClz(L)] and the palladium(I1) dimer [(L)ClzPdPdC12(L)12+(L = H[9]aneN3; 50) have been reported [51]. H N’

+ Hfi

IN\ H

H

(50) I 12.3

Cyclometallationcomplexes

The first examples of optically active, cyclopalladated primary amines were reported. Thus, reaction of [PdClz( NI&CH(Me)Ph)2] with AgC104, followed by addition of neutral ligands (L2 =

P.K. Byers/Coordination

Chemistry

2py, cod, bpy) or NaBr led to the isolation [(Pd{C6H4[CH(Me)NH2-2])(~-Br))2]

Reviews

of [Pd(CgH4[CH(Me)NH2-2]](L2)]C104

respectively.

Some of the complexes

optically pure by employing (R)-(+)- or (S)-(-)-a-methylbenzylamine In a separate report, the first orthopalladation Treatment [Pd(OAc)2]3

421

146 (1995) 409-429

or

were obtained

as the starting material [52].

of unsubstituted benzylamine was described [53].

[ 1,4-(CyN=CH)2CgHq]

of N,N-terephthalylidenebis(cyclohexylamine) dimer (51), possessing

gave the monocyclopalladated

with

a free formyl group on each

phenyl ring. Complex (51; X = 02CMe) was reacted with halide ions to form (51; X = Cl, Br, I), and (51; X = Cl, Br, I) with Tl(acac) to give (52) or with tertiary phosphines to give (53) [54].

(51) Cyclometallation

(52) of N-benzyl

[Pd(OAc)2]3 has been investigated. aromatic

ring is formed

(53 )

and N-(phenylethyl)-ol-benzoylbenzylideneamines

A five membered endo-metallocycle

in all cases.

The solid state structure

[Pd(Cd_I4(Cd_15C=O)C=NCH(Me)CgHg)(O=SMe2)Cl] of new terdentate

C,N,N’-bound

with

involving the less activated of one of the derivatives

has been established

aryl, benzyl and alkyl organopalladium

[55]. The synthesis compounds

has been

reported, e.g. (54). By attention to ligand design, palladation can be directed towards sp2 and sp3 C-H activation and towards 5-membered or 6-membered ring formation [56]. The

reaction

of

[Pd(OAc)2]3

C6RmH5-mCH=N(CH2)pC6R’nHS_n macrocycles

from C(aromatic)-H

and

has been studied. and C(aliphatic)-H

C(aromatic)-Cl

bipyridine),

imines

(55), has been described.

The deprotonated

X

general

formula

and 6-membered

endo-

were obtained. The

complexes formed by oxidative addition of

bonds [57]. The preparation of cyclometallated

atoms and a carbon of the tbutyl group [58].

of

activation, respectively,

account also reported the formation of cyclopalladated o&o

the

Five-membered

[PdLCl] @IL = 6-Butyl-2,2’-

bipyridine is tridentate through the two N

422

P.K. Byers/Coordination

Chemists

Reviews 146 (1995) 409-429

R

(56)

Ph2

lP\

CY 1

.N_

R

CY (58)

In two related reports,

treatment

MeOC&C(H)=N-2’,4’,6’-Me$&; acetate gave the corresponding into the analogous

of Schiff bases (e.g. 4-MeCeHdC(H)=NCy;

2,4-RzC&I$(H)=NCy cyclometallated

halo-bridged

acetate-bridged

11.2.4

to give mononuclear, e.g. (57), and dinuclear,

[59,60].

Complexes with sulfur donor ligands

Treatment of &[Pd(SZC202)2] afforded the compound

with 2-methylpyridinium

(HC&I7N)2[Pd(S$Z202)2]

(‘S2c’ = 1,3-imidazolidinyl-N,N’-bis(2-benzenethiolate) synthesis

complexes which could be converted

species upon reaction with NaX, e.g. (56). These dimers were

subsequently reacted with a variety of bis(phosphiies) e.g. (58), complexes

3-Me-4-

(R=Me, OMe)], with palladium(II)

from [PdC12(cod)],

hydrochloride

[61]. The palladium(I1) complex [Pd(‘S2C’)]2 (59) has been prepared

1,2-ethanediamine-N,N’-bis(2-benzenethiolate)

Reaction of (59) with pyridine gave [Pd(py)(‘$C’)]

(59 )

in aqueous solution

(60) [62].

(60 )

in a one pot

and CH(OEt)x.

P.K. Byen/Coordination

11.2.5

423

Complexes with mixed donor Iignnds

The neutral dimer complexes containing

the bridging

containing

[SPPh$

[SPPh2]- as a P,S-chelate

[ (Pd(p-SPPh2)(C&)(PPh3))2] diffraction

Chemistry Reviews 146 (I 995) 409-429

[(Pd(p-SPPh2)(C&,)(PR3)]2] ligand, and cationic

(61) (PR3 = PPh3, PPh2Et)

complexes

[Pd(SPPh2)(PPh3)2]+

have been reported. The crystal structures of two of these,

and [Pd(SPPh2)(PPh3)2]C104,

have been established

methods [63]. The thioyl and selenoyl compounds

as chelating didentate ligands, and form complexes

PhzPN(Ph)PPhz=E

state structure of [PdC12[~h2PCH2CH$S(O)Me)]

using X-ray

(E = S, Se) act

[PdClz(L)] containing the Clz(P-S) and C12(P-

Se) donor set [64]. The synthesis of [PdCl2(kPh2ECH2CH$S(O)Me}]

(E = As, P) and the solid

have been described [65].

Ph, Ph3P\pd

/P

Ph 3 P’

‘S

I I

1 +

(621

(61) Neutral and cationic allyl-palladium(R) [Ph2P(CH2)&02]-

(62)

complexes

(n = 1 to 3) or Ph2P(CH2)&02R

For the neutral allyl-palladium

containing

the P,O-didentate

ligands

(n = 1 to 3; R = Me, Et) have been reported.

complexes containing the ligands [PhZP(CH2)aC02]-

(n = 1,2) the

solid state structures were established using X-ray diffraction methods [66]. Reaction of the sodium phosphinopyrazolonate chelate complexes crystallographically

(63) with [Pd(o-CeH4CH2NMe2)(p-C1)]2

(64) and (65). respectively.

The molecular

and [Pd(acac)2]

yields the

structure of (65) was determined

[67]. Optical resolution of the asymmetric chelate (5)[Ph2ECH2-CH$S(O)Me]

(E = As, P) via fractional crystallisation containing ortho-metallated

of a pair of diastereomeric

(S)-( l-(dimethylamine)ethyl]naphthalene

(63 )

(64 )

The preparation

of a new ferrocenylaminophosphine

palladium(R)

complex cations

has been reported [68].

(65 )

ligand (66) has appeared along with

the synthesis and solid state structure of its palladium dichloride complex [69]. The preparation of the valine-derived ]711.

chiral (L)P,iV-didentate

ligand (67) and its PdC12 complex has been reported

424

Chemisry Reviews I46 (1995) 409-429

P.K. Byers/Cmrdination

(66 1

(67 )

(68) Treatment of [Pd(n3-CH$Z(Me)CH2) new compound cis-[Pd(tBuNC)z(Ph2Ppy)Cl2] is monodentate

through phosphorus

(PhzPpy)Cl]

with cis-[Pd(tBuNC)$12]

affords the

in which the potentially didentate PJV-donor ligand

only [71]. A series of new P,N-didentate

ligands capable of

truns chelation have been prepared. The ligands o-Ph2PC&CH2O(CH&C$ktN-2 (68), when treated with Na[PdQ] complexes

When n = 1, cis complexes

[PdC12(o-Ph2PC6H4CH2O(CH2),CgHqN-2)].

formed, but with longer bridges (n = 2.3) rruns-complexes

has been reported [73]. A series of methionine

([9]aneNS2 = 1,4-dithia-

complexes

Cl, Br, I; L = D-, L- or DL-methionine; dmp = 2,6-dimethyl-4H-pyran-4-one) reaction of PdX2 with methionine L)]*dmp was determined (69)

has

been

[PdXzL]*dmp

(X =

have been prepared by

in the presence of dmp. The solid state structure of [PdIz(DL-

using X-ray crystallography

described

were

were the main products [72].

The solid state structure of the complex [Pd([9]aneNS2)2][BF&, 7-azacyclononane)

(n = 1 to 3),

or [PdC12(PhCN)2] in an equimolar ratio gave mainly the 1:l

[75].

[PhSNC(MeC6H4)N=NC(MeC6H4)NSPh]

[74]. The synthesis and crystal structure of

Treatment in toluene

of produces

[Pd(PPh3)4]

with

trans-

(70), in which the ligand is

bonded to palladium in an NSJ’,S-tridentate fashion [76].

(70 ) Ar=4-Me&H,

(69 ) A series of ($-allyl)paUadium(II)

derivatives of chiral N,O-didentate

synthesised to assess their potential as model intermediates

ligands (71) have been

for regio- and stereo-controlled

catalytic

PK. Byers/Coordinntion

425

Chemistry Reviews 146 (1995) 409-429

allylic alkylation and substitution reactions. Crystals of the complex [Pd(r13-cyclohexenyl)[A’-(amethylbenzyl)salicylaldimine)] crystallography

were obtained

as a single

isomer

and subjected

[77]. Reaction of the ligand N-(2-pyridyl)-3-phenyl-2-propene

to X-ray

amide (N-O) (72)

with PdCl:! gave [PClz(N-0)2], in which only the pyridyl nitrogen was coordinated [78].

R’

R20H RQq9

0

oz

q

0

R3 (72 )

(71)

PALLADIUM(I)

11.3

Redox condensation

of [Pdz(dba)g] with [PdClz(PhCN)2]

(R = Me, Ph) gave the dinuclear complexes 3tP NMR spectroscopy, [79]. Electrolysis

and confirmed

of the complexes

in the presence of RN[P(OPh)2]2

(73). The structures have been deduced from tH and

by single crystal X-ray diffraction

[Pd(P_P)(RNC)2][PF&

P-P = dppm, dppe, dppp, dppb) afforded the dinuclear palladium(I)

species (74); for (74; R = 2,6-

Me2HgH3; P-P = dppm) the solid state structure has been determined

t801.

studies on (73; R = Ph)

(R = 2,6-Me2 or 2,4,6-Me3-phenyl; by X-ray crystallography

a (PhO) ‘5’

‘PfOPh), -Pd-Cl

Cl--d I (PhO)

OF’\

I N,

WJW,

R (74 )

(73 ) Treatment arenediazonium containing

of the A-frame

precursor

salts [~-YCSH~N~][BF~]

a symmetrically

bridging

[Pd212(dppm)z(~-Nz-p-C6H4Me)l[BF41 determined

complexes

[Pd2X2(dppm)2]

(Y = H, Me, OMe, F, N@) arenediazenido

ligand.

The

(X = Cl, Br, I) with afforded crystal

1:l adducts structures

and [Pd2C12(dppm)2(~-N2-p-C6H4F)l[BF41

of

were

[81]. Two unusual cationic palladium(I) dimers containing bridging PtBu2 and terminal

PHlBu2 ligands have been reported. The fist of these, (75). contains a Pd-H-P bridging unit, whilst the other, prepared from (79, possesses state structure

was determined

terminal CO ligands (76). For both complexes

crystallographically

[82]. In a separate,

the solid

but related report, (75)

P.K. Byers/Coordination

426

Chemistry

Reviews

146 (1995)

reacted with excess isoprene to yield (77), which was characterised NMR spectroscopy

409-429

+

co

co

I R,HP -Pd

+ 1

using X-ray diffraction

[83].

I -

Pd - PHR2

\/ 92 L

(76)

and

+

R=‘Bu

(77)

A series of dinuclear palladium(I) complexes containing a bridging q3-indenyl been described. indenyl

The complexes

[84]. The preparation

containing a P,O,N-tridentate

ligand have

(78) were prepared from reaction of [PdC12(RNC)2] with lithium and crystallographic

structure

of a cationic

palladium(I)

dimer

ligand has been reported. The complex, (79), possesses an extremely

short Pd----Pd bond [2.500( 1) A] [85].

RNC

(79 )

(78 ) 11.4

PALLADIUM(O)

The preparation MeC(CHzPPh2)3) secondary phosphines

and single

crystal

have been reported

X-ray

analysis

of [Pd(CO)(triphos)]

[86]. The first palladium(O)

as ligands, [Pd(PtBtqH)3],

complex

{triphos

containing

=

only

has been prepared by treating [Pd($-C5Hs)($-

P.K. Byers/Coordinarion

Chemistn:

CgHg)] with P~BLQH [87]. The photolysis

427

Reviews 146 (1995) 409-429

(at 254 nm) of the palladium oxalate [Pd(C204)(dcpe)]

afforded, in high yield, the dinuclear palladium(O) complex (80). The solid state structure of (SO) has been determined,

and possesses a very short Pd----Pd distance of 2.761 l(5) 8, [88].

Ph2

(81)

(80) A range of mixed bisphosphine complexes

have been characterised

one equivalent phosphine

of a chelating

has been established

of palladium(O)

by 31P NMR spectroscopy

phosphine

ligand (P) affords complexes

[Pd(dba)(dppe)]

complexes

of the form [Pd(dba)(P-P)]

by X-ray diffraction

as determined by crystallography

and the

[89]. Treatment of [Pd(dba)z] with

ligand (P-P), or two equivalents

of a monodentate

(81). The crystal structure of

[90]. Buckminsterfullerene,

treated with [Pd(PPh3)4] gave a high yield of [Pd(Ca)(PPh3)2], q2-fashion,

has been prepared

Cm, when

in which fullerene is ligated in an

[91].

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