EP1732872A1

EP1732872A1 - Method for hydroformylating olefins in the presence of organophosphoric compounds

Info

Publication number: EP1732872A1
Application number: EP05707865A
Authority: EP
Inventors: Cornelia Borgmann; Detlef Selent; Armin BÖRNER; Klaus-Diether Wiese; Dagmara Ortmann; Oliver MÖLLER; Dieter Hess
Original assignee: Oxeno Olefinchemie GmbH
Current assignee: Evonik Operations GmbH
Priority date: 2004-03-19
Filing date: 2005-01-27
Publication date: 2006-12-20
Also published as: KR20070007830A; CN1972889A; US7495133B2; US20070282130A1; JP2007529466A; DE102004013514A1; WO2005090276A1; MXPA06010565A; ZA200608638B

Abstract

The invention relates to the use of novel organophosphoric compounds and metal complexes thereof in catalytic reactions, and to the hydroformylation of olefins in the presence of these compounds.

Description

METHOD FOR HYDROFORMYLING OLEFINS IN THE PRESENCE OF PHOSPHORORGANIC COMPOUNDS

The present invention relates to the use of new organophosphorus compounds and their metal complexes in catalytic reactions and the hydroformylation of olefins in the presence of these compounds.

Hydroformylation (so-called oxation or oxo synthesis) is the reaction between an ethylenically unsaturated compound, carbon monoxide and hydrogen in the presence of a catalyst to give the aldehyde, which is richer by one carbon atom. In these reactions, compounds of transition metals of the 8th to 10th group of the Periodic Table of the Elements, in particular compounds of rhodium and cobalt, are frequently used as catalysts.

Compared to catalysis with cobalt compounds, hydroformylation with rhodium compounds generally offers the advantage of higher selectivity in milder reaction conditions and is therefore usually more economical. In the hydroformylation catalyzed by rhodium, complex compounds are usually used which consist of rhodium and ligands with phosphorus, nitrogen or oxygen donor atoms, preferably trivalent phosphorus compounds as ligands. Known ligands are, for example, compounds from the classes of the phosphines, phosphites and phosphonites. An overview of hydroformylation of olefins can be found in B. CORNILS, W. A. HERRMANN, "Applied Homogeneous Catalysis with Organometallic Compounds", Vol. 1 & 2, VCH, Weinheim, New York, 1996.

Every catalyst system (cobalt or rhodium) has its specific advantages. Depending on the starting material and target product, different catalyst systems consisting of metal and one or more ligands are used. When working with rhodium and henylphosphine, olefins can be hydroformylated at lower synthesis gas pressures. Triphenylphosphine is generally used in excess as the phosphorus-containing ligand, a high ligand / rhodium ratio being required in order to increase the selectivity of the reaction to the commercially desired n-aldehyde product. Around To increase the economy, it would be desirable to reduce the excess ligand with the same results.

US 4,694,109 and US 4,879,416 relate to bisphosphine ligands and their use in the hydroformylation of olefins at low synthesis gas pressures. Particularly in the hydroformylation of propene, high activities and high n / i selectivities are achieved with ligands of this type.

WO 95/30680 describes further bidentate phosphine ligands and their use in catalysis, including in hydroformylation reactions.

Ferrocene-bridged bisphosphines are disclosed, for example, in US 4,169,861, US 4,201,714 and US 4,193,943 as ligands for hydroformylations.

The disadvantage of bidentate phosphine ligands - like those listed above - is the relatively complex production, which reduces the economic efficiency of technical processes. In addition, their activity generally decreases sharply with longer-chain olefins and with olefins with internal double bonds.

Rhodium-monophosphite complexes are suitable catalysts for the hydroformylation of branched olefins with internal double bonds, but the selectivity for terminally hydroformylated compounds is low. EP 0 155 508 describes the use of bisarylene-substituted monophosphites in the rhodium-catalyzed hydroformylation of sterically hindered olefins, e.g. B. isobutene known.

Rhodium-phosphite complexes catalyze the hydroformylation of linear olefins with terminal and internal double bonds, predominantly terminal hydroformylated products being formed, whereas branched olefins with internal double bonds are only converted to a small extent. When coordinated to a transition metal center, these phosphites result in catalysts of increased activity, but the service life of these catalyst systems is, among other things, because of the Hydrolysis sensitivity of the phosphite ligands, unsatisfactory. By using substituted bisaryldiols as starting materials for the phosphite ligands, as described in EP 0214 622 or EP 0472 071, considerable improvements could be achieved.

Rhodium complexes of these ligands are active hydroforming catalysts for α-olefins. US Pat. No. 4,668,651, US Pat. No. 4,748,261 and US Pat. No. 4,885,401 describe polyphosphite ligands with which olefins, but also 2-butene, can be reacted with good selectivity to give the terminally hydroformylated products. In US 5,312,996 bidentate ligands of this type are also used for the hydroformylation of butadiene.

Compared to PhospWnHganden, phosphite ligands are usually characterized by higher activities. In addition, their mostly simple and inexpensive manufacture is advantageous.

Phosphorus compounds of the benzodiazaphosphorinone type and benzoxazaphosphorinone are well known in the literature (see Phosphorus Sulfür Silicon Relat. Elem. 2000, 162, 81-218). Their syntheses and reactivities with ketones as well as their complexation on transition metals are described.

However, these compounds were not used in catalysis, neither as ligands nor as metal complexes.

Neda et al. describe in J. Fluorine Chem. 1995, 71, 65-74 the reaction of benzodiazaphosphorinone derivatives with fluorinated ketones under trimemylamine catalysis. However, the benzodiazaphosphorinone derivatives were not used in catalysis.

Fei et al. describe in Z. Anorg. Gen. Chem. 2000, 626, 1763-1772 the synthesis of bisphosphorus ligands with benzodiazaphosphorinone building blocks and the complexation on Pt complexes. Use in catalysis has not been reported.

Borkenhagen et al. report in Z. Naturforsch. B Chem. 1996, 51, 1627-1638 of chromium complexes with benzodiazaphosphorinone ligands. These complexes were not in the Catalysis used.

Neda et al. describe in Phosphorus, Sulfur Silicon Relat. Elem. 1996, 113, 287-294 the synthesis of benzoxazaphosphorinones and investigate the reactivity of these systems, but not in catalytic reactions.

Kuliev et al. investigated the reactivity of chlorobenzoxazaphosphorinones. The results are in Zh. Obshch. Khim. 1986, 56, 2797-8. The compounds were not used in catalysis.

In Chem. Ber. 1994, 127, 1579-86, Neda et al. u. a. from 2,2 '- [(l, l'-Biρhenyl) -2,2'- diylbis (oxy)] bis-benzoxazaphosphorinones and the complexation of gold. Neither the phosphorus compound itself nor the gold complex have been investigated in catalysis.

US Pat. No. 6,664,427 describes a hydroformylation process in which special bidentate phosphorus ligands which have two bivalent phosphorus atoms which are bonded to a -Hy <h-oxybenzoic acid amide or α-hydroxybenzoic acid imide group are used.

It is an object of the present invention to provide an improved process for the hydroformylation of olefins having at least one ethylenically unsaturated double bond. The activity in the conversion of α-olefins should increase the activity to aldehydes and in the case of olefins with internal double bonds both the activity and the regioselectivity to terminal aldehydes be increased.

It has surprisingly been found that hydroformylations of olefins in the presence of heteroacylphosphites according to the general formula (1)

(1)

which do not have two α-hydroxybenzoic amide groups, are improved in the desired manner.

The present invention therefore relates to a process for the hydroformylation of olefins, comprising the reaction of a monoolefin or monoolefin mixture having 2 to 25 carbon atoms with a mixture of carbon monoxide and hydrogen in the presence of a heteroacyl phosphite according to the general formula (1) or a corresponding complex with or several metals of the 4th to 10th group of the Periodic Table of the Elements

(1)

where R ¹ , R ² , R ³ , R ⁴ and q are each the same or different for a substituted or unsubstituted aHphatic, aHcyclic, aromatic, heteroaromatic, mixed aHphatic-aHcyclic, mixed aHphatic-aromatic, heterocyclic, mixed aHphatic-heterocyclic hydrocarbon radical with 1 up to 70 carbon atoms, H, F, Cl, Br, I, -CF ₃ , -CH ₂ (CF ₂ ) jCF ₃ with j = 0 - 9, -OR ⁵ , -COR ⁵ , -CO ₂ R ⁵ , -CO ₂ M, -SiR ⁵ ₃ , -SR ⁵ , -SO ₂ R ⁵ , -SOR ⁵ , -SO ₃ R ⁵ , -S0 ₃ M, -SO ₂ NR ⁵ R ⁶ , -NR ⁵ R ⁶ , -N = CR ⁵ R ⁶ , where R ⁵ and R ^{6 have the} same or different meanings of R ¹ and M is an alkali metal, formally half an alkaline earth metal, ammonium or phosphonium ion, x, y, z are independently O, NR ⁷ , S mean, where R ^{7 has} one of the meanings of q and x, y, z do not simultaneously stand for O, with the measure that if q has a residue that has a structural unit (6c)

, wherein the radicals R ¹ to R ^{4 have} the meaning of the formula (1), x ¹ , y ¹ , z ¹ independently of one another are O, NR ⁷ , S, where R ^{7 has} one of the meanings of q, T is an oxygen or is a radical NR ³⁰ , where R ^{30 has} one of the meanings of q, position a serves as a point of attachment, x and x ^{1 must} not be N at the same time and x must not be N if T is NR ³⁰ .

In preferred embodiments, q, R ¹ , R ² , R ³ and R ^{4 have} the meanings given for hydrocarbon radicals, but the radicals are unsubstituted with a number of carbon atoms from 1 to 50, in particular from 1 to 25.

Furthermore, R ⁵ , R ⁶ and R ^{7 are} preferably H, or an unsubstituted aHphatic or aromatic hydrocarbon radical having 1 to 25 carbon atoms.

It is possible that the two adjacent radicals R ¹ to R ⁴ (R ¹ and R ² , R ² and R ³ , R ³ and R ⁴ ) together form an newly substituted or unsubstituted aromatic, heteroaromatic, non-aromatic, mixed aromatic-non-aromatic or mixed heteroaromatic-aliphatic ring system form.

In a preferred heteroacyl phosphite according to formula (1), the radical q is composed of aromatics or heteroaromatics which are unsubstituted or with at least one radical selected from aHphatic, aHcyclic, aromatic, heteroaromatic, mixed aHphatic-aHcyclic, mixed aHphatic-aromatic, heterocycHschen, mixed aliphatic -hetero- cyclic hydrocarbon radicals with 1 to 25 carbon atoms, F, Cl, Br, I, -CF ₃ , -CH ₂ (CF ₂ ) _j CF ₃ with j = 0 - 9, -OR ⁵ , -COR ⁵ , -CO ₂ R ⁵ , -CO ₂ M, -SiR ⁵ ₃ , -SR ⁵ , -SO ₂ R ⁵ , -SOR ⁵ , -SO ₃ R ⁵ , -SO ₃ M, -SO ₂ NR ⁵ R ⁶ , -NR ⁵ R ⁶ , or -N = CR ⁵ R ⁶ , where R ⁵ , R ⁶ and M are as previously defined.

In a further process variant, a heteroacyl phosphite of the formula (1) is used, the rest q of which consists of the residues -WR, where W is a double-bonded substituted or unsubstituted aliphatic, aHcyclic, mixed aHphatic-aHcyclic, heterocyclic, mixed aliphatic-heterocyclic, aromatic, heteroaromatic, mixed aUphatic-aromatic hydrocarbon radical with 1 to 50 carbon atoms and the radical R is an -OR ⁵ , -NR ⁵ R ⁶ , phosphite, phosphonite, phosphite, phosphine or heteroacyl phosphite or a radical according to formula (6c), where R ⁵ and R ^6, identical or different, has one of the meanings of R ¹ , but preferably, independently of one another, denotes H, unsubstituted aHphatic and aromatic hydrocarbon radical having 1 to 25 carbon atoms.

In a preferably used heteroacyl phosphite of the formula (1) which has a radical q with -W-R, W represents a radical of the formula (2)

where R ⁸ , R ⁹ , R ¹⁰ , R ¹¹ , R ¹² , R ¹³ , R ¹⁴ and R ¹⁵ each have the same or different meanings of q, preferably independently of one another, for a monovalent substituted or unsubstituted aHphatic, aHcyclic, aromatic, heteroaromatic, mixed aphatic-aHcycHschen, mixed aHphatic-aromatic, heterocycHschen, mixed aliphatic-heterocyclic hydrocarbon radicals with 1 to 50 carbon atoms, H, F, Cl, Br, I, -CF ₃ , -CH ₂ (CF ₂ ) _j CF ₃ with j = 0-9, -OR ⁵ , -COR ⁵ , -CO ₂ R ⁵ , -CO ₂ M, -SiR ⁵ ₃ , -SR ⁵ , -SO ₂ R ⁵ , -SOR ⁵ , -SO ₃ R ⁵ , -SO ₃ M, -SO ₂ NR ⁵ R ⁶ , -NR ⁵ R ⁶ , -N = CR ⁵ R ⁶ , where R ⁵ and R ^{6 are} independently selected from H, monovalent substituted or unsubstituted aphatic and aromatic hydrocarbon radicals having 1 to 25 carbon atoms and M is an alkali metal U, formally half an alkaline earth metal, ammonium or phosphonium ion.

t stands for a radical CR ¹⁶ R ¹⁷ , SiR ¹⁶ R ¹⁷ , N ¹⁶ , O or S. R ¹⁶ and R ¹⁷ are defined as R ⁵ or R ⁶ , n stands for 0 or 1 and positions a and b serve as attachment points.

It is possible that two adjacent radicals R ⁸ to R ¹⁵ together form an newly substituted or unsubstituted aromatic, heteroaromatic, aUphatic, mixed aromatic-aliphatic or mixed heteroaromatic-aliphatic ring system.

In a further heteroacyl phosphite of the formula (1) which can be used in the process, W has the meaning of the formula (3)

where R ¹⁸ , R ¹⁹ , R ²⁰ , R ²¹ , R ²² and R ²³ each have the same or different meanings of q, preferably independently of one another, for a monovalent, substituted or unsubstituted aHphatic, aHcyclic, aromatic, heteroaromatic, mixed aHphatic aHcycHschen, mixed aHphatic-aromatic, heterocyclic, mixed aHphatic-heterocyclic hydrocarbon residues with 1 to 50 carbon atoms, H, F, Cl, Br, I, -CF ₃ , -CH ₂ (CF ₂ ) jCF ₃ with j = 0 - 9, -OR ⁵ , -COR ⁵ , -CO ₂ R ⁵ , -CO ₂ M, -SiR ⁵ ₃ , -SR ⁵ , -SO ₂ R ⁵ , -SOR ⁵ , -S0 ₃ R ⁵ , -SO ₃ M, - SO ₂ NR ⁵ R ⁶ , -NR ⁵ R ⁶ , -N = CR ⁵ R ⁶ , where R ⁵ and R ^{6 are} independently selected from H, monovalent substituted or unsubstituted aHphatic and aromatic hydrocarbon radicals having 1 to 25 carbon atoms and M is an alkali metal, formally half an alkaline earth metal, ammonium or phosphonium ion. Positions a and b in formulas 2 and 3 serve as connecting points to the radical R and to z according to formula (1).

t stands for a radical CR ¹⁶ R ¹⁷ , SiR ¹⁶ R ¹⁷ , NR ¹⁶ , O or S, where R ¹⁶ and R ^{17 are defined} as R ⁵ or R ⁶ and the positions a and b serve as connecting points.

Again, it is possible for two adjacent radicals R ¹⁸ to R ^{23 to} jointly form an annexed substituted or unsubstituted aromatic, heteroaromatic, aUphatic, mixed aromatic-aliphatic or mixed heteroaromatic-aliphatic ring system.

In a further variant of the method according to the invention, the

Heteroacylphosphites of the formula (1) which have a radical q with -W-R, the W for one

The rest according to formula (4)

where u stands for a divalent group, selected from residues of the formulas (5a), (5b) and (5c)

in which R ²⁴ , R ²⁵ , R ²⁶ and R ²⁷ each have the same or different meanings of q, preferably independently of one another for a substituted or unsubstituted Aphatic, acyclic, aromatic, heteroaromatic, mixed aphatic-aromatic, mixed aphatic-aromatic, heterocyclic, mixed aphatic-heterocyclic hydrocarbon radicals with 1 to 50 carbon atoms, H, F, Cl, Br, I, - CF ₃ , -CH ₂ (CF ₂ ) _j CF ₃ with j = 0-9, -OR ⁵ , -COR ⁵ , -CO ₂ R ⁵ , -CO ₂ M, -SiR ⁵ ₃ , -SR ⁵ , -SO ₂ R ⁵ , -SOR ⁵ , -SO ₃ R ⁵ , -SO ₃ M, -SO ₂ NR ⁵ R ⁶ , -NR ⁵ R ⁶ , -N = CR ⁵ R ⁶ , where R ⁵ and R ⁶ independently of one another from H, monovalent substituted or unsubstituted aHphatic and aromatic hydrocarbon radicals with 1 to 25 carbon atoms are selected and M is an alkali metal, formally half an alkaline earth metal, ammonium or phosphonium ion and the positions a and b serve as connecting points for u.

Here, too, it is possible that two adjacent radicals R ²⁴ to R ²⁷ together form an newly substituted or unsubstituted aromatic, heteroaromatic, aUphatic, mixed aromatic-aliphatic or mixed heteroaromatic-aliphatic ring system.

In a preferably used heteroacyl phosphite of the formula (1) which has a radical q with -W- R, R represents radicals according to the general formulas (6a), (6b) and (6c):

where R ²⁸ and R ^29, each identically or independently of one another, have one of the meanings of R ¹ , but preferably for a monovalent unsubstituted aphatic, acyclic, aromatic, heteroaromatic, mixed aphatic-acylic, mixed aphatic-aromatic, heterocyclic, mixed aphatic-heterocyclic Are hydrocarbon radicals with 1 to 50 carbon atoms, m = 0 or 1, n = 0 or 1, k = 0 or 1, 1 = 0 or 1 and the position a serves as a connecting point. R ¹ , R ² , R ³ , R ⁴ , q, W, x, y, z have the meanings mentioned and where the radicals R ¹ to R ⁴ have the meaning according to formula (1), x ¹ , y ¹ , z ¹ independently of one another denote O, NR ⁷ , S, where R ^{7 has} one of the meanings of q, T is an oxygen or a radical NR ³⁰ , where R ³⁰ has one of the meanings of q, position a serves as a starting point, and in the FaU of R equal to 6c, x and x ^{1 must} not be N at the same time and x must not be N if T is NR ³⁰ .

Each two adjacent radicals R ²⁴ to R ²⁷ together can form an annexed, substituted or unsubstituted aromatic, heteroaromatic, aromatic, mixed aromatic-aromatic or mixed heteroaromatic-aromatic ring system.

The following phosphite Ugands mentioned by way of example can be used in the process according to the invention, where Me stands for a methyl, ⁴ Bu for a tertiary-butyl and Ph for a phenyl group.

Heteroacylphosphites according to formula (1) can by a sequence of reactions of

Phosphorus halides with alcohols, amines, thiols, carboxylic acids, carboxamides,

Thiocarboxylic acids, α-hydroxyarylcarboxylic acids, α-Hy (j ^ oxyarylcarboxamides, α-hydroxyarylthiocarboxylic acids, α-aminoarylcarboxylic acids, α-ammoaryrylcarboxamides, α-Aminoarylthiocarboxylic acids, α-mercaptoarylcarboxylic acids, α-mercaptoarylcarboxylic acid arnids and / or oc-mercaptoarylthiocarboxylic acids, in which halogen atoms on the phosphorus are exchanged for oxygen, nitrogen and / or sulfur groups. The basic procedure is exemplified on a way to compounds according to the general formula (1):

In a first step, a compound of formula (Ia) with a phosphorus trihalide P (Hal) ₃ , such as PC1 ₃ , PBr ₃ and PJ ₃ , preferably phosphorus trichloride PC1 ₃ , without base or in the presence of a base which is in equivalent or catalytic Amounts used are converted to the compound of formula (Ib).

In a second reaction step, the compound (Ib) is reacted with an alcohol HO-q or with an amine HN (R ⁷ ) -q or with a thiol HS-q without a base or in the presence of a base which is equivalent or catalytic Amounts are used to obtain the desired heteroacyl phosphite according to formula (1).

(1b) he radicals R to R, R and x, y and q have the meanings already mentioned. Since the alcohols, amines, thiols or carboxylic acid derivatives used and their derivatives are often solid, the reactions are generally carried out in solvents. Non-protic solvents which do not react with the alcohols, amines, thiols or carboxylic acid derivatives or with the phosphorus compounds are used as solvents. Suitable solvents are, for example, tetrahydrofuran, ethers such as diethyl ether or MTBE (methyl tertiary butyl ether) or aromatic hydrocarbons such as toluene.

The reaction of phosphorus halides with alcohols, amines, thiols or carboxylic acid derivatives gives rise to hydrogen halide which escapes by heating or is bound in equivalent or in catalytic amounts by added bases. Examples of bases are tertiary amines such as triethylamine, pyridine or N-methylpyrroUdinone. In some cases it is also sensible to convert the alcohols into metal alcoholates before the reaction, for example by reaction with sodium hydride or butylium.

The solvents used must be largely free of water and oxygen; solvents with a water content of 0 to 500 ppm are preferred, particularly preferably 0 to 250 ppm. The water content can be determined, for example, by the Karl Fischer method.

The solvent can be dried by distilling the solvent using a suitable drying agent or by flowing the solvent through a cartridge or column filled with 4 Å molecular sieve, for example.

The synthesis steps preferably take place at temperatures from -80 ° C to 150 ° C; in most cases it has proven useful to work at temperatures from -20 ° C to 110 ° C, particularly preferably at 0 ° C to 80 ° C.

The metals of the 4th, 5th, 6th, 7th, 8th, 9th or 10th group of the Periodic Table of the Elements can be used in the process according to the invention. Examples of suitable metals are

Rhodium, cobalt, iridium, nickel, PaUadium, platinum, iron, ruthenium, osmium, chrome, Molybdenum and tungsten. Rhodium is particularly preferably used as the metal. The catalyst metals can be introduced into the reaction in the form of salts or complexes; in the case of rhodium, for example, rhodium carbonyls, rhodium nitrate, rhodium chloride, Rh (CO) ₂ (acac) (acac = acetylacetonate), rhodium acetate, rhodium octanoate or rhodium nonanoate are suitable.

The active catalyst species is formed from the heteroacylphosphite ligands according to formula (1) and the catalyst metal under the reaction conditions. In hydroformylation, a carbonyuide hydride heteroacyl phosphite complex is formed upon contact with synthesis gas. The heteroacyl phosphites and optionally other ligands can be added to the reaction mixture in free form together with the catalyst metal (as a salt or complex) in order to generate the active catalyst species in situ. It is also possible to use a heteroacylphosphite metal complex which complies with the abovementioned. Heteroacylphosphitliganden and contains the catalyst metal to use as a precursor for the actual catalytically active complex. These heteroacylphosphite metal complexes are produced by reacting the corresponding catalyst metal of the 4th to 10th group in elemental form or in the form of a chemical compound with the heteroacylphosphite ligand. It may be advantageous if an excess of heteroacylphosphite Ugand of formula (1) is used, so that heteroacylphosphite Ugand is present as a free ligand in the cycloformylation mixture.

In addition to the ligands of the formula (1), other ligands for the metal atom used can be used in the process according to the invention.

Phosphorus-containing ligands, preferably phosphines, bisphosphites, phosphorites or phosphinites, can be used as additional ligands present in the reaction mixture.

Examples of such ligands are:

Phosphines: triphenylphosphine, tris (p-tolyl) phosphine, tris (m-tolyl) phosphine, tris (o-tolyl) phosphine, tris-methoxyphenyl) phosphine, tris (p-dimemylarmnophenyl) phosphine, tricyclohexylphosphine, tricyclopentylphiemylnophylphosplnospin , Trir (l-naphthyl) phosphine, Tribenzylphosphine, tri-n-butylphosphMn, tri-t-butylphosphine.

Phosphites: trimethyl phosphite, triethyl phosphite, tri-n-propyl phosphite, tri-i-propyl phosphite, tri-n-butyl phosphite, tri-i-butyl phosphite, tri-t-butyl phosphite, tris (2-ethyuxexyl) phosphite, tri-phenyl phosphite, tris ( 2,4-di-t-butylphenyl) phosphite, tris (2-t-butyl-4-methoxyphenyl) phosphite, tris (2-t-butyl-4-methylph yl) phosphite, tris (p-cresyl) phosphite.

Phosphonites: Memylώethoxyphosphin, Phenyldimethoxyphosphin, Phenyldiphenoxyphosphin, 2-Phenoxy-2H-dibenz [c, e] [l, 2] oxaphosphorin and its derivatives, in which the hydrogen atoms are completely or partially replaced by alkyl and / or aryl groups or halogen atoms.

Common phosphinite units are diphenyl (phenoxy) phosphine and its derivatives diphenyl (methoxy) phosphine and diphenyl (emoxy) phosphine.

The heteroacylphosphites or heteroacylphosphite metal complexes can be used in processes for the hydroformylation of olefins, preferably with 2 to 25 carbon atoms, particularly preferably from 6 to 12 and very particularly preferably from 8, 9, 10, 11 or 12 carbon atoms, to give the corresponding aldehydes. Heteroacylphosphite complexes with metals from the 8th group are preferably used as catalyst precursors.

1 to 500 mol, preferably 1 to 200 mol and particularly preferably 2 to 50 mol of the heteroacyl phosphite according to the invention are preferably used per mol of MetaU of the 8th group of the periodic table. Fresh heteroacyl phosphite Ugand can be added at any point in the reaction to adjust the concentration of free heteroacyl phosphite, i.e. not coordinated with the metal to keep constant.

The concentration of the MetaU in the reaction mixture is preferably in the range from 1 ppm to 1000 ppm, preferably in the range from 5 ppm to 300 ppm, based on the total weight of the reaction mixture. The hydroformylation reactions carried out with the heteroacylphosphites of the formula I or the corresponding metal complexes can be carried out according to known regulations, such as, for. B. in J. FALBE, "New Syntheses with Carbon Monoxide", Springer Verlag, Berlin, Heidelberg, New York, page 95 ff., (1980). In the presence of the catalyst, the olefin compound (s) is (are) reacted with a mixture of CO and H ₂ (synthesis gas) to give the aldehydes which are richer by one carbon atom.

The reaction temperatures are preferably from 40 ° C to 180 ° C and preferably from 75 ° C to 140 ° C. The pressures at which the hydroforming takes place are preferably from 1 to 300 bar synthesis gas and preferably from 10 to 64 bar. The molar ratio between hydrogen and carbon monoxide (H ₂ / CO) in the synthesis gas is preferably from 10/1 to 1/10 and preferably from 1/1 to 2/1.

The catalyst or ligand is homogeneously dissolved in the hydroforming mixture consisting of starting materials (olefins and synthesis gas) and products (aldehydes, alcohols, high boilers formed in the process). Optionally, a solvent can also be used.

Due to their relatively high molecular weight, the heteroacyl phosphites have a low volatility. They can therefore be easily separated from the more volatile reaction products. They are sufficiently soluble in common organic solvents.

The starting materials for the hydroformylation are olefins or mixtures of olefins having 2 to 25 carbon atoms with a terminal or internal C = C double bond. Preferred starting materials are generally α-olefins such as propene, 1-butene, 2-butene, 1-hexene, 1-octene, and dimers and trimers of butene (mixtures of isomers).

The hydroformylation can be carried out continuously or batchwise. Examples of technical designs are stirred kettles, bubble columns, jet nozzle reactors, tubular reactors or loop reactors, some of which can be cascaded and or can be provided with internals. The reaction can be carried out continuously or in several stages. The separation of the resulting aldehyde compounds and the catalyst can be carried out by a conventional method, such as fractionation, extraction, nanofutration with appropriate membranes. Technically, this can be done, for example, via a destiUation, a vapor evaporator or a thin-film evaporator. This applies in particular if the catalyst is separated from the lower-boiling products in solution in a high-boiling solvent. The separated catalyst solution can be used for further hydroforming. When using lower olefins (e.g. propene, butene, pentene) it is also possible to discharge the products from the reactor via the gas phase.

The present invention furthermore relates to processes for carbonylation, hydrocyanation, isomerization of olefins or amidocarbonylation in the presence of heteroacylphospliins of the formula (1) or their complexes, with metals of the 4th to 10th group of the periodic table of the elements where R ¹ , R ² , R ³ , R ⁴ and q each identically or differently for a substituted or unsubstituted aHphatic, aHcyclic, aromatic, heteroaromatic, mixed aHphatic-aHcycHschen, mixed aliphatic-aromatic, heterocyclic, mixed aHphatic-heterocyclic hydrocarbon radical with 1 to 70 carbon atoms, H, F , Cl, Br, I, -CF ₃ , -CH ₂ (CF ₂ ) jCF ₃ with j = 0-9, -OR ⁵ , -COR ⁵ , -CO ₂ R ⁵ , -C0 ₂ M, -SiR ⁵ ₃ , -SR ⁵ , -SO ₂ R ⁵ , -SOR ⁵ , -SO ₃ R ⁵ , -SO ₃ M, -SO ₂ NR ⁵ R ⁶ , -NR ⁵ R ⁶ , -N = CR ⁵ R ⁶ , where R ⁵ and R ^6, identical or different, have one of the meanings of R ¹ and M is an AlkaHmetaU-, formally half a ErcklkaUmetaU-, ammoni is um- or phosphonium ion, x, y, z are independently O, NR ⁷ , S, where R ^{7 has} one of the meanings of R ¹ .

The radicals q, R ¹ , R ² , R ³ , R ⁴ , x, y and z have the meanings mentioned. The preferred variations of compounds of the formula (1) mentioned for the hydroformylation apply analogously to these reactions.

The following examples are intended to illustrate the present invention. In the case of examples, standard ScMenk technology was used under protective gas. The solvents were dried over suitable drying agents before use.

Example 1; Representation of ligand (D)

a) Representation of the Cl-phosphorus building block (Φ)

To a suspension of 20 g (93.79 mmol) diphenylamine-2-carboxylic acid in toluene (80 ml) slowly add 17.65 ml of a 5.315 M (stands for molar therefore mol / 1) standard solution of phosphorus trichloride in toluene (93 , 79 mmol) was added dropwise. After the addition of PCl ₃ is slowly warmed to 90 ° C. in a water bath. The mixture is stirred at this temperature until no more gas evolution can be observed (about 5 h), heated under reflux for a further 1 h and filtered. The feed cake is washed with 2 x 10 ml of cold toluene. The combined feed rates are evaporated to dryness in vacuo and taken up in 60 ml of dichloromethane. Filtration, evaporation of the solvent in vacuo and drying in an oil pump vacuum give the spectroscopically pure Cl-P compound (Φ) in the form of a dark red-brown syrupy liquid. Yield: 18.0 g (61%). ³¹ P {1H} -NMR (CD ₂ C1 ₂ ) 5135.1 ppm.

b) Representation of the hydroxyphosphite compound (Δ)

The compound (Δ) was as in EP 1 201 675 and as in D. Selent, D. Hess, K-D. Wiese, D. Röttger, C. Kunze, A. Börner, Angew. Chem. 2001, 113, 1739.

c) Presentation of (D)

To a solution of 2.721 g (3.653 mmol) of the hydroxyphosphite (Δ) in THF (36 ml) are added at -20 ° C with stirring 11.4 ml of a 0.32 M (molar) solution of "-ButyUithium in hexane ( 3.653 mmol). The resulting mixture is slowly added to a solution of 1.014 g (3.653 mmol) of the compound (beschriebenen) described in a) in THF (15 ml) at room temperature. The red-brown solution is stirred for 4 h, the solvent is evaporated in vacuo and the residue obtained is stirred up with hexane (60 ml). It is filtered and the filter cake extracted with diethyl ether (50 ml). The extraction solution is stored for 1 day at 5 ° C., filtered, the feed cake washed with hexane (18 ml) and dried for 2 hours at 60 ° C. at 0.1 mbar. Yield: 1.593 g (44%). Elemental analysis (calc. For 986.08 g mol): C 68.73 (69.43), H 6.76 (6.64), P 6.09 (6.28), N 1.48 (1.42)%. FAB-MS: m / e 985 (4%, M ⁺ ), IAA (30%), 727 (100%). ³¹ P NMR (toluene-D ₈ ): δll4.9 (d, J _PP = 22.2 Hz), 117.4 (d, J _PP = 5.5 Hz), 138.9 (d, J _PP = 22.2 Hz), 141.2 (d, J _PP = 5.5 Hz) ppm.

Example 2: Representation of ligand (E)

a) Representation of the Cl-phosphorus building block (T)

(O

28.24 ml of a 5.315 M standard solution of phosphorus trichloride in toluene (145.84 mmol) are slowly added dropwise to a suspension of 20 g (145.83 mmol) of anthranilic acid in toluene (105 ml) at room temperature. After the addition of PC1 ₃ is slowly warmed to 90 ° C. in a water bath. The mixture is stirred at this temperature until gas evolution can no longer be observed (about 5 h) and heated under reflux for a further 1 h. The residue is then decanted and the toluene is separated off in vacuo. The residue is taken up in dichloromethane (80 ml), filtered and the solution is concentrated to 50% of the starting volume. After 3 days' storage at 5 ° C, the condensed fine crystalline yellow substance is filtered off at -15 ° C and then dried in vacuo at room temperature. Yield: 7.76 g (26%) of spectroscopically pure Cl-P compound ³¹ P { ¹ H} -NMR (CD ₂ C1 ₂ ) 5135.1 ppm.

b) Representation of the hydroxyphosphite compound (Δ) For the representation of (Δ) compare the information on the synthesis of the ligand (D).

c) Presentation of (E)

4.1 g of hydroxyphosphite (Δ) (5.50 nmol) in THF (53 ml) are mixed at 3.44 ml at -20 ° C. 1.6 M solution of n-butyuithium (5.50 mmol) deprotonated. The solution of the lithium salt thus obtained is added dropwise with stirring to a solution of 1.108 g (5.50 mmol) of the compound (F) described in a) in THF (23 ml). After stirring for 16 h at room temperature, the mixture is evaporated to dryness in vacuo and the residue obtained is extracted with boiling hexane (80 ml) until only traces (Δ) are present (recognizable by the sharp phosphor signal at 140.7 ppm in CD ₂ C1 ₂ ). The residue is extracted with diethyl ether (50 ml). The ether filtrate is concentrated and 2.0 g (40%) of a yellow, spectroscopically pure solid are obtained. P analysis (calc. For 909.99 g mole): P 6.95 (6.81)%. ³¹ P {1H} -NMR (CD ₂ C1 ₂ ): δ 118.0, 124.0, 136.2, 141.8 ppm FAB-MS: e / m 910 (40%, Mf), 727 (100% ).

Example 3; Representation of ligand (H)

a) Representation of the Cl-phosphorus building block (Φ)

The Cl-phosphorus building block (Φ) is prepared as described in Example 1.

b) Representation of the hydroxyphosphite compound (Σ)

The compound (Σ) was as in EP 1 201 675 or as in D. Selent, D. Hess, K.-D. Wiese, D. Röttger, C. Kunze, A. Börner, Angew. Chem. 2001, 113, 1739.

c) Presentation of Ligand (H)

The representation is analogous to the synthesis of ligand (D). The reaction was carried out with 2.518 g (2.97 mmol) of hydroxyphosphite (Σ), an equimolar amount of n-butyl lithium, used as a 0.32 M solution in hexane, and 0.825 g (2.97 mmol) of the compound (Φ) in a total of 50 ml THF. After working up, 1.51 g (47% of theory) of the spectroscopically pure ligand (H) are isolated in the form of a light brown solid. Elemental analysis (calc. For 1090.41 g mole): C 76.10 (76.00), H 8.46 (8.23), N 1.31 (1.29) P 5.68 (5.68)%. ³¹ P {1H} -NMR (CD ₂ C1 ₂ ): δ 113.1, 116.0, 141.7 ppm. CI-MS (isobutane): m / e 1090 (65%, "), 832 (100%).

Example 4: Representation of ligand ()

The preparation and processing was carried out analogously to the synthesis of (E). Starting from 2.418 g (2.847 mmol) of hydroxyphosphite compound (Σ), an equimolar amount of t-butyuithium, used as a 0.32 M solution in hexane, and 0.573 g (2.847 mmol) of the compound used for the synthesis of (E) () in a total of 55 ml THF, 0.837 g (29% of theory) of the spectroscopically pure ligand (J) is isolated in the form of a yellow solid. Elemental analysis (calc. For C ₆₃ H ₈₅ O ₆ P ₂ N = 1014.31 g / mol): C 74.86 (74.60), H 8.43 (8.45), N 1.26 (1, 38) P 5.44 (6.10)%. ³¹ P {1H} -NMR (CD ₂ C1 ₂ ): δ 119.5, 123.8, 140.0, 143.0 ppm EI- MS: m / e 1015 (13%, MT), 833 (83% ), 440 (100%).

Hydroformylation Examples 5 to 15

The hydroforming tests were carried out in a 200 ml autoclave from Buddeberg, Mannheim, equipped with constant pressure, gas flow measurement, gassing stirrer and pressure pipette. For the experiments, the following rhodium solutions in the form of [acacRh (COD)] (acac = acetylacetonate anion, COD = cycloocta-l, 5-diene) as a catalyst precursor were introduced into toluene in an autoclave under an argon atmosphere: For experiments with 14 mass% ppm rhodium 10 ml of a 0.604 mM solution, for experiments with 28 mass ppm rhodium 20 ml of a 0.604 mM solution, for experiments with 140 mass ppm rhodium 10 ml of a 6.04 mM solution. The corresponding amount of the phosphite compound dissolved in toluene, generally 5 ligand equivalents per rhodium, was then mixed in. By adding more toluene, the initial volume of the catalyst solution was increased to 41 ml for the reaction with 1-octene or the «-octenes (= mixture of 1-octene, 2-octene, 3-octene and 4-octene with approx. 3% 1 Octene portion) and set to 51.5 ml for the reaction with 2-pentene. 15 ml of 1-octene or n-octene or 4.5 ml of 2-pentene were added to the pressure pipette; the mass of the olefin had been determined beforehand. After exchanging the argon atmosphere by purging with synthesis gas (CO / H ₂ = 1: 1), the mixture was heated to the following temperatures at a synthesis gas pressure of 11-13 bar (33 bar for 1-octene) with stirring (1500 rpm): a) Experiments with 1-octene: 100 ° C, b) Experiments with n-octenes: 130 ° C, c) Experiments with 2-pentene: 120 ° C. After the reaction temperature had been reached, the synthesis gas pressure was increased to 20 bar (50 bar for 1-octene) and the olefin was added. The reaction was carried out at constant pressure (pressure regulator from Bronkhorst, NL) over the reaction times given in Table 1. After the test period, the autoclave was cooled to room temperature, decompressed and flushed with argon while stirring. 1 ml portions of the reaction mixtures were removed immediately after the stirrer was switched off, diluted with 5 ml pentane and analyzed by gas chromatography.

* Ligand / rhodium ratio = 1 0: 1

Comparative Example 16 The hydroforming test was carried out in a 100 ml Parr autoclave equipped with a constant pressure, gas flow measurement, stirrer and pressure pipette. For the experiments, a solution of rhodium in the form of rh nonanoate as catalyst precursor was introduced into toluene in an autoclave under an argon atmosphere: 3.1 ml of a 0.734 mM solution were used for experiments with 40 ppm by mass of rhodium. Then the corresponding amount of 5 ligand equivalents per rhodium of the phosphite compound X dissolved in toluene was added. The initial mass of the catalyst solution was adjusted to 29 g for the reaction with 1-octene or the n-octenes (= mixture of 1-octene, 2-octene, 3-octene and 4-octene) by adding further toluene. 29 g of 1-octene or w-octene were added to the pipette. The mixture was heated to 120 ° C. at a synthesis gas pressure of 11-13 bar with stirring (1000 rpm).

After the reaction temperature had been reached, the synthesis gas pressure was raised to 20 bar and the olefin was added. The reaction was carried out at constant pressure (pressure regulator from Bronkhorst, NL) over the reaction times given in the table. After the test period, the autoclave was cooled to room temperature, decompressed and emptied. Samples were taken during the reaction, diluted with 1 ml of pentane and analyzed by gas chromatography.

The comparison experiment gives an n-selectivity at 120 ° C, which e.g. is comparable to Examples 1 and 2. Despite the higher reaction temperature, the yield is significantly lower at 46.2% (Table 1).

Comparative Example 17

Analogous to experiments 5 and 6, example experiments 5b and 6b were carried out with a ligand of the formula Z. The preparation of the ligand Z can e.g. B. DE 100 53 272 can be removed. Examples 5b and 6b consistently show lower n-selectivities observed than obtained when using the ligands according to the invention (Table 2) -

Table 2: Comparative examples with the ligand Z

* Ligand / rhodium ratio = 10: 1

Example 18: Representation of ligand (M)

a) Representation of the P-Cl module (Ω)

17.2 ml of a 2.73 M solution (46.85 mmol) of phosphorus trichloride in toluene are added dropwise at room temperature to a suspension of 9.99 g (46.85 mmol) of SaUzylanüid in toluene (42 ml). The mixture is then heated under reflux for 5.5 h, filtered after cooling and concentrated to dryness in vacuo. The product (Ω) thus obtained is approx. 95% pure by NMR spectroscopy and was used as received for the further synthesis. The purity can be further increased by recrystallization from toluene. Yield: 12.23 g (93% of theory). ³¹ P {1H} NMR (CD ₂ Cl ₂ ): δ 139.6 ppm.

b) Representation of the hydroxyphosphite compound (Δ)

For the presentation of (Δ) compare the information on the synthesis of the ligand (D).

c) Representation of the ligand (M)

To a solution of 3.065 g (4.114 mmol) of the hydroxyphosphite (Δ) in THF (50 ml) is added an equimolar amount of “butyutium in the form of a 0.32 M solution in hexane at -20 ° C. with stirring. The mixture is stirred for a further 15 min, then allowed to warm to room temperature and the solution thus obtained is added at 0 ° C. to a solution of 1.20 g (4.32 mmol, approx. 5% excess) of the Cl-phosphorus compound in THF (20 ml ). After warming to room temperature, the mixture is stirred for 16 h and the solvent is removed in vacuo. The remaining residue is extracted first with 3 × 20 ml of hexane and then with 50 ml of boiling toluene. Concentration of the toluene filtrate in half, additions of 25 ml of hexane and storage at 5 ° C. for several days gave a beige-colored precipitate. It is filtered, washed with hexane (2x5ml) and dried at 60 ° C bath temperature in an oil pump vacuum. Yield: 2.23 g (55%). Elemental analysis (calc. For C ₅₇ H ₆₅ OιoP ₂ N = 986.08 g / mol): C 70.49 (69.43), H 6.64 (6.57), N 1.38 (1.42) %. 31 PD {f 1Η} NMR (CD ₂ C1 ₂ ): δ 112.2, 113.8, 115.2, 140.1, 141.4, 143.2 ppm

Example 19: Representation of ligand (D

The presentation is analogous to ligand (M).

2.957 g (3.482 mmol) of the hydroxyphosphite (Σ) (see Example 3), an equimolar amount of “-butylHthium in the form of a 0.32 M solution and 1.015 g (3.656 mmol) of those used for the synthesis of (M) Cl-phosphorus compound used. For working up, the reaction mixture is evaporated to dryness, the residue is stirred with hexane (65 ml), filtered and the solvent is removed in vacuo. Drying at 60 ° C bath temperature in an oil pump vacuum gives 3.615 g (94%) of the target compound. Elemental analysis (calc. For C ₆₉ H ₈₉ O ₆ P ₂ N = 1090.41 g / mol): C 75.68 (76.00), H 8.21 (8.23), N 1.30 (1, 29) P 5.20 (5.68)%. ^3l P {1H} -NMR (CD ₂ C1 ₂ ): δ 112.4, 115.4, 141.9 ppm.

Example 20: Representation of ligand P

a) Representation of the P-Cl building block (Ξ)

To a suspension of 20.23 g (69.44 mmol) of 3-hydroxy-naphthoe-2-carboxylic acid 2-ethylaniHd in toluene (80 ml), 18.5 ml of a 3.747 M solution (69, 44 mmol) of phosphorus trichloride in toluene. The mixture is then heated under reflux for 5 h and concentrated to dryness in vacuo. The brown residue formed is taken up in dichloromethane (60 ml). After filtration, the solvent is evaporated in vacuo and the residue is dissolved in warm toluene (50 ml). The crystal mass formed after storage for several days at 5 ° C. is filtered off, washed with cold toluene (10 ml) and dried at 60 ° C. bath temperature in an oil pump vacuum. The product (Ξ) obtained in this way is pure by NMR spectroscopy. Yield: 13.18 g (60% of theory. Elemental analysis (calc. For C ₉ H ₅ NO ₂ PCl = 355.76 g mol): C 64.48 (64 , 15), H 4.13 (4.25), N 3.89 (3.94), P 8.73 (8.71), Cl 9.88 (9.97)%.). ³¹ P {1H} -NMR (CD ₂ C1 ₂ ): δ 138.2, 139.4 ppm.

b) Representation of the hydroxyphosphite bond (Δ)

c) Representation of Ligand (P)

The reaction is carried out with 3.078 g (4.133 mmol) of the hydroxyphosphite (Δ), 12.9 ml of a 0.32 M solution of "-ButyUithium in hexane (4.133 mmol) and 1.47 g (4.133 mmol) of the Cl-phosphorus compound ( Ξ). After the solvent had been removed in vacuo, the syrupy residue was extracted first with hot hexane (100 ml) and then at room temperature with toluene (40 ml). Half of the hexane filtrate is concentrated and stored for 3 days at room temperature. The precipitate formed is filtered off, washed with cold hexane (10 ml) and dried at 60 ° C. in vacuo. The toluene filtrate is evaporated to dryness. The solid obtained is spectroscopic to that obtained from hexane identical. Yield: 2.42 g (55%). Elemental analysis (calc. For C ₆₃ H ₇₁ NOι ₀ P ₂ = 1064.20 g / mol): C 71.05 (71.11), H 7.01 (6.72), N 1.42 (1.32 ) P 5.55 (5.82)%). CI-MS (isobutane): m / e 1064 (18%, ^{1 "} ), 783 (12%), 745 (85%), 677 (60%). ³¹ P {1H} -NMR (CD ₂ C1 ₂ ) : δ 112.2, 113.3, 113.8, 114.2, 115.6, 116.3, 139.8, 141.1, 141.6, 142.2, 143.0, 143.6 ppm

Example 21: Representation of ligand (O)

The reaction is carried out with 3.144 g (3.7 mmol) of the hydroxyphosphite (Σ), 11.6 ml of a 0.32 M solution of “-butylUthium in hexane (3.7 mmol) and 1.316 g of the Cl-phosphorus compound (Ξ) first carried out analogously to the ligand (M). After stirring for 16 h at room temperature, the mixture is heated at 60 ° C. for a further 5 h, the solvent is then removed in vacuo and the residue is taken up in hexane (60 ml) and filtered. Concentration of the solution to half the volume and standing overnight at 5 ° C. gives a crystalline precipitate, which is filtered off, washed with 10 ml of cooled hexane and dried at 60 ° C. in vacuo. Yield: 3.05 g (71% of theory). Elemental analysis (calc. For 1168.52 g / mol): C 77.30 (77.09), H 8.52 (8.19), N 1.35 (1.20)%. CI-MS (isobutane): m / e 1168 (30%, Mf), 850 (51%), 833 (84%), 731 (81%), 441 (100%). ³¹ P {1H} -NMR (CD ₂ C1 ₂ ): δ 112.6, 113.8, 118.9, 122.6, 142.2 ppm

Hydroformylation examples 22 to 30

The experiments were carried out as described above for ligands (D), (E), (H) and (J). For all experiments, 10 ml of the 6.04 mM solution of the rhodium starting compound were used, corresponding to approximately 140 mass ppm of rhodium. The The ratio of ligand rhodium was always 5 (for results see Table 3).

Comparative Examples 31 to 33 The tests were carried out as described above for Comparative Example 16. Experiment 31 gives selectivities similar to experiments 22 and 28. The yield for the catalyst with the ligand M (experiment 22) is significantly higher than with the ligand X. Experiments 32 and 33 show examples with internal n-octenes as starting material, in selectivities of 81.9% (ligand X) and 83.9% (ligand Y) are achieved. The yield is about 16.9%. In comparison, you get z. B. with the ligands M and P according to the invention in the implementation of the internal 2-pentene (experiments 23 and 29) both higher n-selectivities and significantly higher yields (TabeUe 3).

Table 3: Examples of hydroforming with ligands (M), (L), (O) and (P)

Example 34: Representation of ligand (A)

a) Representation of the P-Cl building block (Ψ)

(Ψa) (Ψ)

The synthesis was based on I. Neda et al., Z. Naturforsch. 49b, 1994, 788-800:

To a solution of 30.2 g (0.153 mol) of N-MemyHsatoic anhydride (90%) in 300 ml of dioxane (dried) in a 500 ml Schlenk tube was added within 20 min

Stirring was added dropwise using a syringe to 27.4 g (28 mL; 0.253 mol) of benzylamine (99%). The The resulting reaction mixture was heated to 70 ° C. with stirring and kept at this temperature for 8 hours. The solution was cooled to room temperature overnight. The entire reaction mixture was then filtered through a frit. The very small black precipitate (particles) on the frit was discarded. The solvent was evaporated from the feed by vacuum. The residue was extracted with 120 ml of diethyl ether. The product (Ψa) crystallizes after storage for 24 hours at -21 ° C. After filtration, the product was washed twice with 50 ml of pentane and then dried. Analysis: GC / MS: 27.33 min; m / e 240 (80%, M *), 134 (60%), 106 (100%).

12.1 g (0.05 mol) (Ψa) and 10.1 g (14 mL) (0.1 mol) of triethylamine are dissolved in 175 mL of dried toluene in a 250 mL Schlenk tube. 6.9 g (4.4 mL) (0.05 mol) of phosphorus trichloride are slowly added dropwise to the solution at room temperature. This reaction mixture is stirred at 70 ° C. for 4 h and then cooled to room temperature. The triethylammonium chloride is then filtered off and the solvent of the filtrate is removed in an oil pump vacuum. An orange, viscous oil (Ψ) is created. Analysis: GC / MS: 28.35 min; m / e 304 (100%, MT), 269 (100%), 199 (55%), 91 (100%); ³¹ P {1H} -NMR (d ₈ - toluene): δ 127.9 ppm.

c) Representation of the ligand (A) To a solution of 8.6 g (0.1 mol) (Ψ) in 100 ml of toluene is added dropwise at -20 ° C a solution of 5.8 g (0.028 mol) 2.4 -Di-tert-butylphenol and 6 g (= 8.4 ttύ; 0.06 mol) triethylamine in 100 ml of toluene. After warming to room temperature within 14 h, the reaction mixture is filtered, the solvent of the filtrate is removed in an oil pump vacuum and the residue is crystallized in acetonitrile. ³¹ P { ¹ H} NMR (d ₈ toluene): δ 112.3 ppm.

Hvdroformylation examples 35 to 37

The hydroforming tests were carried out in a constant

Gas flow measurement, paddle stirrer and HPLC pump equipped 100 ml autoclave from Parr. 2.55 g of a solution of 0.357% by mass of Rh-nonanoate in toluene and 4.50 g of a solution of 2.204% by mass were placed in the autoclave under an argon atmosphere. of the ligand (A) filled in toluene. The amount of toluene was made up to 30 g. The rhodium-ligand mixture was then stirred (1000 rpm) with synthesis gas (CO / H2 1: 1) to a pressure of 5 - 10 bar (target pressure 20 bar) or 10 - 15 bar (SoUdrack 40 bar) brought and heated to 100 ° C or 120 ° C. After the desired reaction temperature had been reached, 1-octene was added via an HPLC pump and the pressure on the SoUdrack was adjusted to 20 bar or 40 bar. Samples were taken at fixed intervals during the test period. The reaction was carried out at constant pressure (pressure regulator from Bronkhorst (NL)) for 5 h. After the trial period, the autoclave was cooled to room temperature, decompressed and flushed with argon. Each 0.2 ml of the autoclave solution was mixed with 0.8 ml of n-pentane and analyzed by gas chromatography.

Table 4: Examples of hydroformylation with (A)

Comparative Examples 38 to 40

The tests were carried out as described above for Comparative Example 16. T henylphosphine was used as the ligand. Experiment 35, in which 1-octene is reacted, gives a higher yield than comparative example 38 with the ligand according to the invention. In experiment 36, in which n-octenes are reacted, both the yield and the n-selectivity are significantly increased compared to comparative experiment 39 , The yield with n-butenes as starting material (experiment 37) is significantly increased compared to experiment 40 (TabeUe 4).

Claims

claims:

1. A process for the hydroformylation of olefins, which comprises reacting a monoolefin or monoolefin mixture having 2 to 25 carbon atoms with a mixture of carbon monoxide and hydrogen in the presence of a heteroacyl phosphite according to the general formula (1) or a corresponding complex with one or more metals of FIG. 4. to 10th group of the Periodic Table of the Elements

(1) where R ¹ , R ² , R ³ , R ⁴ and q are each the same or different for a substituted or unsubstituted aphatic, acylic, aromatic, heteroaromatic, mixed aphatic-acylic, mixed aphatic-aromatic, heterocyclic, mixed aphatic-heterocycle Hydrocarbon residue with 1 to 70 carbon atoms, H, F, Cl, Br, I, -CF ₃ , -CH ₂ (CF ₂ ) jCF ₃ with j = 0 - 9, -OR ⁵ , -COR ⁵ , -CO ₂ R ⁵ , -CO ₂ M, -SiR ⁵ ₃ , -SR ⁵ , -SO ₂ R ⁵ , -SOR ⁵ , -SO ₃ R ⁵ , -SO ₃ M, -SO ₂ NR ⁵ R ⁶ , -NR ⁵ R ⁶ , -N = CR ⁵ R ⁶ , where R ⁵ and R ^{6 have the} same or different meanings of R ¹ and M is an alkali metal, formally half an alkaline earth metal, ammonium or phosphonium ion, x, y, z are independent of one another O, NR ⁷ , S mean, where R ^{7 has} one of the meanings of q and x, y, z do not simultaneously stand for O, with the proviso that if q has a residue which has a slracta unit (6c)

2. The method according to claim 1, characterized in that the radicals R ¹ and R ² , R ² and R ³ and / or R ³ and R ^{4 are} an anneUtes, substituted or unsubstituted aromatic, heteroaromatic, aUphatic, mixed aromatic-aliphatic or mixed Apply heteroaromatic-aliphatic ring system.

3. The method according to claim 1 or 2, characterized in that the residue q consists of the residues WR, where W is a double-bonded substituted or unsubstituted aphatic, alicyclic, mixed aphatic-acyclic, heterocyclic, mixed aliphatic-heterocyclic, aromatic, heteroaromatic, mixed AUphatic-aromatic hydrocarbon radical having 1 to 50 carbon atoms and the radical R is -OR ⁵ , -NR ⁵ R ⁶ , phosphite, phosphonite, phosphinite, phosphine or heteroacyl phosphite according to formula (6c), where R ⁵ and R ^{6 are} identical or different are and have one of the meanings of R ¹ .

4. The method according to claim 3, characterized in that W represents a radical according to the general formula (2) where R ⁸ , R ⁹ , R ¹⁰ , R ", R ¹² , R ¹³ , R ¹⁴ and R ¹⁵ each have the same or different meanings of R ¹ , t for a divalent radical CR ¹⁶ R ¹⁷ , SiR ¹⁶ R ¹⁷ , NR ¹⁶ , O or S is and R ¹⁶ and R ^{17 are defined} as R ⁵ and R ⁶ , n = 0 or 1 and the positions a and b serve as connecting points.

5. The method according to claim 4, characterized in that two adjacent radicals R ⁹ to R ¹⁵ together an annelHertes substituted or unsubstituted aromatic, heteroaromatic, aUphatic, mixed aromatic-aHphatic or mixed heteroaromatic-aUphatic ring system.

6. The method according to claim 4, characterized in that W represents a radical according to the general formula (3):

where R ¹⁸ , R ¹⁹ , R ²⁰ , R ²¹ , R ²² and R ²³ each have the same or different meanings of R ¹ , t for a divalent radical CR ¹⁶ R ¹⁷ , SiR ¹⁶ R ¹⁷ , NR ¹⁶ , O or S stands and R ¹⁶ and R ^{17 are defined} as R ⁵ and R ⁶ , n = 0 or 1 and the positions a and b as Serve as starting points.

7. The method according spoke 6, characterized in that two adjacent radicals R ¹⁸ to R ²³ together form an annelHertes substituted or unsubstituted aromatic, heteroaromatic, non-aromatic, mixed aromatic-non-hepatic or mixed heteroaromatic-non-aromatic ring system.

8. The method according to any one of claims 3 to 7, characterized in that W represents a radical according to the general formula (4):

wherein u represents a divalent group selected from residues of the formulas (5a), (5b) and (5c)

in which R ²⁴ , R ²⁵ , R ²⁶ and R ²⁷ each have the same or different meanings of R ¹ and the positions a and b serve as starting points.

9. The method according spoke 8, characterized in that two adjacent radicals R ²⁴ to R ²⁷ together an annelHertes substituted or Use unsubstituted aromatic, heteroaromatic, aUphatic, mixed aromatic-AUphatic or mixed heteroaromatic-aHphatic ring system.

10. The method according to any one of claims 3 to 9, characterized in that R represents radicals according to the general formulas (6a), (6b) and (6c):

wherein R ²⁸ and R ²⁹ each have the same or different one of the meanings of R ¹ , x, y, z and W have the meanings mentioned and m = 0 or 1, n = 0 or 1, k = 0 or 1 , 1 = 0 or 1, and the position a serves as a connection point.

11. The method according to any one of claims 1 to 10, characterized in that the metal of the 4th to 10th group of the periodic table is rhodium, platinum, palladium, cobalt or ruthenium

12. The method according to any one of claims 1 to 11, characterized in that further phosphorus-containing ligands are present.

13. A process for carbonylation, hydrocyanation, isomerization of olefins or amidocarbonylation in the presence of heteroacylphosphines of the formula (1) or their metal complexes, where R ¹ , R ² , R ³ , R ⁴ and q are each the same or different for a substituted or unsubstituted aHphatic, aHcyclic, aromatic, heteroaromatic, mixed aHphatic-aHcycHschen, mixed aHphatic-aromatic, heterocycHschen, mixed aliphatic-heterocycUschen hydrocarbon residue with 1 to 70 carbon atoms, H, F, Cl, Br, I, -CF ₃ , - CH ₂ (CF ₂ ) _j CF ₃ with j = 0-9, -OR ⁵ , -COR ⁵ , -CO ₂ R ⁵ , -CO ₂ M, -SiR ⁵ ₃ , -SR ⁵ , -SO ₂ R ⁵ , -SOR ⁵ , -SO ₃ R ⁵ , -SO ₃ M, -SO ₂ NR ⁵ R ⁶ , -NR ⁵ R ⁶ , -N = CR ⁵ R ⁶ , where R ⁵ and R ^6, identical or different, have one of the meanings of R ^{1 has} and M is an alkali metal, formally half an alkaline earth metal, ammonium or phosphonium ion, x, y, z are independently O, NR ⁷ , S, where R ^{7 has} one of the meanings of R ¹ .