Derivatives of N,N'-bis[2-hydroxy-1,1-bis(hydroxymethyl)ethyl]ethanediamide

Low, John N.; Milne, Bruce F.; Ross, Jennifer-Nicola; Wardell, James L.

doi:10.1590/S0103-50532002000200012

Abstracts

Compound, [(HOCH2)3CNHC(O)]2 (1), obtained from (HOCH2)3CNH2 and EtOC(O)C(O)OEt, reacts with aryl aldehydes, ArCHO, to give the symmetric bis-alkylidene derivatives, N,N'-bis(2-Ar-5-ROCH 2-1,3-dioxan-5-yl)ethanediamides 3 (Ar = Ph, p-MeC6H4 or p-MeOC6H4, R = H). A similar reaction with Me2CO produced N'-bis(2,2-dimethyl-5-hydroxymethyl-1,3-dioxan-5-yl)ethanediamide (2). While three stereoisomers, (Z,Z)-, (Z,E)- and (E,E)-3 (Ar = Ph, R = H), were formed from 1 and PhCHO, only (Z,Z)-3 (Ar = p-MeC6H4 or p-MeOC6H4, R = H) was isolated from ArCHO (Ar = p-MeC6H4 or p-MeOC6H4) [the Z conformations in the solid state and in solution have equatorial-aryl, equatorial-HOCH2 and axial-amido groups: E forms have equatorial-aryl, equatorial-amido and axial-HOCH2 groups]. A 1:1 mixture of (Z,Z)-:(E,E)-3 (Ar = Ph, R = H) co-crystallises. Molecular mechanics calculations have been carried out on the conformation energies of (Z,Z)-and (E,E)-3 (Ar = Ph, R = H) and 1 and support the crystallographic and spectral findings. The stereoisomer, (Z,Z)-3 (Ar = Ph, R = H), is more reactive in alkylation reactions than the (E,E)-form: only (Z,Z)-3 (Ar = Ph, R = Ph3SnCH2) was isolated from the reaction of a mixture of (Z,Z)- and (E,E)-3 (Ar = Ph, R = H) with Ph3SnCH2I. From the reaction of excess allyl bromide with a 1:1 mixture of (Z,Z)- and (E,E)-3 (Ar = Ph, R = H), a 4:3 mixture of (Z,Z)- and (E,E)-3 (Ar = Ph, R = H2C=CHCH2) was isolated. Oxymercuriation of (Z,Z)-3 (Ar = Ph, R = H2C=CHCH2) with Hg(OAc)2 in MeOH, followed by anion exchange using NaCl, produced the single stereoisomer, {N-(Z)-[[(R²)-5-(3-chloromercuri-2-methoxypropyl)oxymethyl]-2-phenyl-1,3 -dioxan-5-yl]}{N'-(Z)-[[(S²)-5-(3-chloromercuri-2-methoxypropyl)oxymethyl]-2-phenyl-1,3-dioxan -5-yl]}ethanediamide (4), characterised by X-ray crystallography.

alkylidene formation; stannylation; oxymercuriation; X-ray crystallography; molecular mechanics

O composto [(HOCH2)3CNHC(O)]2 (1), formado a partir da reação de (HOCH2)3CNH2 com EtOC(O)C(O)OEt, reage com aldeídos aromáticos ArCHO, gerando como produtos bis-alquilideno simétricos, N,N'-bis(2-Ar-5-ROCH2-1,3-dioxan-5-a)etanodiamides 3 (Ar = Ph, p-MeC6H4 or p-MeOC6H4, R = H). Uma reação similar com Me2CO produziu N'-bis(2,2-dimethil-5-hidroximetil-1,3-dioxan-5-a)etanodiamida (2). Enquanto três estereoisômeros (Z,Z)-, (Z,E)- e (E,E)-3 (Ar = Ph, R = H) foram formados a partir da reação de 1 com PhCHO, somente (Z,Z)-3 (Ar = p-MeC6H4 ou p-MeOC6H4, R = H) foi isolado quando 1 reagiu com ArCHO (Ar = p-MeC6H4 ou p-MeOC6H4). As conformações Z têm os grupos: aril- equatorial, HOCH2- equatorial e amido-axial, no sólido e em solução, enquanto as conformações E têm os grupos aril- equatorial, amido- equatorial e HOCH2-axial. Uma mistura na proporção 1:1 de (Z,Z)-: (E,E)-3 (Ar = Ph, R = H) co-cristaliza. As energias de conformação de (Z,Z)- e (E,E)-3 (Ar = Ph, R = H) e 1 foram determinadas por cálculos de mecânica molecular. O estereoisômero (Z,Z)-3 (Ar = Ph, R = H) é mais reativo do que o (E,E) em reações de alquilação: somente o estereoisômero (Z,Z)-3 (Ar = Ph, R = Ph3SnCH2) foi isolado da reação de uma mistura de (Z,Z)- e (E,E)-3 (Ar = Ph, R = H) com Ph3SnCH2I. Quando uma mistura 1:1 de (Z,Z)- e (E,E)-3 (Ar = Ph, R = H) foi reagida com um excesso de brometo alílico, uma mistura na proporção de 4:3 de (Z,Z)- e (E,E)-3 (Ar = Ph, R = H2C=CHCH2) foi isolada. Reação de oxomercuração de (Z,Z)- e (E,E)-3 (Ar = Ph, R = H2C=CHCH2) com Hg(OAc)2 em metanol, seguida por uma troca aniônica utilizando NaCl, produziu um único estereoisômero, {N-(Z)-[[(R²)-5-(3-cloromercuria-2-metoxipropil)oximetil]-2-fenil-1,3-dioxan-5-il]}{ N'-(Z)-[[(S²)-5-(3-cloromercúria-2-metoxipropil)oximetil]-2-fenil-1,3-dioxan-5-il]}etanodiamida (4) que foi caracterizado por cristalografia de raio X.

Article

Derivatives of N,N'-bis[2-hydroxy-1,1-bis(hydroxymethyl)ethyl]ethanediamide

John N. Low^a, Bruce F. Milne^a, Jennifer-Nicola Ross^a and James L. Wardell^* * e-mail: j.wardell@abdn.ac.uk ^b

^a

Department of Chemistry, University of Aberdeen, Meston Walk, Old Aberdeen AB24 3UE, Scotland

^b

Departamento de Química Inorgânica, Instituto de Química, Universidade Federal do Rio de Janeiro, CP 68563, 21945-970, Rio de Janeiro - RJ, Brazil

O composto [(HOCH

₂

)

₃

CNHC(O)]

₂

(

1

), formado a partir da reação de (HOCH

₂

)

₃

CNH

₂

com EtOC(O)C(O)OEt, reage com aldeídos aromáticos ArCHO, gerando como produtos bis-alquilideno simétricos,

N,N

'-

bis

(2-Ar-5-ROCH

₂

-1,3-dioxan-5-a)etanodiamides

3

(Ar = Ph,

p

-MeC

₆

H

₄

or

p

-MeOC

₆

H

₄

, R = H). Uma reação similar com Me

₂

CO produziu

N

'-

bis

(2,2-dimethil-5-hidroximetil-1,3-dioxan-5-a)etanodiamida (

2

). Enquanto três estereoisômeros (

Z,Z

)-, (

Z,E

)- e (

E,E

)-

3

(Ar = Ph, R = H) foram formados a partir da reação de

1

com PhCHO, somente (

Z,Z

)-

3

(Ar =

p

-MeC

₆

H

₄

ou

p

-MeOC

₆

H

₄

, R = H) foi isolado quando

1

reagiu com ArCHO (Ar =

p

-MeC

₆

H

₄

ou

p

-MeOC

₆

H

₄

). As conformações

Z

têm os grupos: aril- equatorial, HOCH

₂

- equatorial e amido-axial, no sólido e em solução, enquanto as conformações

E

têm os grupos aril- equatorial, amido- equatorial e HOCH

₂

-axial. Uma mistura na proporção 1:1 de (

Z,Z

)-: (

E,E

)-

3

(Ar = Ph, R = H) co-cristaliza. As energias de conformação de (

Z,Z

)- e (

E,E

)-

3

(Ar = Ph, R = H) e

1

foram determinadas por cálculos de mecânica molecular. O estereoisômero (

Z,Z

)-

3

(Ar = Ph, R = H) é mais reativo do que o (

E,E

) em reações de alquilação: somente o estereoisômero (

Z,Z

)-

3

(Ar = Ph, R = Ph

₃

SnCH

₂

) foi isolado da reação de uma mistura de (

Z,Z

)- e (

E,E

)-

3

(Ar = Ph, R = H) com Ph

₃

SnCH

₂

I. Quando uma mistura 1:1 de (

Z,Z

)- e (

E,E

)-3 (Ar = Ph, R = H) foi reagida com um excesso de brometo alílico, uma mistura na proporção de 4:3 de (

Z,Z

)- e (

E,E

)-

3

(Ar = Ph, R = H

₂

C=CHCH

₂

) foi isolada. Reação de oxomercuração de (

Z,Z

)- e (

E,E

)-

3

(Ar = Ph, R = H

₂

C=CHCH

₂

) com Hg(OAc)

₂

em metanol, seguida por uma troca aniônica utilizando NaCl, produziu um único estereoisômero, {

N

-(

Z

)-[[(

R

²

)-5-(3-cloromercuria-2-metoxipropil)oximetil]-2-fenil-1,3-dioxan-5-il]}{

N

'-(

Z

)-[[(

S

²

)-5-(3-cloromercúria-2-metoxipropil)oximetil]-2-fenil-1,3-dioxan-5-il]}etanodiamida (

4

) que foi caracterizado por cristalografia de raio X.

Compound, [(HOCH

₂

)

₃

CNHC(O)]

₂

(

1

), obtained from (HOCH

₂

)

₃

CNH

₂

and EtOC(O)C(O)OEt, reacts with aryl aldehydes, ArCHO, to give the symmetric bis-alkylidene derivatives,

N,N

'-bis(2-Ar-5-ROCH

₂

-1,3-dioxan-5-yl)ethanediamides

3

(Ar = Ph,

p

-MeC

₆

H

₄

or

p

-MeOC

₆

H

₄

, R = H). A similar reaction with Me

₂

CO produced

N

'-bis(2,2-dimethyl-5-hydroxymethyl-1,3-dioxan-5-yl)ethanediamide (

2

). While three stereoisomers, (

Z,Z

)-, (

Z,E

)- and (

E,E

)-

3

(Ar = Ph, R = H), were formed from

1

and PhCHO, only (

Z,Z

)-

3

(Ar =

p

-MeC

₆

H

₄

or

p

-MeOC

₆

H

₄

, R = H) was isolated from ArCHO (Ar =

p

-MeC

₆

H

₄

or

p

-MeOC

₆

H

₄

) [the

Z

conformations in the solid state and in solution have

equatorial

-aryl,

equatorial

-HOCH

₂

and

axial

-amido groups:

E

forms have

equatorial

-aryl,

equatorial

-amido and

axial

-HOCH

₂

groups]. A 1:1 mixture of (

Z,Z

)-:(

E,E

)-

3

(Ar = Ph, R = H) co-crystallises. Molecular mechanics calculations have been carried out on the conformation energies of (

Z,Z

)-and (

E,E

)-

3 (

Ar = Ph, R = H) and

1

and support the crystallographic and spectral findings. The stereoisomer, (

Z,Z

)-

3

(Ar = Ph, R = H), is more reactive in alkylation reactions than the (

E

,

E

)-form: only (

Z

,

Z

)-

3

(Ar = Ph, R = Ph

₃

SnCH

₂

) was isolated from the reaction of a mixture of (

Z

,

Z

)- and (

E

,

E

)-

3

(Ar = Ph, R = H) with Ph

₃

SnCH

₂

I. From the reaction of excess allyl bromide with a 1:1 mixture of (

Z

,

Z

)- and (

E

,

E

)-

3

(Ar = Ph, R = H), a 4:3 mixture of (

Z

,

Z

)- and (

E

,

E

)-

3

(Ar = Ph, R = H

₂

C=CHCH

₂

) was isolated. Oxymercuriation of (

Z,Z

)-

3

(Ar = Ph, R = H

₂

C=CHCH

₂

) with Hg(OAc)

₂

in MeOH, followed by anion exchange using NaCl, produced the single stereoisomer, {

N

-(

Z

)-[[(

R

²

)-5-(3-chloromercuri-2-methoxypropyl)oxymethyl]-2-phenyl-1,3 -dioxan-5-yl]}{

N

'-(

Z

)-[[(

S

²

)-5-(3-chloromercuri-2-methoxypropyl)oxymethyl]-2-phenyl-1,3-dioxan -5-yl]}ethanediamide (

4

), characterised by X-ray crystallography.

Keywords

: alkylidene formation, stannylation, oxymercuriation, X-ray crystallography, molecular mechanics

Introduction

Despite being known for at least half a century,¹ and being readily prepared from common precursors, the symmetric diamido-hexol, N,N'-bis[2-hydroxy-1,1-bis(hydroxymethyl)ethyl]ethanediamide, [(HOCH₂)₃CNHC(O)]₂ (1), has attracted only occasional attention. However, its versatility as a precursor has still been well indicated, e.g., its hexa-O-derivatives have been mentioned in patents as potential explosives,² as sustained release [nitrogen] fertilizers,³ in preparations of ink-jets dyes⁴and as antioxidants.⁵ Unsubstituted 1 has also been used as a precursor of sucrose mimics⁶and as a ligand in lanthanide complexes in a study of the catalysed hydrolysis of phosphate esters.⁷

The versatility of 1 as a precursor would be greatly enhanced if reactions at the hydroxyl groups were controlled. Such a control effectively requires selective protection of the OH groups. A study of the protection of the OH groups in 1 has been carried out and the findings on the use of alkylidene groups are reported here.

Results and Discussion.

Compound 1 was readily obtained by a published route⁶ from (HOCH₂)₃CNH₂ and EtO₂CCO₂Et.

O-Alkylidene derivatives of 1

The reaction of a 1:1 mole ratio of 1 with Me₂CO in the presence of a catalytic amount of H₂SO₄ was sluggish and unselective, with both mono-and bis-isopropylidene derivatives being formed. Reaction with excess Me₂CO gave the bis-isopropylidene derivative, N,N'-bis(2,2-dimethyl-5-hydroxymethyl-1,3-dioxan-5-yl)ethane diamide (2), Scheme 1. Reaction of 1 with excess ArCHO similarly produced N,N'-bis-(5-HOCH₂-2-Ar-1,3-dioxan-5-yl)ethanediamide 3 (R = H). The chemical shifts for the NH, CH₂OH and 1,3-dioxanyl CH₂ ring protons in 2 are similar to those in (Z,Z)-3 (R = H) and are quite distinct from those in (E,E)-3 (R = H), see Tables 1 and 2 and the later discussion. Thus as in (Z,Z)- 3 (R = H), the conformation of the chair shaped 1,3-dioxanyl rings in 2 in solution has the NH(CO) units in axial sites and the CH₂OH (and aryl) groups in equatorial positions. As shown by the NMR spectra, the 1,3-dioxanyl rings are conformationally rigid at ambient temperature with no chair Û chair conversions detected for either the (Z) or (E)-forms: furthermore no (Z)- Û (E)- conversions occur.

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Three solid stereoisomeric benzylidene products, (Z,Z)-, (Z,E)- and (E,E)-3 (Ar = Ph, R = H), were isolated from the reaction of 1 with excess PhCHO, see Figure 1. The mole ratios of the initial products, (Z,Z)-, (Z,E)- and (E,E)-3 (Ar = Ph, R = H), as determined by ¹H NMR spectroscopy, were 1.8: 1.3: 1, i.e., an overall (Z): (E) ratio of ca. 3:2. Recrystallisation of the initial reaction products from aqueous acetone gave as the first crop of crystals, a 1:1 mixture of (Z,Z)- and (E,E)-3 (Ar = Ph, R = H), as indicated by NMR spectroscopy and confirmed by X-ray crystallography.⁸ Of interest, while co-crystallisation of enantiomers is often reported, reports of the co-crystallisations of other types of isomers, such as the stereoisomers here, are seldom made. This co-crystallized stereoisomeric mixture possessed a wide melting range, 185-224^oC. Successive recrystallisations, from ethyl acetate, of the material left in the mother liquor, led to the isolation of crystalline (Z, Z)-3 (Ar = Ph, R = H), m.p. 238-241^oC, and subsequently (Z,E)-3 (Ar = Ph, R = H), m.p. 194-197^oC. As well as the crystal structure of the 1:1 stereoisomeric mixture, that of the (Z,Z)-stereoisomer has also been reported.⁸ Suitable crystals of the (Z,E)-3 (Ar = Ph, R = H) isomer could not be grown for crystallography but its stereochemistry was readily resolved from the ¹H and ¹³CNMR spectra. The (Z,Z)-3 (Ar = Ph, R = H) molecules in the solid state are Z-shaped, whereas the (E,E)-isomers are maximally extended, as shown in Figure 1. A "L"-shape is proposed for the (Z,E)-stereoisomer. The (Z,Z)-3 (Ar = Ph, R = H) molecular shapes are essentially identical in the 1:1 stereoisomeric mixture and in the pure single stereoisomer sample. The 1,3-dioxanyl rings adopt chair conformations in all molecules, with the phenyl substituents, at C-2, always in equatorial sites. In (E)- and (Z)-5-hydroxymethyl-2-phenyl-1,3-dioxane rings, the hydroxymethyl groups at C-5 are in axial and equatorial sites, respectively. There are inversion symmetry related pairs of intramolecular N-HO hydrogen bonds between amide N-H and adjacent carbonyl oxygen centres: intermolecular O-HO hydrogen bonding between hydroxymethyl group and carbonyl atoms link molecules.⁸

From reaction of 1 with p-methoxybenzaldehyde or p-methylbenzaldehyde, only the (Z,Z)-isomer of 3 (Ar = p-R'C₆H₄, R' = MeO or Me, R = H) was isolated. NMR spectra clearly indicated their stereochemistries to be (Z,Z), with no other isomer present in the isolated and toluene-washed compounds. Both the (Z,Z)-isomers were essentially insoluble in most common organic solvents, and only sparingly so in DMSO. They were obtained from the reaction mixtures as pure compounds merely by extensive extractions with toluene, to remove the excess aldehyde. Small quantities of the other stereoisomers could have been lost with the washings: as there was no indications in the NMR spectra for other stereoisomers in the original crude product mixtures, the maximum amounts of these would have to be less than 5%.

Molecular mechanics calculations on 1 and 3 (Ar = Ph, R = H)

Molecular mechanics calculations on 1 and 3 (Ar = Ph, R = H) were obtained⁹ using the program Macromodel v6.5. Molecules in the gas phase were investigated using a 5000 step Monte Carlo search for conformers, followed by energy minimisation of the conformers generated. All energy minimisations were performed with the Macromodel MM2^* force field: solvent effects were assessed by the GB/AS continuum solvent model.¹⁰

Calculations on 1 and 3 (Ar = Ph, R = H) were limited to symmetric structures, e.g., only the (Z,Z)- and (E,E)- and not (Z,E)-forms of 3 were included in the calculations. Two favoured conformations, 1a and 1b, were calculated for 1, the more stable form in the three phases considered being invariably 1a, see Figure 2 and Table 3. In both conformations, one of the CH₂OH groups in each C(CH₂OH)₃unit is H-bonded to the carbonyl oxygen of the adjacent amide. The distinction between 1a and 1b resides in the orientations of the other two CH₂OH units, see Figure 2: these two OH groups are considered to be those used in the formation of the 1,3-dioxanyl rings in 3 (Ar = Ph, R = H). Calculations were carried out on four conformers of 3 (Ar = Ph, R = H) - two (Z,Z)- and two (E,E)-forms in three different phases, see Figure 3. Differences in the relative energies are found between the three phases, indicating the importance of solvation and H-bonding. The relative energies calculated for the organic solvent, CHCl₃, are most relevant to the reactions carried out in the aryl aldehyde.

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Reaction of PhCHO with the more stable 1a conformer provides either the (E,E)-conformer [(E,E)-3a] (Ph axial/CH₂OH equatorial) or the (Z,Z)- conformer [(Z,Z)-3a] (Ph equatorial/ CH₂OH equatorial): calculations show that [(Z,Z)-3a] is the more stable in CHCl₃. Reaction of PhCHO with the other conformer 1b will provide either the (E,E) conformer [(E,E)-3b] (Ph equatorial/ CH₂OH axial) or the (Z,Z)-conformer [(Z,Z)-3b] (Ph axial/ CH₂OH axial). Calculations indicated that of these two, [(E,E)-3b] is favoured. Thus the molecular mechanics calculations point to the favoured formations of [(Z,Z)-3a] and [(E,E)-3b] with the former dominating, from the two symmetrical forms of 1. The calculated preference for the Z-conformations of the 1,3-dioxanyl rings [i.e. with axial amido groups] and the indications that the phenyl groups are generally in equatorial sites are in agreement with the NMR and crystallographic findings.

The preference for the amido group over the CH₂OH group to occupy axial sites in 3 is similar to the situation reported for cyclohexane derivatives. In cyclohexanes, substituents, X, invariably favour equatorial sites. For example, the preferences [conformational energies]¹¹for NHC(O)OPh, CH₂OH and Ph to be in equatorial sites in cyclohexanes are 6.7, 7.36 and 11.7 kJ mol^-1, respectively, the NHC(O)Ph group being the nearest to the NHCOCONH group for which data could be found.¹¹ However, this equatorial preference need not apply to X-substituted 1,3-dioxanes, where polar OX interactions have to be considered. As also pointed out by Eliel and Wilen,¹¹steric compression of axial groups by lone pairs on oxygen atoms in 1,3-dioxanes is very small compared to the compression by syn-axial H-atoms in cyclohexanes. These effects can, in fact, result in a preference for axial positions, as shown, for example, by the CH₂OH group in 5-hydroxymethyl-2-isopropyl-1,3-dioxane in CCl₄ solution.¹¹

Reactions of the alkylidene derivatives

The remaining free hydroxyl groups in 3 (Ar = Ph, R = H) can be successfully derivatised as illustrated by the use of methanesulfonyl chloride and allyl bromide. Reactions of the 1:1 (Z,Z): (E,E)-3 mixture with these reagents gave 1:1 (Z,Z): (E,E)-mixtures of N,N'-bis(5-mesyloxymethyl-2-phenyl-1,3-dioxan-5-yl)ethanediamides 3 (Ar = Ph, R = MeSO₂), and N,N'-bis(5-allyloxymethyl-2-phenyl-1,3-dioxan-5-yl)ethanediamides 3 (Ar = Ph, R = CH₂=CHCH₂), respectively, as shown by the NMR spectra. Work-up can lead to preferential isolation of one of the components, e.g., [(Z,Z)-3 (Ar = Ph, R = H₂C=CHCH₂)] was isolated in a pure form on recrystallisation of the 1:1 mixture of [(Z,Z):(E,E)-3 (Ar = Ph, R = CH₂=CHCH₂)], from ethyl acetate: further work-up of the mother liquor, unfortunately, resulted in irreversible changes, which prevented the collection of [(E,E)-3 (Ar = Ph, R = CH₂=CHCH₂)]. In general, separation of both sets of isomers could be achieved by chromatography. Attempts to obtain N,N'-bis(5-chloromethyl-2-phenyl-1,3-dioxan-5-yl)ethane diamides from 3 (Ar = Ph, R = H) using Ph₃P/CCl₄ or thionyl chloride were unsuccessful: no reaction occurred using Ph₃P/CCl₄, even on reflux, while extensive decomposition resulted from the use of thionyl chloride.

Organometallic derivatives

Bis-oxymercuriation of (Z,Z)-3 (Ar = Ph, R = CH₂=CHCH₂) using Hg(OAc)₂ in methanol proceeded readily at room temperature.¹² NMR spectroscopy indicated that the product, isolated on crystallisation from Me₂CO/ethyl acetate, after anion exchange with NaCl, was the Marknovikov adduct, N,N'-bis-{(Z)-[5-[(3-chloromercuri-2-methoxypropyl)oxymethyl]-2-phenyl-1,3-dioxan-5 -yl]}ethanediamide (4) Equation 1. The atom arrangements in 4 were confirmed by X-ray crystallography. Furthermore, the stereochemistries at the -CH(OMe)- centres [C(19) and C(19a) in the crystallographic numbering scheme] were revealed, see Figure 4. Unfortunately, the structure of 4 was only refined to 9.4%, due in the greater part to crystal decomposition in the X-ray beam.

The molecule of 4 possesses a centre of symmetry at the midpoint of the central (O)-C-C(O) bond with both mercury sites being equivalent. Due to the symmetry in 4, selected geometric parameters for only one half of the molecule are listed in Table 4: parameters involving atoms in the other half of the molecule are indicated by the use of the superscipt (ª) [symmetry operation a: -x, 2-y, 1-z]. The carbon atoms at which the OMe groups are attached have opposite chirality and so overall the molecule is achiral, i.e. we have {N-(Z)-[[(R²)-5-(3-chloromercuri-2-methoxy propyl)oxymethyl]-2-phenyl-1,3-dioxan-5-yl]}{N '-(Z)-[[(S²)-5-(3-chloromercuri-2-methoxypropyl)oxymethyl]-2 -phenyl-1,3-dioxan-5-yl]}ethanediamide stereoisomer of 4: the high yield of the isolated stereoisomer pointed to a high stereoselectivity in the mercuriation reaction. Indeed other stereoisomers of 4, e.g. the bis-[(N,N'-(Z),(R²)] or bis-[(N,N'-(Z),(S²)] stereoisomers, were not detected. The dioxanyl rings, as found for stereoisomers of 3 (Ar = Ph: R = H) have chair conformations, with puckering parameters,¹³ amplitude (Q) = 0.570(16)^o, q = 175.3(17)^o, f = 191(25)^o.

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The primary bonds to each Hg in 4 are essentially collinear, C(22)-Hg(1)-Cl(1) / [C(22)^a-Hg(1)^a-Cl(1)^a ] = 179.6(7)^o,see Table 4: the primary bond lengths, Hg(1)-C(22) / [Hg(1)^a-C(22)^a] = 2.06(3)Å and Hg(1)-Cl(1) / [Hg(1)^a-Cl(1)^a] = 2.331(6)Å, are in the expected regions.^14-16 As well as forming primary bonds, mercury(II) also exhibits a strong tendency to form secondary bonds within the sum of the van der Waals radii of the relevant atoms.^14-17 There is some controversy over the value of the van der Waals radius of mercury. Values of 1.73¾2.00Å have been suggested by Canty and Deacon,¹⁸ while even higher values, 2.1-2.2Å, have been proposed by Batsanov,¹⁹ all these being much higher than the value of 1.55Å, estimated from the critical volume of the metal.²⁰ As the generally accepted van der Waals radius for O is 1.50Å, the O(17)-Hg(1) /[O(17)aHg(1)a] intramolecular separations of 2.882(15)Å fall well within the van der Waals radii sum for Hg and O, no matter which Hg vdW value is taken. These secondary Hg-O bonds result in the formation of 5-membered Hg(1)-O(17)-C(18)-C(19)-C(22) / [Hg(1)^a-O(17)^a-C(18)^a -C(19)^a-C(22)^a] rings with envelope conformations [flap at C(19) / C(19)^a]. Other intramolecular, HgO separations, Hg(1)-O(20) / [Hg(1)^a-O(20)^a] = 3.32(3)Å, are within the majority of the limits set for the sum of the van der Waals radii for Hg and O. As shown in Figure 5, the gauche arrangements of Hg(1) and O(20), Hg(1) and C(18), about the C(19)-C(22) bond, are ideal for HgO (20) and HgO(17) interactions and are taken as indications of secondary bonding.

There are, in addition, intermolecular contacts, HgHgⁱ [3.776(2)Å] in 4: symmetry operation i: -x, 3-y, -z], which produce staggered chains of molecules almost parallel to the b, c diagonal. Intermolecular mercurymercury interactions have been variously reported, for example,²¹ HgHg = 3.5620(5)Å in [Hg₃O(1,3-dimethyluracil-5-yl)₃ ]NO₃.2H₂O. The closest Hg separations with aromatic C atoms in 4 occur at distances of 3.75-3.79Å, cf. vdW radius of C = 1.65-1.70Å.²⁰ As found generally in organomercury chemistry, secondary bonds have little effect on the linear geometry of the primary bonds.^14-16

As with 3 (Ar = Ph, R = H), there are intramolecular hydrogen bonds involving N(13)-H(13)O(15) [N(13)-H(13) = 0.86Å: H(13)O(15) = 2.28Å: N(13)O(15) 2.67(2) Å: N(13)-H(13)O(15) = 108^o] and analogously for N(13)^a-H(13)^aO(15)^a.

Attempts to get Ph₃SnH addition to the alkenyl groups in (Z,Z)-3 (Ar = Ph, R = CH₂=CHCH₂), in the presence of the radical initiator, AIBN, failed: complete recover of [(Z,Z)-3 (Ar = Ph, R = CH₂=CHCH₂)] was made and a near quantitative formation of Ph₃SnSnPh₃ was indicated. Tin hydrides, such as Ph₃SnH, are known to be sensitive to organic bases, such as amines and sulfoxides, and decompose to Ph₃SnSnPh₃:²² it appears that the amido derivative, (Z,Z)-3 (Ar = Ph, R = CH₂=CHCH₂), is also sufficiently basic to affect this decomposition.

A bis-stannylated derivative was, however, obtained from 3 (Ar = Ph, R = H): the compound, (Z,Z)-3 (Ar = Ph, R = Ph₃SnCH₂), d¹¹⁹Sn = -139.8ppm, was isolated from the reaction of the 1:1 mixture of (Z,Z)-:(E,E)-3 (Ar = Ph, R = H), with Ph₃SnCH₂I [1:2.05 mole ratio], in DMF in the presence of NaH, after chromatography, see Figure 6. The ¹¹⁹Sn NMR spectrum of the crude reaction product, prior to chromatographic separation, exhibited several peaks: the most intense peak being at -139.8ppm, i.e. the precise value of the isolated product. Other peaks were also in the region expected for Ph₃SnCH₂OR*compounds [-145 to -135ppm],²³ but all these were minor peaks. It is possible that the stannylated derivative of (E,E)-3 (Ar = Ph, R = H) would also have a d¹¹⁹Sn value of -139.8ppm, and that it was also present among the reaction products, but it somehow escaped isolation by chromatography. However, the latter is considered unlikely, and it is assumed that (E,E)-3 (Ar = Ph, R = Ph₃SnCH₂) could not be a significant product, if formed at all. The crystal structure determination of (Z,Z)-3 (Ar = Ph, R = Ph₃SnCH₂), already reported,²⁴ indicated the tin centres to be 4-coordinate, with slightly distorted tetrahedral geometries, as have been found for other Ph₃SnOR* compounds.²³ As also in these other Ph₃SnCH₂OR* compounds, the intramolecular SnO(C-5) separation is short [2.91(1)Å] and within the limits accepted for coordination [the sum of the van der Waals radii for Sn and O is ca. 4.1Å].²⁰ However, no Sn-O bonding is assumed since the C-Sn-C angles are close to those expected for a 4-coordinate and near tetrahedral arrangement. Any SnO interaction would create, in any case, highly strained three membered rings.

As shown by the structures listed in the Cambridge Crystallographic Data Base,²⁵ tetraorganotin compounds generally have 4-coordinate tin centres with near tetrahedral geometries. This is a consequence of the poor acceptor strength of the tin centre: however, in a limited number of rigid tetraorganotin compounds with suitably sited donor groups, intramolecular complexation can occur with the formation of 5- and even 6-coordinate tin centres.²⁶ Clearly the tin centres in (Z,Z)-3 (Ar = Ph, R = Ph₃SnCH₂) are not complexed to any of the donor centres. The Lewis acidity of organotin halides, R_4-nSnX_n, invariably increases with the value of n. The reactions of (Z,Z)-3 (Ar = Ph, R = Ph₃SnCH₂) with iodine (2n mol equivalents) were undertaken to obtain the stronger Lewis acids, (Z,Z)-3 (Ar = Ph, R = I_nPh_3-nSnCH₂, n = 1 or 2): as indicated by the solution NMR parameters, especially d¹¹⁹Sn values, (Z,Z)-3 (Ar = Ph, R = IPh₂SnCH₂) [d¹¹⁹Sn = -122.5ppm] and (Z,Z)-3 (Ar = Ph, R = I₂PhSnCH₂) [d¹¹⁹Sn = -227ppm], were 4 and 5 coordinate, respectively.

Conclusions

Protection of 4 of the 6 hydroxyl groups in 2 can be achieved by standard alkylidene procedures: the bis alkylidene derivatives, 3, can be further derivatised by standard means. Transformations of the bis-mercurated, 4, and the bis stannylated, (Z,Z)-3 (Ar = Ph, R = Ph₃SnCH₂), compounds provide further routes to selected derivatives.

Experimental

Melting points were determined using a Kofler hotstage and are uncorrected Solution NMR spectra were obtained on Bruker 250 MHz and Varian 400 MHz instruments. IR spectra were obtained on Philips Analytical PU 9800 FTIR and Nicolet 205 FTIR instruments.

N,N'-Bis-[tris(hydroxymethyl)methyl]ethanediamide (1)

A solution of tris(hydroxymethyl)aminomethane (10.00 g, 82.6 mmol) and diethyl oxalate (6.03g, 41.3 mmol) in methanol (25ml) was refluxed for 2h. The reaction mixture was cooled, filtered and the precipitate was recrystallised from aqueous EtOH (80%); yield 75-80%; m.p. 221-223 ^oC [lit.⁶m.p. 224 ^oC]. ¹H and ¹³C NMR spectra were identical with those reported.⁶IR (n_max/cm^-1): 3413, 3339 (NH), 3245 (OH), 1667, 1516 (amide),

N,N'-Bis-(5-hydroxymethyl-2,2-dimethyl-1,3-dioxan -5-yl)ethanediamide (2)

A reaction mixture of 1 (3.00g, 10mmol) and concentrated H₂SO₄ (1ml) in acetone (100ml) was stirred at room temperature for 16h and filtered. The filtrate was washed with aqueous sodium bicarbonate, dried and rotary evaporated. The solid residue was recrystallised from acetone, yield 15%, m. p. 157-159 ^oC. Anal. calcd. for C₁₆H₂₈N₂O₈ : C, 51.1; H, 7.5; N, 7.4. Found: C, 51.0; H, 7.5; N, 7.4%. NMR data are listed in Table 1. IR (n_max/cm^-1): 3312, 3211, 3147, 3048, 1663, 1574 (amide).

N,N'-Bis-(5-hydroxymethyl-2-phenyl-1,3-dioxan-5-yl)ethanediamide, 3 (Ar = Ph, R = H)

A reaction mixture of 1 (1.5g, 5.1mmol) and concentrated H₂SO₄ (0.5ml) in benzaldehyde (25ml) was stirred for 12h at room temperature. Diethyl ether (10ml) and water (25ml) were added, and the viscous organic layer separated. On standing, a finely divided solid was collected, yield 85-95%. NMR spectra of this crude product revealed the presence of three stereoisomers, (Z,Z)-, (E,E)- and (Z,E)-3 (Ar = Ph, R = H), in mole ratios of 1.8:1.3:1. Recrystallisation of the crude product from aqueous acetone gave a 1:1 mixture of stereoisomers, (Z,Z)- and (E,E)-3 (Ar = Ph, R = H), yields ranged between 45-60%. This 1:1 mixture had a melting range between 185-225 ^oC. Anal. calcd. for C₂₄H₂₈N₂O₈ : C, 61.0; H, 6.0; N, 5.9. Found: C, 61.1; H, 6.0; N, 5.9 %. IR (n_max/cm^-1): 3490, 3382, 3337, 1671, 1516.

All solvents were removed from the mother liquor under vacuo to leave a solid residue, which was recrystallised from ethyl acetate. The colourless crystalline solid obtained was the single steroisomer, (Z,Z)-3 (Ar = Ph, R = H); m.p. 238-241 ^oC. The mother liquor from the second crystallisation, on concentration and further recrystallisation gave crystals of stereoisomer, (Z,E)-3 (Ar = Ph, R = H); m.p. 194-197 ^oC. NMR spectra of the three stereoisomers are displayed in Tables 1 and 2.

N,N'-Bis-[(Z)-(5-hydroxymethyl-2-(p-methoxyphenyl)-1,3 -dioxan-5-yl)]ethanediamide, (Z,Z)-3 (Ar = p-MeOC₆H₄, R = H)

A reaction mixture of 1 (1.5g, 5.1mmol) and concentrated H₂SO₄ (0.5ml) in p-methoxybenzaldehyde (25ml) was stirred for 12h at room temperature. Diethyl ether (10ml) and water (25ml) were added, and the viscous organic layer separated. On standing, a finely divided solid was collected. ¹H NMR spectrum of the solid, indicated the presence of a single stereoisomer, still contaminated with p-methoxybenzaldehyde. The latter was removed on Soxhlet extraction with toluene. The white residue was insoluble in most organic solvents and only sparingly soluble in DMSO. Yield: 78%; m.p. 245-248 ^oC. Anal. calcd. for C₂₆H₃₂N₂O₁₀ : C, 58.6; H, 6.1; N, 5.3. Found: C, 58.1; H, 5.9; N, 5.6 %. IR (n_max/cm^-1): 3467, 3412, 3374, 3341, 1676, 1518. NMR data, displayed in Tables 1 and 2, indicated that the stereoisomer was (Z,Z)-(3: Ar = p-MeOC₆H₄, R = H).

N,N'-Bis-[(Z)-(5-hydroxymethyl-2-(p-methylphenyl)-1,3 -dioxan-5-yl)]ethanediamide, (Z,Z)-3 (Ar = p-MeC₆H₄, R = H)

A reaction mixture of 1 (1.5g, 5.1mmol) and concentrated H₂SO₄ (0.5ml) in p-methylbenzaldehyde (25ml) was stirred for 12h at room temperature. Diethyl ether (10ml) and water (25ml) were added, and the viscous organic layer separated. On standing, a finely divided solid was collected. ¹H NMR spectrum of the solid, indicated the presence of a single stereoisomer, (Z,Z)-3 (Ar = p-MeC₆H₄, R = H), still contaminated with p-methylbenzaldehyde, which was removed on Soxhlet extraction with toluene. The white residue was insoluble in most organic solvents and only sparingly soluble in DMSO. Yield: 73%; m.p. 240 ^oC dec. Anal. calcd. for C₂₆H₃₂N₂O₈ : C, 62.4; H, 6.4; N, 5.6. Found: C, 61.7; H, 6.3; N, 5.6 %. IR (n_max/cm^-1): 3488, 3366, 3336, 1686, 1508.

NMR data are displayed in Tables 1 and 2.

N,N'-Bis-(Z)- and -(E)- (5-allyloxymethyl-2-phenyl-1,3-dioxan-5-yl)ethanediamide, (Z,Z)- and (E,E)-3 (Ar = Ph, R = H₂C=CHCH₂)

To a solution containing a 1:1 mixture of (Z,Z)-:(E,E)-3 (Ar = Ph, R = H), (2.00g, 4.23mmol) and NaH (0.2g) in dry DMF (6ml) was added allyl bromide (3.07g, 25.4 mmol). After stirring the reaction mixture at room temperature for 24h, it was poured onto ice (25g) and filtered. The dried solid residue had a melting range from 137 to 184 ^oC, and was shown by the ¹H NMR spectrum to be a 4:3 mixture of stereoisomers, (Z,Z)-:(E,E)-3 (Ar = Ph, R = H₂C=CHCH₂. Recrystallisation from acetone gave pure stereoisomer (Z,Z)-3 (Ar = Ph, R = H₂C=CHCH₂), m.p. 155-156 ^oC. The mother liquor still contained both (Z,Z)-:(E,E)-3 (Ar = Ph, R = H₂C=CHCH₂). NMR data are displayed in Tables 1 and 2.

N,N'-Bis-{(Z)-[5-(3-chloromercuri-2-methoxypropyl oxymethyl)-2-phenyl-1,3-dioxan-5-yl]}ethanediamide (4)

To a suspension of (Z,Z)-3 (Ar = Ph, R = H₂C=CHCH₂) (0.38g, 1.2 mmol) in MeOH (10ml) was added a solution of Hg(OAc)₂ (0.44g, 1.2mmol) in MeOH (20ml). After stirring overnight, a saturated solution of sodium chloride (20 ml) was added, followed by water (80 ml). The precipitate was collected, and recrystallised from acetone: ethyl acetate (2:1) to give colourless crystals of {N-(Z)-[[(R²)-5-(3-chloromercuri-2-methoxypropyl)oxymethyl] -2-phenyl-1,3-dioxan-5-yl]}{N'-(Z)-[[( S²)-5-(3-chloromercuri-2-methoxypropyl)oxymethyl]-2-phenyl -1,3-dioxan-5-yl]}ethanediamide (4). Yield 95%, m.p.169-171 ^oC. ¹H NMR (CDCl₃): d: 1.84-1.97 (m, 4H, CH₂Hg), 3.31(s, 6H, OMe), 3.46-3.50 (m, 4H, ºCOCH₂), 3.74-3.82 (m, 4H, CH₂OCHPh), 3.94-4.03 (m, 6H, =CHOCH₃ + OCH₂CHOCH₃), 4.49-5.58 (m, 4H, CH₂OCHPh), 5.61 (s, 2H, CHPh), 7.36-7.39 (m, 6H, aryl), 7.49-7.52 (m, 4H, aryl), 7.98 (s, 2H, NH). ¹³C NMR (CDCl₃): d: 31.8 (CH₂Hg), 53.9 (C_quart), 56.4 (OMe), 69.6 (ºC-CH₂O), 69.9 (CH₂), 70.3 (=CHOCH₃), 73.7 (CH₂CHOCH₃), 101.5(CHPh), 126.1, 128.2, 129.0 & 137.3 (aryl), 159.7 (CO).

N,N'-Bis-[(Z)-(5-triphenylstannylmethyloxymethyl)-2 -phenyl-1,3-dioxan-5-yl)]ethane-diamide, (Z,Z)-3 (Ar = Ph, R = Ph₃SnCH₂)

Sodium hydride (1.50g, 6.5 mmol), and (iodomethyl) triphenylstannane (4.28g, 8.72 mmol) were successively added to a solution of a 1:1 mixture of (Z,Z)-:(E,E)-3 (Ar = Ph, R = H), (2.00g, 4.23 mmol) in anhydrous DMF (20ml). The mixture was stirred overnight at room temperature, water (20ml) and diethyl ether (20ml) were added, and the organic layer was collected, dried over magnesium sulfate, and rotary evaporated. The reaction residue had d¹¹⁹Sn values in the NMR spectrum in CDCl₃solutionof -145.2, -142.0, -142.4, -139.8 (major), -130.2, -107.5, -101.6, -92.6 and ¾78.7ppm. The residue was separated, on a chromatotron, using hexane/ethyl acetate (2:1) as eluent. The major fraction contained the triphenylstannylmethyl derivative of (Z,Z)-3 (Ar = Ph, R = H). It was recrystallised from ethyl acetate; yield 23%, m.p. 170- 174 ^oC. Anal. calcd. for C₆₂H₆₀N₂O₈ Sn: C, 62.1; H, 5.1; N, 2.3. Found: C, 63.0; H, 5.5; N, 2.2%. IR (n_max/cm^-1) 3297, 1676, 1507.

NMR Data are displayed in Tables 1 and 2.

X-Ray crystallography

Data were collected on an Enraf-Nonius CAD-4 diffractometer: data collection: CAD-4/PC.²⁷ Cell refinement: SET4 and CELDIM Software.²⁷Data reduction: DATRD2 in NRCVAX94.^28. Program used to solve structure: SHELXS-97. ²⁹ Program used to refine structure: SHELXL-97.³⁰Preparation of material for publication: SHELXL-97 ³⁰and WordPerfect macro PRPKAPPA.³¹ Diagrams were prepared with the aid of PLATON.³²

The compound 4 was found to be unstable in the X-ray beam. The compound lies on an inversion centre in the crystal and has an overall Z-shape. H atoms were treated as riding atoms with C-H 0.93 to 0.98Å, N-H 0.86Å. Atoms C(7) to C(12) had anisotropic displacement parameter restraints applied to them. The C(14)-C(14)^a distance (symmetry operation: a: -x, 2-y, 1-z) was constrained to be 1.520(5)Å, this was the average distance found for this bond in the 3 molecules reported in 3 (Ar = Ph, R = H).⁸ The largest peaks in the difference map were adjacent to the Hg atom at distances 1.11 to 1.06Å.

Crystal refinement data for the compound are listed in Table 5.

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Supplementary material

Supplementary X-ray data for 4 are available from the Cambridge Crystallographic Data Centre, 12 Union Road, Cambridge CB2 1EZ, UK (fax: +44-1223-336033) on request, quoting the deposition number CCDC 153008.

Acknowledgement

The authors thank Professor George Ferguson, University of Guelph, Canada for the X-ray data collection. JLW thanks CPNq for support as a visiting professor at UFRJ.

Received: May 19, 2001

Published on the web: February 22, 2002

1. Pierce, J.S.; Lunsford, C.D.; Raiford, R.W.; Rush, J.L.; Riley, D.W.; J. Am. Chem. Soc 1951, 73, 2595.
2. Frankel, M.B. US Patent 3.228.929, 1966 [CA: 64, P9594].
3. EniChem Anic S.P.A.: Jpn. Kokai Tokkyo. J. Patent 62.249.958 (87.249.958), 1988 [CA: 109, P92287].
4. Malhotra, S.L.; Naik, K.N.; MacKinnon, D.N.; Mayo, J.D.; Gagnon, Y.; Goodgrand, H.B.; US Patent 57709737, 1998 [CA: 128, P129292].
5. Wheeler, E.L.; Jancis, E.H.; Gencarelli, R.A.; Barrows, F.H.; US Patent 4.304.714, 1982 [CA: 96, P86482].
6. Dubois, G.E.; Zhi, B.; Roy, G.M.; Stevens, S.Y.; Yalpani, M.; J Chem. Soc., Chem. Commun 1992, 1604.
7. Rammo, J; Schneider, H.-J.; Liebigs Ann 1996, 1957.
8. Ross, J.-N.; Wardell, J.L.; Low, J.N.; Ferguson, G.; Acta Crystallogr. 1996, C52, 228.
9. Mohamadi, F.; Richards, N.G.J.; Guida, W.C.; Liskamp, R.; Lipton, M.; Caulfield, C.; Chang, G.; Hendrickson, T.; Still, W.C.; J. Comput. Chem 1990, 11, 440.
10. Still, W.C.; Tempczyk, A.; Hawley, R.C.; Hendrickson, T.; J. Am. Chem. Soc 1990, 12, 6127.
11. Eliel, E.L.; Wilen, S.H.; Organic Stereochemistry;Wiley: New York, 1994.
12. Wardell, J.L. In Inorganic Reactions and Mechanisms; Zuckerman, J.J. ed.; VCH Publications: New York, 1988, Vol. 11, 277.
13. Cremer, D.; Pople, J.A.; J. Amer Chem. Soc 1975, 97, 1354.
14. Casas, J.S.; García-Tasende, M.S.; Sordo, J.; Coord. Chem. Revs 1999, 193-195, 283.
15. Holloway, C.E.; Melnik, M.; J. Organomet. Chem 1995, 495, 1.
16. Davies, A.G.; Wardell, J.L. In Comprehensive Organometallic Chemistry; Abel, E.W.; Stone, F.G.A.; Wilkinson, G. eds.; 2^nd ed.; Pergamon Press: Oxford, 1995, Volume 3, p 135; Wardell, J.L. In Comprehensive Organometallic Chemistry, Wilkinson, G.; Stone, F.G.A.; Abel, E.W. eds.; 1^st ed.; Pergamon Press: Oxford, 1982, Volume 1, p 863.
17. Grdenic, D.; Quart. Rev 1955, 19, 303.
18. Canty, A.J.; Deacon, G.B.; Inorg. Chim. Acta 1980, 45, L225.
19. Batsanov, S.S.; Russ. J. Inorg. Chem 1991, 36, 1694.
20. Huheey, J.E.; Keiter, E.A.; Keiter, R.L.; Inorganic Chemistry, 4^th ed., Harper Collins: New York, 1993.
21. Zamora, F.; Sabat, M.; Janik, M.; Siethoff, C.; Lippert, B.; Chem. Commun 1997, 485.
22. Wardell, J.L.; Wigzell, J.McM.; J. Organomet. Chem. 1982, 244, 225.
23. Cox, P.J.; Doidge-Harrison, S.M.S.V.; Howie, R.A.; Wardell, J.L.; J. Crystallogr. Spectrosc. Res. 1991, 21, 735.
24. Ross, J.-N.; Wardell, J.L.; Low, J.N.; Ferguson, G.; Acta Crystallogr 1996, C52, 1961.
25. Allen, F. H., Kennard, O.; Chem. Des. Autom. News 1993, 8, 31.
26. see for example, Lo, K.M.; Ng, S.W.; Das, V.G.K.; J. Cryst. Chem. Res 1997, 12, 933;
27. Fu, F.Z.; Li, H.Y.; Zhu, D.S.; Fang, Q.X., Pan, H.A.; Tiekink, E.R.T.; Kayser, F.; Biesemans, M.; Verbruggen, I.; Willem, R.; Gielen, M.; Organometallics 1995, 490, 163;
28. Jurkschat, K.; Schilling, J.; Mugge, C.; Tzschach, A.; Meunier-Piret, J.; van Meerssche, M.; Gielen, M.; Willem, R.; Organometallics 1988, 7, 38.
29. Enraf-Nonius; CAD4-PC Software; Version 1.1; Delft, Holland, 1992.
30. Gabe, E.J.; Le Page, Y.; Charland, J.-P.; White, P.S.; J. Appl. Cryst 1989, 22, 384.
31. Sheldrick, G.M; SHELXS-97; Program for the solution of crystal structures; University of Göttingen, Germany, 1997.
32. Sheldrick, G.M.; SHELXL-97; Program for the refinement of crystal structures; University of Göttingen, Germany, 1997.
33. Ferguson, G.; PRPKAPPA - a WordPerfect-5.1 macro to formulate and polish CIF format files from the SHELXL-97 refinement of Kappa-CCD data; University of Guelph, Canada, 1999.
34. Spek, A.L.; PLATON; Molecular Geometry and Graphics Program, January March 2000 version; University of Utrecht, Holland, 2000.

*

e-mail:

j.wardell@abdn.ac.uk

Publication Dates

Publication in this collection
25 June 2002
Date of issue
2002

History

Accepted
22 Feb 2002
Received
19 May 2001

This work is licensed under a Creative Commons Attribution-NonCommercial 4.0 International License.

[1] 1. Pierce, J.S.; Lunsford, C.D.; Raiford, R.W.; Rush, J.L.; Riley, D.W.; J. Am. Chem. Soc 1951, 73, 2595.

[2] 2. Frankel, M.B. US Patent 3.228.929, 1966 [CA: 64, P9594].

[3] 3. EniChem Anic S.P.A.: Jpn. Kokai Tokkyo. J. Patent 62.249.958 (87.249.958), 1988 [CA: 109, P92287].

[4] 4. Malhotra, S.L.; Naik, K.N.; MacKinnon, D.N.; Mayo, J.D.; Gagnon, Y.; Goodgrand, H.B.; US Patent 57709737, 1998 [CA: 128, P129292].

[5] 5. Wheeler, E.L.; Jancis, E.H.; Gencarelli, R.A.; Barrows, F.H.; US Patent 4.304.714, 1982 [CA: 96, P86482].

[6] 6. Dubois, G.E.; Zhi, B.; Roy, G.M.; Stevens, S.Y.; Yalpani, M.; J Chem. Soc., Chem. Commun 1992, 1604.

[7] 7. Rammo, J; Schneider, H.-J.; Liebigs Ann 1996, 1957.

[8] 8. Ross, J.-N.; Wardell, J.L.; Low, J.N.; Ferguson, G.; Acta Crystallogr. 1996, C52, 228.

[9] 9. Mohamadi, F.; Richards, N.G.J.; Guida, W.C.; Liskamp, R.; Lipton, M.; Caulfield, C.; Chang, G.; Hendrickson, T.; Still, W.C.; J. Comput. Chem 1990, 11, 440.

[10] 10. Still, W.C.; Tempczyk, A.; Hawley, R.C.; Hendrickson, T.; J. Am. Chem. Soc 1990, 12, 6127.

[11] 11. Eliel, E.L.; Wilen, S.H.; Organic Stereochemistry;Wiley: New York, 1994.

[12] 12. Wardell, J.L. In Inorganic Reactions and Mechanisms; Zuckerman, J.J. ed.; VCH Publications: New York, 1988, Vol. 11, 277.

[13] 13. Cremer, D.; Pople, J.A.; J. Amer Chem. Soc 1975, 97, 1354.

[14] 14. Casas, J.S.; García-Tasende, M.S.; Sordo, J.; Coord. Chem. Revs 1999, 193-195, 283.

[15] 15. Holloway, C.E.; Melnik, M.; J. Organomet. Chem 1995, 495, 1.

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