This application relates to processes and systems for producing substituted lactones from oxidative carbonylation of alkanes with three or more carbon atoms.
Lactone is a class of important chemical or chemical intermediate. For example, Pivalolactone (α,α-dimethyl-β-propiolactone) can be used as a monomer to synthesize linear polyesters including polypivalolactone (PPVL). PPVL may be prepared with a wide range of molecular weights from oligomers to polymers with molecular weights in the order of millions. PPVL has a high degree of crystallinity and may have desirable properties such as low glass transition temperature, chemical stability with resistance to water, acids, alkalis, solvents, bleaching agents, detergents, heat, and UV light. Some applications of PPVL may include fibers, molded articles, films, blends, and composites, for example. However, while PPVL may be a desirable polymer to synthesize, preparation of the monomer pivalolactone (PVL) typically involves the use of exotic materials such as ketenes, which may be extremely reactive and difficult to handle or may involve corrosive materials such as β-chlorocarboxylic acids.
Olefin epoxides are an important intermediate that can be converted to many useful products, for example, olefin epoxides may be converted to surfactants, detergents, esters, and epoxies. In some instances, isobutylene epoxide can be converted to lactone (by carbonylation) and further to polypivalolactone. Olefin epoxides can be produced by oxidation of olefins with an epoxidation agent. During the epoxidation, an oxygen atom is transferred from the epoxidation agent to C═C double bond in the olefins, thus forming a three-membered ring with two carbon and one oxygen. Suitable epoxidation agents may typically include peracids, hydroperoxides, hydrogen peroxide, and ozone, or O2 (in the case of ethylene oxide). Existing technologies typically require olefins as feeds, which are produced by steam cracking, catalytic cracking, or catalytic dehydrogenation of alkanes. Since olefin generation from alkanes is a highly endothermic process, the processes to produce olefins are energy intensive with high carbon footprint. Therefore, it is desirable to use alkanes as the feed to produce olefin epoxides via oxidation using oxygen or air. Such an advantaged process to produce olefin epoxides leads to a desired process to prepare lactones via carbonylation of the olefin epoxides derived from oxidation of alkanes.
As discussed above, there may be two commercially available routes to synthesize the monomer pivalolactone (PVL) illustrated in Reactions 1 and 2. PVL may be considered a di-methyl substituted lactone.
In Reaction 1, a carbonyl compound, such as formaldehyde, may be reacted with a ketene, such as dimethylketene to form the PVL monomer. Reaction 1 may be carried out the presence of an aprotic Lewis acid which may produce PVL by a 2+2 addition. The reaction conditions are typically about 50° C. in ethyl acetate or propyl acetate solvent in a weak Lewis acid such as zinc chloride (ZnCl2). This reaction route typically requires the preparation and handling of the ketene as well as the use of formaldehyde. There may be some downsides to Reaction 1 such as difficulty in separating the product from reactants and water workup to quench the reactive dimethylketene and remove the Lewis acid followed by fractional distillation of the product. Reaction 1 may be expensive as catalyst loading may be high and the PVL purification may be difficult.
A reaction path to produce PVL on a larger scale than Reaction 1 is illustrated in Reaction 2. In Reaction 2, a β-chlorocarboxylic acid such as chloropivalic acid may undergo a ring closing reaction to form PVL. However, chloropivalic acid may be corrosive to metal surfaces, and chloropivalic acid may thermally polymerize to polypivalolactone (PPVL). There have been some efforts to suppress the tendency of chloropivalic acid to polymerize thermally or otherwise during synthesis by addition of additives such as boron trifluoride (BF3) and tribenzylamine, phosphorus acids, phosphates, and potassium permanganate/sulfur dioxide mixtures. However, the thermodynamics and kinetics of the reaction dictate that the reaction temperature generally must be in excess of 160° C. which max exacerbate the aforementioned premature polymerization during synthesis. Furthermore, the ring closing reaction often produces caustic by-products which may be harmful to reactor equipment and may be difficult or expensive of which to dispose.
There may be other routes to produce PVL, such as the cyclization of hydroxyacids where the halogen of a β-chlorocarboxylic acid is instead replaced by a hydroxyl group. Such ring closing reactions may be conducted in a solvent with a base. Some exemplary solvents may include paraffin oils, phthalates, chloroform, water/methanol, and benzene/butanol, for example. Some exemplary bases may include sodium hydroxide, sodium hydrogen carbonate, lead oxide, and sodium methoxide, for example. For PVL synthesis, these methods are prone to produce a variety of side products including isobutyric acid, formaldehyde, and isobutylene, for example. Some efforts to mitigate the production of side products may include first converting 3-hydroxypivalic acid to 3-acetoxypivalic acid prior to ring close. While this modified synthesis may be effective in reducing the production of side products, it also complicates the synthesis by including an additional step to the procedure.
Another reaction path to PVL may include catalytic carbonylation of isobutylene oxide (IBO). For example, ionic complexes with [Co(CO)4]− anion and aluminum salen cations which may catalyze carbonylation of IBO in solvents such as dimethoxy ethane [CH3OCH2CH2OCH3] or triglyme [CH3OCH2CH2OCH2CH2OCH2CH2OCH3], for example. Without being limited by theory, the solvent chosen may affect the yield and conversion of IBO to PVL. IBO may be produced from isobutylene, which may be produced from steam or catalytic cracking of crude oil, vacuum gas oil, or other hydrocarbon sources, or by the catalytic dehydrogenation of alkanes, all of which are energy intensive processes. Other substituted epoxides, such as cis-butene oxide, may be produced similarly.
Given the limitations and challenges of the forgoing processes, finding a means to produce lactones using a less energy-intensive processes is desirable.
Disclosed herein is an example method including: introducing a substituted olefin epoxide stream including a substituted olefin epoxide and a carbon monoxide stream including carbon monoxide into a carbonylation reactor; and carbonylating at least a portion of the substituted olefin epoxide with the carbon monoxide to generate a product stream including a substituted lactone, wherein the step of carbonylating is catalyzed by a catalyst comprising a cationic Lewis acid bound to a support.
Further disclosed herein is an example composition including: a substituted olefin epoxide, carbon monoxide, and a catalyst comprising a cationic Lewis acid bound to a support, wherein the substituted olefin epoxide has the form of:
wherein R1 and R2 are individually selected from H or a hydrocarbyl group containing 1 to 10 carbon atoms, wherein the hydrocarbyl group is linear, branched, or cyclic, and wherein R3 is selected from H or a hydrocarbyl group containing 1 to 9 carbon atoms, wherein the hydrocarbyl group is linear, branched, or cyclic, and wherein not all three of R1, R2, and R3 are H.
Further disclosed herein is an example method including introducing isobutylene oxide and carbon monoxide into a carbonylation reactor; carbonylating at least a portion of the isobutylene oxide with the carbon monoxide; and generating a product stream including pivalolactone, wherein the step of carbonylating is catalyzed by a catalyst comprising a cationic Lewis acid bound to a support.
The drawing illustrates certain aspects of the present disclosure and should not be used to limit or define the disclosure.
The FIGURE is a schematic diagram of a process for production of substituted lactones in accordance with embodiments of the present disclosure.
This application relates to processes and systems for producing substituted lactones from oxidative carbonylation of alkanes with three or more carbon atoms.
There may be several potential advantages to the methods and systems disclosed herein, only some of which may be alluded to in the present disclosure. As discussed above, olefin epoxides can be an important intermediate in the production of many useful products which may include substituted lactones. Advantageously, embodiments provide processes and systems that react branched alkanes with oxygen for production of substituted olefin epoxides with three or more carbon atoms. Then the substituted olefin epoxide may be further reacted with carbon monoxide to produce a substituted lactone. The process and systems may be particularly advantageous as embodiments may produce substituted lactones in an integrated process that uses only branched alkanes, oxygen, and carbon monoxide to produce substituted lactones. Accordingly, the methods and systems disclosed may enable efficient large-scale production of substituted lactones from readily available materials, such as branched alkanes, oxygen, and carbon monoxide.
Embodiments may include an integrated process for production of substituted lactones by carbonylation of substituted olefin epoxides. The substituted olefin epoxide may be produced as an integrated part of the process alongside solvents required. The process may include the following steps: (1) oxidation of a branched alkane to produce an organic hydroperoxide and a branched alcohol; (2) epoxidizing a branched alkene with an organic hydroperoxide to produce a substituted olefin epoxide and a branched alcohol; (3) catalytically reacting a branched alcohol to form a branched alkene and branched ether; and (4) carbonylating a substituted olefin epoxide with carbon monoxide to produce a substituted lactone. The substituted olefin epoxide in step (2) may include three or more carbon atoms.
In Step (1), any suitable technique for oxidation of a branched alkane to produce an organic hydroperoxide and a branched alcohol may be used. By way of example, the oxidation may include reaction of a branched alkane and oxygen in the liquid phase. Reaction 3 shows a generalized oxidation of a branched alkane.
In Reaction 3, corresponding to Step (1) above, the branched alkane may include R1, R2, and R3 substitution groups. R1 and R2 may be individually selected from H or a hydrocarbyl group containing 1 to 10 carbon atoms, wherein the hydrocarbyl group is linear, branched, or cyclic, and wherein the cyclic hydrocarbyl may be aromatic or non-aromatic. R3 may be selected from H or a hydrocarbyl group containing 1 to 9 carbon atoms, wherein the hydrocarbyl group is linear, branched, or cyclic, and wherein the cyclic hydrocarbyl may be aromatic or non-aromatic. R1, R2, and R3 may be individually selected such that not all three of R1, R2, and R3 are H. In Reaction 3, the organic hydroperoxide and branched alcohol may include R1, R2, and R3 groups that correspond to the R1, R2, and R3 groups present in the branched alkane reactant. Any of a variety of branched alkanes may be used in the oxidation of Step (1). Suitable branched alkanes may have, for example, from 4 carbon atoms to 30 carbon atoms. Specific examples of suitable branched alkanes may include, but are not limited to, iso-butane, iso-pentane, iso-hexane, iso-heptane, and iso-octane, among others. Alternatively, R1 and R2 groups may be connected as part of a ring with 4 to 14 carbon atoms as shown in structure 1. The ring may be saturated or have multiple degrees of unsaturation without being aromatic.
The oxidation of the branched alkane may be autocatalytic with no catalyst required. However, in some embodiments, a small amount of initiator may be used. For example, the initiator may be used in an amount of 50-10000 ppm. Suitable initiators may include, but are not limited to, the hydroperoxide generated from the branched alkane, t-butyl hydroperoxide, cumyl hydroperoxide, 1-phenylethyl hydroperoxide, di-t-butyl peroxide, di-cumyl peroxide, azobisisobutyronitrile (AIBN), 1,1′-azobis(cyanocyclohexane) (ACHN). In at least one embodiment, the reaction may be carried out in a reaction medium that is devoid of any substantial amount of metals in an ionic state, for example, to provide a reaction medium in which the organic hydroperoxide is stable. In at least one embodiment, water may be added to the reaction mixture in excess of that present as a result of the oxidation process. By way of example, water may be added in an amount of at least 1 wt % water based on the weight of the reaction mixture, for example, from about 1 wt % water to about 6 wt % water by weight of the reaction mixture. By way of further example, the oxidation may be carried out in a dense phase reaction mixture, that is the oxidation may be carried out above the critical pressure of the mixture and under a specified temperature (e.g., about 140° C. to about 170° C.) so that the reaction mixture behaves as a single, dense, quasi-liquid phase. In the dense-phase embodiments, for example, the oxidation may be conducted in a series of corresponding reaction zones. By way of yet another example, the oxidation exothermic heat of reaction may be removed by circulating a portion of the reaction mixture through an indirect heat exchange with the oxygen introduced by sparging into the cooled, circulating reaction mixture. In at least one embodiment, the oxidation of Step (1) may include the co-production of an alcohol. In some embodiments, the oxidation may be optimized to maximize the selectivity to the organic hydroperoxide.
Any suitable source of oxygen may be used in the oxidation of Step (1). In some examples it may be desired that the oxygen-to-hydrocarbon vapor ratio may be maintained outside the explosive regime. For example, source of oxygen may include air (approximately 21 vol % oxygen), a mixture of nitrogen and oxygen, or pure oxygen. The mixture of nitrogen and oxygen may contain, for example, about 2 vol % to about 20 vol % oxygen (or greater).
The oxidation of Step (1) may occur in an oxidation unit which includes equipment to facilitate the oxidation reaction. The oxidation unit may include a reactor and supporting equipment to control the oxidation reaction, add reactants, remove products, and maintain and control pressure and temperature. The oxidation step may occur at any suitable oxidation conditions, including temperature, pressure, and residence time. For example, the oxidation of step (1) may occur at a temperature of about 100° C. or greater. In some embodiments, the temperature of the oxidation may range from about 110° C. to about 200° C. or, alternatively, from about 130° C. to about 160° C. In some embodiments, the oxidation may be at a pressure of about 300 psig (2068 kpa) to about 800 psig (5526 kpa) or, alternatively, about 400 psig (2758 kpa) to about 600 psig (4199 kpa) or, alternatively, about 450 psig (3102 kpa) to about 550 psig (3792 kpa). In some embodiments, the residence time in the oxidation unit may be about 2 hours to about 24 hours, about 4 hours to about 10 hours, or about 6 hours to about 8 hours. The residence time may be selected to give a conversion to the organic hydroperoxide of about 15% to about 70%, about 20% to about 60%, or about 30% to about 50%. Where alcohol is co-product of the oxidation, the reaction conditions may be selected to provide a selectivity to the organic hydroperoxide of at least 50%, for example, of about 50% to about 80% with selectivity to the alcohol of about 20% to about 50%.
In Step (2), any suitable technique for epoxidation of the branched alkene with the organic hydroperoxide to produce a substituted olefin epoxide and a branched alcohol may be used. Reaction 4 shows a generalized epoxidation of the branched alkene.
In Reaction 4, corresponding to Step (2) above, the organic hydroperoxide may be the organic hydroperoxide produced from Step (1). The branched alkene may be produced in Step (3) as will be explained in further detail below. The organic hydroperoxide and branched alkene may include R1, R2, and R3 substitution groups which may correspond to the R1, R2, and R3 groups from the branched alkane from Step (1).
In Step (2), the epoxidation may be carried out using a catalyst. In some embodiments, a soluble catalyst may be used that includes a metal, such as Re, Mo, Nb, Ti, Ta or mixtures thereof. An example of a suitable catalyst may have a Mo(VI)-oxo core such as molybdenum dioxide bis(acetylacetonate) or MoO2(acac)2 where acac is acetylacetonate. Any suitable amount of the catalyst may be used for catalyzing the epoxidation, including, an amount of about 0.001 mol % to about 5 mol % of the total moles of reactants, about 0.01 mol % to about 4 mol %, or about 0.1 mol % to about 2 mol %. Basic promoters may be also be used in the epoxidation. Examples of suitable basic promoters may include, but are not limited to, amines, phosphines, phosphine oxides, or alkyl borate esters. Any suitable amount of the basic promoter may be used, including about 0.001 mol % to about 10 mol % of the total moles of reactants, about 0.01 mol % to about 8 mol %, or about 0.1 mol % to about 5 mol %. The epoxidation may be performed with or without a solvent. Where used, suitable solvents may include, but are not limited to, methanol, ethanol, isopropyl alcohol, t-butyl alcohol. Other solvent such as ethers, hydrocarbons such as C10+ paraffins, cyclo-paraffins, aromatics such as toluene, xylenes, can also be used as long as it can provide the necessary solubility for the catalyst in the reaction mixture. Advantageously, the branched alcohol generated in Step (1) or as a co-product in Step (2) can be used as the solvent, avoiding the need for any additional chemicals in the process.
Any of a variety of branched alkenes may be used in the epoxidation of Step (2). Suitable branched alkenes may have, for example, from 4 carbon atoms to 30 carbon atoms. Specific examples of suitable branched alkene may include, but are not limited to, iso-butene, iso-pentene, iso-hexene, iso-heptene, and iso-octene, among others. In some embodiments, the branched alkene may include cyclic branches, which may be aromatic or non-aromatic. Examples of a suitable branched alkene s may include, for example, 4 carbon atoms, 5 carbon atoms, 6 carbon atoms, or 7 carbon atoms. In some embodiments, the branched alkene may be a combination of any of the previously mentioned branched alkenes. One example of a suitable branched alkene may include isobutylene. In some embodiments, the branched alkene may include cyclic branches, which may be aromatic or non-aromatic. In some examples, the branched alkene may be produced in-situ within the process in Step (3) as will be described in detail below.
The epoxidation of Step (2) may occur in an epoxidation unit which includes equipment to facilitate the epoxidation reaction. The epoxidation unit may include a reactor and supporting equipment to control the epoxidation reaction, add reactants, remove products, and maintain and control pressure and temperature. The epoxidation reaction may occur in a solution or a slurry at any suitable reaction conditions, including temperature, pressure, and residence time. For example, the epoxidation of step (2) may occur at a temperature of about 30° C. to about 200° C., about 130° C. to about 200° C., or about 75° C. to about 125° C. In some embodiments, the epoxidation may be at a pressure of about 15 psig (103 kpa) to about 1500 psig (10342 kpa), about 30 psig (207 kpa) to about 1000 psig (6895 kpa), or about 100 psig (689 kpa) to about 500 psig (3447 kpa). In some embodiments, the residence time in the epoxidation unit may be about 0.1 hours to about 24 hours, about 0.5 hours to about 12 hours, or about 1 hour to about 8 hours. The reaction conditions may be selected, for example, to give a conversion to the substituted olefin epoxide and a branched alcohol olefin epoxide of about 90% or greater and selectivity to the olefin epoxide of about 50% or greater.
In Step (3), the branched alcohol produced in Step (1) and/or Step (2) may be catalytically reacted to form a branched alkene and branched ether. Reaction 5 shows a generalized catalytic reaction of the branched alcohol.
In Reaction 5, corresponding to Step (3) above, the branched alcohol may be the branched alcohol produced in Step (1) and/or Step (2). The branched alcohol may include R1, R2, and R3 substitution groups which may correspond to the R1, R2, and R3 groups from the branched alkane from Step (1).
Reaction 5 may be considered a dehydration reaction of the branched alcohol which produces the branched alkene, branched ether, and water as products. The branched alkene may be the branched alkene utilized in Step (2) above and the branched ether may be the solvent utilized in Step (2) or Step (4) in the carbonylation reaction. The dehydration may be performed in a dehydration unit which includes equipment to facilitate the dehydration reaction. The dehydration unit may include a reactor and supporting equipment to control the dehydration reaction, add reactants, remove products, and maintain and control pressure and temperature. The dehydration reaction may occur in a solution or a slurry at any suitable reaction conditions, including temperature, pressure, and residence time.
The branched ether of Reaction 5 may be an intermediate reaction product in the dehydration reaction and the ratio of branched alkane to branched ether in the product may be adjusted depending on reaction conditions, for example. The molar ratio of branched ether to branched alkene may be in the range of about 0.01 to about 100. Alternatively, the molar ratio of the branched ether to branched alkene may be in the range of about 0.02 to about 50, about 0.05 to about 20, about 0.1 to about 10, or about 0.2 to about 5.
The dehydration may be carried out, for example, in any suitable reactor with any suitable catalyst. An acid catalyst may be used, for example, to catalyze the dehydration. Suitable acid catalyst may include, but are not limited to, crosslinked polystyrene resins containing sulfonic acid groups, carboxylic acid groups, or both sulfonic acid groups and carboxylic acid groups, or sulfonated fluoropolymers. Other acid catalysts may include acids such sulfuric acid, sulfonic acid, or phosphoric acid (neat or solid-supported on silica, alumina, or clay), alumina, aluminosilicates, acidic clay, zeolites (natural or synthetic), silicoaluminophosphates (SAPO), acidic ionic liquids, or acids, such as aluminum chloride or boron trifluoride.
The dehydration of Step (3) may be performed, for example, in the vapor phase at any suitable reaction conditions, including temperature, pressure, and residence time. For example, the dehydration of Step (3) may occur at a temperature of about 150° C. to about 450° C. or, alternatively, about 200° C. to about 350° C. In some embodiments, the dehydration be at a pressure of about 100 psig (103 kpa) to about 500 psig (10342 kpa), about 100 psig (207 kpa) to about 400 psig (6895 kpa), or about 150 psig (689 kpa) to about 300 psig (3447 kpa). In some embodiments, the residence time in the dehydration reactor may be about 1 second to 5 hours or, alternatively, about 5 seconds to 2 hours, or about 10 seconds to 1 hour. The reaction conditions may be selected, for example, to give a conversion to the hydrocarbon of about 80% or greater, or 85% or higher, or 90% or higher.
In Step (4), the substituted olefin epoxide produced in Step (2) may be catalytically reacted with carbon monoxide to form a substituted lactone. Reaction 6 shows a generalized catalytic reaction of an olefin epoxide with carbon monoxide.
In Reaction 6, corresponding to Step (4) above, the substituted olefin epoxide may be the substituted olefin epoxide produced in Step (2). The substituted olefin epoxide may include R1, R2, and R3 substitution groups which may correspond to the R1, R2, and R3 groups from the branched alkane from Step (1). The lactones produced may be of the α-α form or β-β form, wherein the ratios produced may be controlled through catalyst selection and tuning of reaction conditions.
The reaction of the substituted olefin epoxide with carbon monoxide may occur in a carbonylation unit includes equipment to facilitate the carbonylation reaction. The carbonylation unit may include a reactor, such as a carbonylation reactor, and supporting equipment to control the carbonylation reaction, add reactants, remove products, and maintain and control pressure and temperature. The substituted olefin epoxide from Step (2) may be combined with carbon monoxide and introduced into the carbonylation unit. Further, the branched ether from Step (3) may be introduced into the carbonylation unit as a solvent. The reactor in the carbonylation unit may include a catalyst capable of facilitating the carbonylation reaction at the operating temperature and pressure of the reactor.
In some embodiments, a suitable catalyst may include a catalyst such as Structure 1. By way of example, the catalyst of Structure 1 may be suitable for catalyzing Reaction 6, corresponding to Step (4) above. Structure 1 depicts a generalized catalyst including support (S), linker (Z), and coordination ligand (LC). In heterogeneous catalysis, the catalyst support (S) is usually a solid with a relatively high surface area to which the active catalyst is affixed. The support (S) may anchor the coordination ligand (LC) in place to prevent leaching of the coordination ligand (LC) and provide a volume of solid which may be pelletized or otherwise processed to form a solid catalyst. The linker (Z) may be an organic linker which may be covalently bonded to support (S) and coordination ligand (LC) which binds the support (S) and coordination ligand (LC) together. The coordination ligand (LC) may include active sites whereby the reaction of the substituted olefin epoxide produced in Step (2) may be catalytically reacted with carbon monoxide to form a substituted lactone.
Supports may be inert or may contribute to catalytic activity of the coordination ligand (LC). Supports may include, without limitation, silicon based supports including silica and silicates such as aluminosilicates, zeolites, aluminum based supports including alumina and aluminates, titania based supports, zirconia based supports, carbon based supports, Group (I) and Group (II) oxides such as potassium oxide and magnesium oxide, talc, zeolites, clays, or organoclays, for example. Supports may further include organic materials such as polystyrene, polystyrene cross-linked with divinylbenzene, cellulose, cellulose derivatives, acrylic resins, polyvinylpyrrolidone, or copolymers of vinyl and acrylamide, for example. Further examples of supports may include fluoropolymers which may include, but are not limited to polytetrafluoroethylene, ethylene tetrafluoroethylene copolymer, ethylene chlorotrifluoroethylene, polychlorotrifluoroethylene, polyvinyl fluoride, polyvinylidene fluoride, polyperfluoroethylene/propylene copolymer, tetrafluoroethylene-perfluoroalkyl vinylether copolymer, hexafluoropropylene, or perfluoropropyl vinyl ether, for example. Supports may further include metal organic framework based supports including such as zeolitic imidazolate materials or covalent organic frameworks. While only some supports are specifically enumerated herein, one of ordinary skills in the art, with the benefit of this disclosure, should readily recognize other supports not specifically listed herein that would be operable to perform as a catalyst support.
In some examples, linker (Z) may be a di, tri, or multiple functionalized linker that provides a covalent linkage which binds the support (S) and coordination ligand (LC) together. In some embodiments, linker (Z) may include a linker such as Structure 2. Structure 2 depicts a general linker which may include first linking diradical (J), second linking diradical (Q), and third linking polyradical (T). First linking diradical (J) may be covalently bonded to coordination ligand (LC), thereby binding linker (Z) and coordination ligand (LC). Second linking diradical (Q) may be covalently bonded to first linking diradical (J) and third linking polyradical (T). Finally, third linking polyradical (T) may contain functional groups which may form bonds with support (S) thereby immobilizing coordination ligand (LC) to support (S) via linker (Z).
The first linking diradical (J) may include linking groups such as hydrocarbylene, hydrocarboylene, hydrocarbylsiloxene, oxygen, or sulfur, for example. The second linking diradical (Q) may include linking groups capable of bonding to the linking group of first linking diradical (J) and third linking polyradical (T). In Structure 2, the range for n″ is from 1 to 30. Second linking diradical (Q) may include linking groups such as hydrocarbylenes including substituted alkylenes, cycloalkylenes, arylene diradicals, or hydrocarbylsilylenes, and any combinations thereof. Alternatively, second linking diradical (Q) may include substituted siloxane diradicals such as Formula 1 or hydrocarbylsiloxene diradicals including those of Formulas 2-4.
In Formulas 1-4, n may be from 1 to 30 and R″ may be independently selected from the group of hydrogen radical, a hydrocarbyl radical, or a substituted hydrocarbyl radical. CR″2 may independently be replaced by an aromatic diradical such as C6R″4, or an alicyclic diradical of formula Cn′R″2n′-2 where n′ is from 4 to 20, and R is as previously defined.
Alternatively, first linking diradical (J), second linking diradical (Q), and third linking polyradical (T) may be selected from Table 1.
In some examples, coordination ligand (LC) from Structure 1 may include a Lewis acid such as a metal that is capable of accepting an electron pair. The Lewis acid may be included in the coordination ligand (LC) as part of a larger metallic complex whereby the Lewis acid is bound to one or more ligands. Some examples may include a Lewis acid bound to one or more of carbon, oxygen, nitrogen, or any combinations thereof. Some embodiments may include a metal complex that has the formula [(Lc)yMb]z+, where: Lc is a ligand. M is a metal as defined below; b is an integer from 1 to 4; y is an integer from 1 to 12; and z is an integer from 1 to 4.
In further embodiments, coordination ligand (LC) may be the coordination ligand shown in Structure 3. The coordination ligand (LC) of Structure 3 may be characterized as a cationic Lewis acid. In some embodiments, the coordination ligand (LC) may include a metallo salenate complex. The catalytic activity of the metallo salenate complex may arise from a metal such as a metal-centered cationic Lewis acid, shown in Structure 3 as metal (M). The bonds between metal (M) and the atoms N and O in Structure 3 may anchor metal (M) in place within the metallo salenate complex.
In some embodiments, metal (M) may be an element selected from periodic table groups 3-13. For example, metal (M) may be aluminum, chromium, titanium, zirconium, hafnium, indium, gallium, zinc, iron, cobalt, copper, scandium, yttrium, or combinations thereof. In some embodiments, the metal (M) may have an oxidation state of +2, such as, metal (M) may be Zn(II), Cu(II), Mn(II), Co(II), Ru(II), Fe(II), Co(II), Rh(II), Ni(II), Pd(II) or Mg(II). In further embodiments, metal (M) may have an oxidation state of +3. In some embodiments, metal (M) may be Al(III), Cr(III), Fe(III), Co(III), Ti(III), Zr(III), Hf(III), Sc(III), Y(III), In(III), Ga(III), V(III) or Mn(III). In some embodiments, metal (M) may have an oxidation state of +4. In some embodiments, metal (M) may be Ti(IV), Zr(IV), V(IV), Cr(IV), or Mn(IV).
In some embodiments, metal (M) may include multiple metal atoms, designated as M1 and M2 which may be each independently a metal atom selected from the periodic table groups 2-13. In some embodiments, M1 and M2 may be a transition metal selected from the periodic table groups 4, 6, 11, 12 and 13. In some embodiments, M1 and M2 may be aluminum, chromium, titanium, indium, gallium, zinc cobalt, or copper. M1 and M2 may be selected to have the same chemical identity. In some embodiments, M1 and M2 may be selected to be the same metal but have different oxidation states. In some embodiments, M1 and M2 may be different metals.
The coordination ligand (LC) of Structure 3 may include substituted groups Ra, Rb, Rc, Rd, and Re. As discussed above, coordination ligand (LC) may be bound to linker (Z) such as in Structure 1. In embodiments, at least one or more of substituted groups Ra-Re of Structure 3 may be bonded to any embodiment of linker (Z) discussed above. Linker (Z) may be bonded to substrate (S) and coordination ligand (LC) through at least one or more of substituted groups Ra-Re thereby immobilizing the coordination ligand (LC) to the substrate (S).
Additionally, any one or more of the substituted groups Ra-Re which are not bonded to linker (Z) may be bonded to a moiety such as hydrogen, a halogen, or a hydrocarbyl. Examples of hydrocarbyls may include, but are not limited to, C1-20 aliphatics, C1-20 heteroaliphatics having 1-4 heteroatoms such as nitrogen, oxygen, sulfur, 6- to 10-membered aryl, 5- to 10-membered heteroaryl having 1-4 heteroatoms such as nitrogen, oxygen, or sulfur, or 4- to 7-membered heterocyclic having 1-2 heteroatoms such as nitrogen, oxygen, or sulfur. Substituted groups R1-R5 may also include moieties such as —OR, —NR, —SR, —CN, —NO2, —SO2R, —CNO, —NRSO2R, —NCO, —N3, —SiR wherein each R is a C1-C20 hydrocarbyl.
The carbonylation reaction may be catalyzed by the catalyst described above, and may be carried out in a solution or a slurry at any suitable reaction conditions, including temperature, pressure, and residence time. For example, the carbonylation of Step (4) may occur at a temperature of about 50° C. to about 100° C., about 60° C. to about 95° C., or about 70° C. to about 90° C. In some embodiments, the epoxidation may be at a pressure of about 500 psig (3447 kpa) to about 2000 psig (13790 kpa), about 750 psig (5171 kpa) to about 1500 psig (10342 kpa), or about 1000 psig (6895 kpa) to about 1500 psig (10342 kpa). In some embodiments, the residence time in the carbonylation unit may be about 0.1 hours to about 50 hours, about 0.5 hours to about 40 hours, or about 1 hour to about 36 hours. The reaction conditions and catalyst may be selected, for example, to give a conversion of the substituted olefin epoxide about 90%, 95%, 99%, or greater and selectivity to the substituted lactone of about 90%, 95%, 99%, or greater.
A composition may be formed in the reactor of the carbonylation unit. The composition may include the reactants introduced into the reactor such as substituted olefin epoxide, carbon monoxide, and the catalyst comprising a Lewis acid component. The composition may further include reaction products such as substituted lactone as well as branched ether solvent as well as unreacted reactants and products of any of the previously mentioned reactions. In some examples the composition may include carbon dioxide, isobutylene oxide, and a catalyst comprising a cationic Lewis acid bound to a support as described herein.
The net reaction of Steps (1)-(4) are illustrated in Reaction 7 below.
In Reaction 7, corresponding to Steps (1)-(4) described above, substituted lactones may be produced by an integrated process whereby common refinery streams such as branched alkanes, oxygen, and carbon monoxide may be reacted. The integrated process may recycle unreacted branched alkanes and unreacted carbon monoxide. Furthermore, the integrated process may allow production of a branched ether which may be utilized as a solvent within the integrated process. Generation of the solvent in-situ allows for a closed loop solvent solution whereby any solvent required is generated without the need for addition of an external solvent. Depending on the chemical identity of the solvent, there may also be commercial value in producing the solvent alongside the substituted lactone.
An embodiment may include production of pivalolactone from isobutane, oxygen, and carbon monoxide. In the present embodiment, the branched alkane is isobutane which may be considered to have R1 and R2 methyl substitutions and R3 hydrogen substitution. A first step in the present embodiment may include oxidation of isobutane as illustrated in Reaction 8, corresponding to Step (1) described above.
In Reaction 8, the oxidation of isobutane may proceed according the methods described above. The oxidation reaction may produce t-butyl hydroperoxide and t-butyl alcohol as products. A second step in the present embodiment may include the epoxidation of isobutene with t-butyl hydroperoxide as illustrated in Reaction 9, corresponding to Step (2) described above.
In Reaction 9, the epoxidation may proceed according to the methods described above. The epoxidation reaction may produce isobutylene oxide with t-butyl alcohol as a co-product. A third step in the present embodiment may include catalytic dehydration of t-butyl alcohol illustrated in Reaction 10, corresponding to Step (3) described above.
In Reaction 10, the catalytic dehydration may proceed according to the methods described above. The catalytic dehydration reaction may produce di-tert-butyl ether, isobutylene, and water as products. Di-tert-butyl-ether produced in Reaction 10 may advantageously be used as the solvent in downstream processes. There may be several advantages to utilizing di-tert-butyl ether including, but not limited to, that the solvent necessary for the carbonylation reaction may be generated from the available materials thereby eliminating the need for a foreign solvent, the boiling point of di-tert-butyl ether (107° C.) is high enough to allow elevated temperature for the step of carbonylation, produced pivalolactone and di-tert-butyl ether may be readily separated by distillation, and the dehydration conditions may be readily adjusted to meet the demand of makeup di-tert-butyl ether (DTBE) needed. The isobutylene produced in Reaction 10 may be used in Reaction 9. A fourth step in the present embodiment may include carbonylation of the isobutylene oxide as illustrated in Reaction 11, corresponding to Step (3) described above.
In Reaction 11, the carbonylation reaction may proceed according to the methods described above and may be catalyzed by any of the previously described catalysts. The carbonylation reaction may produce pivalolactone as a product. The DTBE solvent may be removed from the reaction mixture leaving pivalolactone as the product. Thus, the net reaction is converting isobutane, oxygen, and carbon monoxide to pivalolactone and water as shown in Reaction 12. Additionally, DTBE production may be readily controlled within the process and may be inter-converted with isobutylene over an acid catalyst.
The FIGURE illustrates an embodiment of a process 100 for producing substituted lactones. As illustrated, process 100 may include oxidation unit 102, epoxidation unit 104, dehydration unit 106, carbonylation unit 108, and separation unit 110. Process 100 may begin with introduction of oxygen stream 112 and branched alkane stream 114 into oxidation unit 102. Oxygen stream 112 may be any source of oxygen described above including, air, pure oxygen, or oxygen enriched air, for example. Branched alkane stream 114 may include any of the previously described branched alkanes. Oxidation unit 102 may include a reactor where the reactions of Step (1) may be performed. Stream 118 may exit oxidation unit as a product stream. Stream 118 may include unreacted branched alkane, oxygen and other gasses introduced alongside the oxygen, and products organic hydroperoxide and branched alcohol. Stream 118 may be stripped of unreacted branched alkane, oxygen, and other gasses in a stripping unit (not shown) such that a majority of stream 118 introduced into epoxidation unit 104 is organic hydroperoxide and branched alcohol. Stripping unit may include any units capable of removing at least a portion of unreacted reactants such as, without limitation, flash drums and stripping columns for example.
Branched alkene stream 124 and stream 118 may be introduced into epoxidation unit 104. Branched alkene stream 124 may include a branched alkene generated in dehydration unit 106. Epoxidation unit 104 may include a reactor whereby the reactions of Step (2), described above, may be performed. The branched alcohol from stream 118 may be utilized as a solvent within epoxidation unit 104 to solubilize and bring into contact the branched alkene and organic hydroperoxide. As described above, the branched alkene and organic hydroperoxide may be reacted to form a substituted olefin epoxide and branched alcohol. An effluent from the reactor of epoxidation unit 104 may include the branched alcohol, organic hydroperoxide, branched alkene, and substituted olefin epoxide. The substituted olefin epoxide may be separated from the branched alcohol and unreacted branched alkene and organic hydroperoxide in a distillation column, for example, to generate substituted olefin epoxide stream 122 containing a majority of the substituted olefin epoxide generated in epoxidation unit 104 and branched alcohol stream 120 containing a majority of the branched alcohol from the effluent of the reactor of epoxidation unit 104.
Branched alcohol stream 120 may be introduced into dehydration unit 106. Dehydration unit 106 may include a reactor whereby the reactions of Step (3), described above, may be performed. In dehydration unit 106 the branched alcohol may be catalytically reacted to form the branched alkene, a branched ether, and water. The products of the dehydration reaction may be separated by distillation, for example, to form water stream 130, branched alkene stream 124, and branched ether stream 126. Branched alkene stream 124 may be conveyed to an introduced to epoxidation unit 104 and branched ether stream may be introduced to carbonylation unit 108.
Substituted olefin epoxide stream 122, branched ether stream 126, and carbon monoxide stream 128 may be introduced into carbonylation unit 108. Carbonylation unit 108 may include a reactor whereby the reactions of Step (4), described above, may be performed. In carbonylation unit 108 branched ether provided by branched ether stream 126 may act as a solvent to bring into contact the substituted olefin epoxide from substituted olefin epoxide stream 122 and carbon monoxide from carbon monoxide stream 128. The olefin epoxide and carbon monoxide may be reacted to produce a substituted lactone. Effluent stream 132 from the reactor of carbonylation unit 108 may include a mixture of unreacted carbon monoxide, substituted lactone, and branched ether. Effluent stream 132 may be conveyed to an introduced into separation unit 110 which may include equipment for separating the substituted lactone product. The unreacted carbon monoxide may be separated from a bulk liquid phase including the substituted lactone and branched ether in a flash drum, for example, to produce recycle carbon monoxide stream 134 which may be recycled back to carbonylation unit 108. The remaining liquid phase including substituted lactone and branched ether may be separated by distillation, for example, to produce substituted lactone stream 138 and recycle branched ether stream 136 which may be recycled back to carbonylation unit 108.
Accordingly, the preceding description describes examples of processes and systems for producing substituted lactones from oxidative carbonylation of alkanes with three or more carbon atoms. The processes and systems disclosed herein may include any of the various features disclosed herein, including one or more of the following embodiments.
Embodiment 1. A method comprising: introducing a substituted olefin epoxide stream comprising a substituted olefin epoxide and a carbon monoxide stream comprising carbon monoxide into a carbonylation reactor; and carbonylating at least a portion of the substituted olefin epoxide with the carbon monoxide to generate a product stream comprising a substituted lactone, wherein the step of carbonylating is catalyzed by a catalyst comprising a cationic Lewis acid bound to a support.
Embodiment 2. The method of embodiment 1 further comprising generating the substituted olefin epoxide stream by: introducing a branched alkane stream into an oxidation unit, the branched alkane stream comprising a branched alkane; oxidizing at least a portion of the branched alkane and generating at least an oxidized stream from the oxidation unit, the oxidized stream comprising an organic hydroperoxide and a branched alcohol; introducing at least a portion of the oxidized stream and a branched alkene stream into an epoxidation unit, the branched alkene stream comprising a branched alkene; and epoxidizing at least a portion of the branched alkene with the organic hydroperoxide and generating the substituted olefin epoxide stream.
Embodiment 3. The method of embodiment 2 wherein, the branched alkane has the form of:
wherein, R1 and R2 are individually selected from H or a first hydrocarbyl group containing 1 to 10 carbon atoms, wherein the first hydrocarbyl group is linear, branched, cyclic and non-aromatic, or cyclic and aromatic, and wherein R3 selected from H or a second hydrocarbyl group containing 1 to 9 carbon atoms, wherein the second hydrocarbyl group is linear, branched, cyclic and non-aromatic, or cyclic and aromatic, and wherein R1, R2, and R3 are not each H, or wherein the branched alkane has the form of:
wherein R1 and R2 groups are connected by a ring of 4 to 14 carbon atoms, and wherein R3 is selected from H or a hydrocarbyl group containing 1 to 9 carbon atoms, and wherein the hydrocarbyl group is linear, branched, cyclic and non-aromatic, or cyclic and aromatic.
Embodiment 4. The method of any of embodiments 1-3 wherein the catalyst has the
wherein LC is a coordination ligand comprising the cationic Lewis acid, Z is a linker, and S is the support, and wherein the linker is covalently bonded to the coordination ligand and the support.
Embodiment 5. The method of embodiment 4 wherein the coordination ligand comprises a metallo salenate complex that has the form of:
wherein the M comprises a metal and Ra, Rb, Rc, Rd, and Re are substituted groups.
Embodiment 6. The method of embodiment 5 wherein the metal has an oxidation state of 3+ wherein the metal is selected from the group consisting Al(III), Cr(III), Ti(III), Zr(III), Hf(III), In(III), Ga(III), Fe(III), Co(III), V(III), Mn(III), Sc(III), Y(III), Ti(IV), Zr(IV), V(IV), Cr(IV), Mn(IV), and combinations thereof.
Embodiment 7. The method of embodiment 5 wherein the metal has an oxidation state of 2+ or lower wherein the metal is selected from the group consisting of Zn(I), Zn(II), Fe(I), Fe(II), Co(I), Co(II), Cu(I), Cu(II), Mn(I), Mn(II), Ru(I), Ru(II), Rh(I), Rh(II), Ni(I), Ni(II), Pd(I), Pd(II), Mg(I), Mg(II), and combinations thereof.
Embodiment 8. The method of embodiment 5 wherein at least one of the substituted groups Ra, Rb, Rc, Rd, and Re are bonded to the linker.
Embodiment 9. The method of any of e embodiments 4-8 wherein the linker has the form of:
wherein J comprises a first linking diradical, Q comprises a second linking diradical, and T comprises a third linking polyradical, wherein the first linking diradical is covalently bonded to coordination ligand, wherein the second linking diradical is covalently bonded to the first linking diradical and the third linking polyradical, n″ is an integer in the range of 1-30, and wherein the third linking polyradical is covalently bonded to the support.
Embodiment 10. The method of embodiment 9 wherein the first linking diradical is selected from the group consisting of methylene, methylmethylene, ethylmethylene, dimethylmethylene, ethylmethylmethyleme, diethylmethylene, cyclohexylmethylene, methylcyclohexylmethylene, phenylene, xylylene, naphthylene, methanoylene, dimethylsiloxene, methylethylsiloxene, methylisopropylsiloxene, ethylisopropylsiloxene, di-isopropylsiloxene, oxo, thio, and combinations thereof, wherein the second linking diradical is selected from the group consisting of methylene, methylmethylene, ethylmethylene, dimethylmethylene, ethylmethylmethyleme, diethylmethylene, cyclohexylmethylene, methylcyclohexylmethylene, phenylene, xylylene, naphthylene, methanoylene, dimethylsiloxene, methylethylsiloxene, methylisopropylsiloxene, dimethylsiloxene, methylethylsiloxene, methylisopropylsiloxen, ethylisopropylsiloxene, di-isopropylsiloxene, oxo, thio, and combinations thereof, and wherein the third linking polyradical is selected from the group consisting of methylene, methylmethylene, ethylmethylene, dimethylmethylene, ethylmethylmethyleme, diethylmethylene, cyclohexylmethylene, methylcyclohexylmethylene, phenylene, xylylene, naphthylene, methanoylene, dimethylsiloxene, methylethylsiloxene, methylisopropylsiloxene, ethylisopropylsiloxene, di-isopropylsiloxene, oxo, and combinations thereof.
Embodiment 11. The method of any of embodiments 4-10 wherein the support comprises at least one inorganic material selected from the group consisting of silica, alumina, zirconia, titania, aluminosilicates, talc, zeolites, magnesium oxide, clays, metal organic frameworks, zeolitic imidazolate frameworks, carbon, polystyrene, polystyrene cross-linked with divinylbenzene, cellulose, cellulose derivatives, acrylic resins, polyvinylpyrrolidone, or copolymers of vinyl and acrylamide, fluoropolymers, covalent organic frameworks and combinations thereof.
Embodiment 12. A composition comprising: a substituted olefin epoxide, carbon monoxide, and a catalyst comprising a cationic Lewis acid bound to a support, wherein the substituted olefin epoxide has the form of:
wherein R1 and R2 are individually selected from H or a hydrocarbyl group containing 1 to 10 carbon atoms, wherein the hydrocarbyl group is linear, branched, or cyclic, and wherein R3 is selected from H or a hydrocarbyl group containing 1 to 9 carbon atoms, wherein the hydrocarbyl group is linear, branched, or cyclic, and wherein not all three of R1, R2, and R3 are H.
Embodiment 13. The composition of embodiment 12 wherein the catalyst has the form of:
wherein LC is a coordination ligand comprising the cationic Lewis acid, Z is a linker, and S is the support, and wherein the linker is covalently bonded to the coordination ligand and the support.
Embodiment 14. The composition of embodiment 13 wherein the coordination ligand comprises a metallo salenate complex that has the form of:
wherein the M comprises a metal and Ra, Rb, Rc, Rd, and Re are substituted groups.
Embodiment 15. The composition of embodiment 14 wherein the metal is selected from the group consisting of Al(III), Cr(III), Ti(III), Zr(III), Hf(III), In(III), Ga(III), Fe(III), Co(III), V(III), Mn(III), Sc(III), Y(III), Ti(IV), Zr(IV), V(IV), Cr(IV), Mn(IV), Zn(II), Fe(II), Co(II), Cu(II), Mn(II), Ru(II), Rh(II), Ni(II), Pd(II), Mg(II), and combinations thereof.
Embodiment 16. The composition of embodiment 14 wherein at least one of the substituted groups Ra, Rb, Rc, Rd, and Re is bonded to the linker.
Embodiment 17. The composition of any of embodiments 13-16 wherein the linker has the form of:
wherein J comprises a first linking diradical, Q comprises a second linking diradical, and T comprises a third linking polyradical, wherein the first linking diradical is covalently bonded to coordination ligand, wherein the second linking diradical is covalently bonded to the first linking diradical and the third linking polyradical, n″ is an integer in the range of 1-30, and wherein the third linking polyradical is covalently bonded to the support.
Embodiment 18. The composition of embodiment 17 wherein first linking diradical is selected from the group consisting of methylene, methylmethylene, ethylmethylene, dimethylmethylene, ethylmethylmethyleme, diethylmethylene, cyclohexylmethylene, methylcyclohexylmethylene, phenylene, xylylene, naphthylene, methanoylene, dimethylsiloxene, methylethylsiloxene, methylisopropylsiloxene, ethylisopropylsiloxene, di-isopropylsiloxene, oxo, thio, and combinations thereof, wherein the second linking diradical is selected from the group consisting of methylene, methylmethylene, ethylmethylene, dimethylmethylene, ethylmethylmethyleme, diethylmethylene, cyclohexylmethylene, methylcyclohexylmethylene, phenylene, xylylene, naphthylene, methanoylene, dimethylsiloxene, methylethylsiloxene, methylisopropylsiloxene, dimethylsiloxene, methylethylsiloxene, methylisopropylsiloxen, ethylisopropylsiloxene, di-isopropylsiloxene, oxo, thio, and combinations thereof, and wherein the third linking polyradical is selected from the group consisting of methylene, methylmethylene, ethylmethylene, dimethylmethylene, ethylmethylmethyleme, diethylmethylene, cyclohexylmethylene, methylcyclohexylmethylene, phenylene, xylylene, naphthylene, methanoylene, dimethylsiloxene, methylethylsiloxene, methylisopropylsiloxene, ethylisopropylsiloxene, di-isopropylsiloxene, oxo, and combinations thereof.
Embodiment 19. The composition of any of embodiments 13-18 wherein the support comprises at least one inorganic material selected from the group consisting of silica, alumina, zirconia, titania, aluminosilicates, talc, zeolites, magnesium oxide, clays, metal organic frameworks, zeolitic imidazolate frameworks, carbon, polystyrene, polystyrene cross-linked with divinylbenzene, cellulose, cellulose derivatives, acrylic resins, polyvinylpyrrolidone, or copolymers of vinyl and acrylamide, fluoropolymers, covalent organic frameworks, and combinations thereof.
Embodiment 20. A method comprising: introducing isobutylene oxide and carbon monoxide into a carbonylation reactor; carbonylating at least a portion of the isobutylene oxide with the carbon monoxide; and generating a product stream comprising pivalolactone, wherein the step of carbonylating is catalyzed by a catalyst comprising a cationic Lewis acid bound to a support.
Embodiment 21. The method of embodiment 20 wherein the wherein the catalyst has the form of:
wherein LC is a coordination ligand comprising the cationic Lewis acid, Z is a linker, and S is the support, and wherein the linker is covalently bonded to the coordination ligand and the support.
Embodiment 22. The method of embodiment 21 wherein the coordination ligand comprises a metallo salenate complex that has the form of:
wherein M is a metal selected from Al(III), Cr(III), Fe(III), Co(III), Ti(III), In(III), Ga(III), Sc(III), Hf(III), Zr(III) or Mn(III), and combinations thereof.
Embodiment 23. The method of any of embodiments 21-22 wherein the support comprises at least one inorganic material selected from the group consisting of silica, alumina, zirconia, titania, aluminosilicates, talc, zeolites, magnesium oxide, clays, metal organic frameworks, zeolitic imidazolate frameworks, and combinations thereof.
Embodiment 24. The method of any of embodiments 21-23 where the linker has the form of:
wherein J comprises a first linking diradical, Q comprises a second linking diradical, and T comprises a third linking polyradical, wherein the first linking diradical is covalently bonded to the coordination ligand, wherein the second linking diradical is covalently bonded to the first linking diradical and the third linking polyradical, n″ is an integer in the range of 1-30, and wherein the third linking polyradical is covalently bonded to the support.
Embodiment 25. The method of embodiment 24 wherein first linking diradical is selected from the group consisting of methylene, methylmethylene, ethylmethylene, dimethylmethylene, ethylmethylmethyleme, diethylmethylene, cyclohexylmethylene, methylcyclohexylmethylene, phenylene, xylylene, naphthylene, methanoylene, dimethylsiloxene, methylethylsiloxene, methylisopropylsiloxene, ethylisopropylsiloxene, di-isopropylsiloxene, oxo, thio, and combinations thereof, wherein the second linking diradical is selected from the group consisting of methylene, methylmethylene, ethylmethylene, dimethylmethylene, ethylmethylmethyleme, diethylmethylene, cyclohexylmethylene, methylcyclohexylmethylene, phenylene, xylylene, naphthylene, methanoylene, dimethylsiloxene, methylethylsiloxene, methylisopropylsiloxene, dimethylsiloxene, methylethylsiloxene, methylisopropylsiloxen, ethylisopropylsiloxene, di-isopropylsiloxene, oxo, thio, and combinations thereof, and wherein the third linking polyradical is selected from the group consisting of methylene, methylmethylene, ethylmethylene, dimethylmethylene, ethylmethylmethyleme, diethylmethylene, cyclohexylmethylene, methylcyclohexylmethylene, phenylene, xylylene, naphthylene, methanoylene, dimethylsiloxene, methylethylsiloxene, methylisopropylsiloxene, ethylisopropylsiloxene, di-isopropylsiloxene, oxo, and combinations thereof.
While the disclosure has been described with respect to a number of embodiments and examples, those skilled in the art, having benefit of this disclosure, will appreciate that other embodiments can be devised which do not depart from the scope and spirit of the disclosure as disclosed herein. Although individual embodiments are discussed, the present disclosure covers all combinations of all those embodiments.
While compositions, methods, and processes are described herein in terms of “comprising,” “containing,” “having,” or “including” various components or steps, the compositions and methods can also “consist essentially of” or “consist of” the various components and steps. The phrases, unless otherwise specified, “consists essentially of” and “consisting essentially of” do not exclude the presence of other steps, elements, or materials, whether or not, specifically mentioned in this specification, so long as such steps, elements, or materials, do not affect the basic and novel characteristics of the disclosure, additionally, they do not exclude impurities and variances normally associated with the elements and materials used.
All numerical values within the detailed description and the claims herein modified by “about” or “approximately” with respect the indicated value are intended to take into account experimental error and variations that would be expected by a person having ordinary skill in the art.
For the sake of brevity, only certain ranges are explicitly disclosed herein. However, ranges from any lower limit may be combined with any upper limit to recite a range not explicitly recited, as well as, ranges from any lower limit may be combined with any other lower limit to recite a range not explicitly recited, in the same way, ranges from any upper limit may be combined with any other upper limit to recite a range not explicitly recited.
Filing Document | Filing Date | Country | Kind |
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PCT/US20/40619 | 7/2/2020 | WO |
Number | Date | Country | |
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62929513 | Nov 2019 | US |