Patent Application
20240174808
The present teachings relate generally to free-standing structured organic films and, more particularly, to compositions for anionic exchange membranes containing N-cyclic quaternary ammonium compounds formed from free-standing structured organic films.
Ion-exchange membranes (IEM) can be used in many electrochemical devices such as fuel cells, redox flow batteries, electrolyzers, reverse electrodialysis cells and bioelectrochemical systems (BES) such as microbial fuel cells. IEMs can be composed of hydrophobic substrates with immobilized ion-functionalized groups and mobile counter-ions. Depending on the type of ionic groups being transported, the IEMs can be anion exchange membranes (AEMs) or cation exchange membranes (CEMs). CEMs selectively transport cations (positively charged ions) across a permeable membrane. CEMs can be non-acidic such as those containing Na+ cations, or acidic in the case of proton-exchange membranes (PEMs) which specifically transport H+ cations. AEMs selectively transport anion and are available in non-alkaline anion forms (e.g. containing Cl− anions) and alkaline anions, designated AAEM, for example, OH−, CO32− and HCO3−.
Due to the conformation, and the steric hindrance associated with it, N-cyclic quaternary ammonium compounds have been found to reduce the elimination and substitution reactions that commonly degrade quaternary ammonium cations. It has been shown that N-cyclic quaternary ammonium compounds with 5 and 6 membered rings fused by a central nitrogen atom were stable in 1 M sodium hydroxide (NaOH) at 80° C. for at least 3000 hours. This stability is imperative for a viable commercial system when the material is constantly subjected to alkaline conditions as part of an electrochemical cell, be it for a fuel cell, or CO2 reduction, or other uses. There are several commercial anion exchange membranes available today, which remain stable under such operating conditions for 1000-2000 hours. Extending the life of these materials is essential in order to make these technologies more viable.
While such materials used in ion exchange membranes are typically polymers and cross-linked polymers, most known polymer chemistry synthesis processes do not provide precise control over the molecular-level structure of the formed material since most are randomly patterned. Most polymers are amorphous or partially amorphous except for some classes of linear polymers that can efficiently pack together resulting in high density with crystalline characteristics.
Therefore, it is desirable to fabricate ion exchange membranes synthesized from robust, highly ordered patterned network systems including quaternary ammonium compounds that can be used in a variety of applications such as fuel cells, redox flow batteries, electrolyzers, reverse electrodialysis cells, and microbial fuel cells that will remain stable and resist degradation in alkaline, high temperature operating conditions.
The following presents a simplified summary in order to provide a basic understanding of some aspects of one or more embodiments of the present teachings. This summary is not an extensive overview, nor is it intended to identify key or critical elements of the present teachings, nor to delineate the scope of the disclosure. Rather, its primary purpose is merely to present one or more concepts in simplified form as a prelude to the detailed description presented later.
A structured organic film (SOF) is disclosed. The structured organic film also includes a plurality of segments, a plurality of linkers, and a plurality of ionic capping segments, where at least one or more of the ionic capping segments may include a piperidinium group. Implementations of the structured organic film (SOF) may include where the piperidinium group is a bicyclic piperidinium group. The piperidinium group can be an n-cyclic quaternary ammonium group. A total concentration of ionic segments in the SOF is from about 0.1 to about 5.0 molar equivalents based on a total concentration of segments in the SOF. A thickness of the SOF is from about 250 nm to about 500 μm. The piperidinium group can be 3-methanol-6-azoniaspiro[5.5]undecane (MeASU). At least one of the plurality of ionic capping segments may include one or more hydroxide functional groups or alcohol functional groups. The structured organic film (SOF) has an ion exchange capacity (IEC) of from about 0.25 meq/g to about 5.00 meq/g. An ion-exchange membrane may include the structured organic film (SOF). The structured organic film (SOF) is free-standing.
Another structured organic film (SOF) is disclosed. The structured organic film also includes a plurality of segments. The film also includes a plurality of linkers. The film also includes at least one or more ionic capping segments which may include at least one cationic species. The film also includes where at least one cationic species may include a piperidinium group. Implementations of the structured organic film (SOF) may include where the piperidinium group is 3-methanol-6-azoniaspiro[5.5]undecane (MeASU). A total concentration of ionic segments in the SOF is from about 0.1 to about 5.0 molar equivalents based on a total concentration of segments in the SOF. A thickness of the SOF is from about 250 nm to about 500 μm. The structured organic film (SOF) has an ion exchange capacity (IEC) of from about 0.25 meq/g to about 5.00 meq/g.
A structured organic film (SOF) is disclosed, including a plurality of segments, a plurality of linkers, and at least one or more ionic capping segments which may include at least one cationic species such as 3-methanol-6-azoniaspiro[5.5]undecane (MeASU). The structured organic film (SOF) may include where a total concentration of ionic segments in the SOF is from about 0.1 to about 5.0 molar equivalents based on a total concentration of segments in the SOF. A thickness of the SOF is from about 250 nm to about 500 μm. The structured organic film (SOF) has an ion exchange capacity (IEC) of from about 0.25 meq/g to about 5.00 meq/g.
The features, functions, and advantages that have been discussed can be achieved independently in various implementations or can be combined in yet other implementations further details of which can be seen with reference to the following description.
The accompanying drawings, which are incorporated in and constitute a part of this specification, illustrate embodiments of the present teachings and together with the description, serve to explain the principles of the disclosure. In the figures:
It should be noted that some details of the figures have been simplified and are drawn to facilitate understanding of the present teachings rather than to maintain strict structural accuracy, detail, and scale.
Reference will now be made in detail to exemplary embodiments of the present teachings, examples of which are illustrated in the accompanying drawings. Wherever possible, the same reference numbers will be used throughout the drawings to refer to the same, similar, or like parts.
“Structured organic film” (SOF) refers to a COF that is a film at a macroscopic level. The SOFs of the present disclosure have a capping segment or group added into the SOF formulation, which (after film formation), ultimately bonds to the SOF via at least one functional group located on the capping segment. SOFs of the present disclosure in certain examples can have non-ionic or ionic character, including cationic or anionic. This ionic character can be imparted by either a charged molecular building block or a capping group in the SOF structure.
In this specification and the claims that follow, singular forms such as “a,” “an,” and “the” include plural forms unless the content clearly dictates otherwise.
The term “SOF” generally refers to a covalent organic framework (COF) that is a film at a macroscopic level. The phrase “macroscopic level” refers, for example, to the naked eye view of the present SOFs. Although COFs are a network at the “microscopic level” or “molecular level” (requiring use of powerful magnifying equipment or as assessed using scattering methods), the present SOF is fundamentally different at the “macroscopic level” because the film is for instance orders of magnitude larger in coverage than a microscopic level COF network. SOFs described herein have macroscopic morphologies much different than typical COFs previously synthesized. Films as presently disclosed in a free-standing film example, or as coated onto a surface, include but are not limited to, a top surface and a bottom surface, in which “top” and “bottom” can be dependent on a temporal orientation or position of the film. Furthermore, a surface is still considered a surface even if adhered or bound to a substrate or other material. Films as presently disclosed in a free-standing film example, or as coated onto a surface, also include one or more edges, which can be, but are not limited to, one or more boundaries between where a film is present and where a film is not present.
Additionally, when a capping segment is introduced into the SOF, the SOF framework is locally ‘interrupted’ where the capping segments are present. These SOF compositions are ‘covalently doped’ because a foreign molecule is bonded to the SOF framework when capping segments are present. Capped SOF compositions may alter the properties of SOFs without changing constituent building block segments. For example, the mechanical and physical properties of the capped SOF where the SOF framework is interrupted may differ from that of an uncapped SOF or an SOF without capping segments.
The SOFs of the present disclosure are at the macroscopic level substantially pinhole-free SOFs or pinhole-free SOFs having continuous covalent organic frameworks that can extend over larger length scales such as for instance much greater than a millimeter to lengths such as a meter and, in theory, as much as hundreds of meters. It will also be appreciated that SOFs tend to have large aspect ratios where typically two dimensions of a SOF will be much larger than the third. SOFs have markedly fewer macroscopic edges and disconnected external surfaces than a collection of COF particles.
In examples, a “substantially pinhole-free SOF” or “pinhole-free SOF” may be formed from a reaction mixture deposited on the surface of an underlying substrate. The term “substantially pinhole-free SOF” refers, for example, to an SOF that may or may not be removed from the underlying substrate on which it was formed and contains substantially no irregular pinholes, blisters, ruptures, or gaps, such as those that would be considered coating defects that could form such as when a bubble ruptures during a film formation that is greater than the distance between the cores of two adjacent segments per square cm; such as, for example, less than 10 pinholes, pores or gaps greater than about 250 nanometers in diameter per cm2, or less than 5 pinholes, pores or gaps greater than about 100 nanometers in diameter per cm2. The term “pinhole-free SOF” refers, for example, to an SOF that may or may not be removed from the underlying substrate on which it was formed and contains no unintended pinholes or gaps greater than the distance between the cores of two adjacent segments per micron2, such as no pinholes or gaps greater than about 500 Angstroms in diameter per micron2. Pores that are intentionally and uniformly introduced into SOFs as tunable features for transport via a membrane are distinguished from pinholes for the purposes of this disclosure.
A need for ion exchange membranes, or more specifically anionic functional exchange membranes synthesized from highly ordered patterned network systems including imidazolium compounds that can be used in a variety of applications such as fuel cells, redox flow batteries, electrolyzers, reverse electrodialysis cells, and microbial fuel cells can be addressed by using covalent organic frameworks (COFs). Covalent organic frameworks (COFs) are highly patterned materials with molecular components called building blocks or building block segments which differ from monomers used to synthesis polymers. COFs react to form two- or three-dimensional networks made up of these building block segments that are linked to each other through strong covalent bonds. COFs are typically in powder form and are highly porous materials with extremely low densities. Examples of the present disclosure take advantage of COF's molecular building block approach to design structured organic films (SOFs) that also rely on the same segments, capping segments including imidazolium compounds and linkers as used to arrange COFs but at a macroscopic level are assembled as a film.
Examples of the present disclosure provide organic compositions containing N-cyclic quaternary ammonium-based cations, for use as anion exchange membranes (AEMs). Synthetic methods for exemplary N-cyclic quaternary ammonium containing compounds are also described herein. These anion exchange membranes can be used in electrochemical devices such as, but not limited to, electrolyzers for H2, NH3 production or CO2 conversion, fuel cells, battery separators, and the like. The use of charged building blocks and/or capping segments or groups to form the SOF composition allows the N-cyclic quaternary ammonium functionalized species to be incorporated within and throughout the film network. The SOFs can be used as free-standing films or coated over top a porous support to provide membranes that are stable against swelling and chemical or thermal degradation. The cationic species are fixed within the structured organic film (SOF) which are ordered or periodic at the molecular level. The benefits of ordered cationic SOF compositions lie in their functional characteristics, for example, minimal swelling, tunable ion exchange capacity (IEC) and high durability. N-cyclic quaternary ammonium compounds further provide additional stability to SOF and other films in contact with environmentally harsh use or operation conditions, such as, but not limited to alkaline environments or high temperature environments. This additional stability is in comparison to alternative additives or ionic capping segments that can be incorporated into SOFs. While the general classification of the N-cyclic quaternary ammonium containing compounds of the present disclosure are referred to as piperidiniums, one such example, 6-Azoniaspiro (5.5)undecane bromide may also be referred to as 1,1′-spirobi-piperidinium bromide. In the case of this specific molecular class, it may be referred to as a spirobipiperidinium, N-spiro, heterocyclic spiro, spirocyclic compounds, or spiro quaternary ammonium compounds.
In embodiments, the SOF comprises at least one atom of an element that is not carbon, such at least one atom selected from the group consisting of hydrogen, oxygen, nitrogen, silicon, phosphorous, selenium, fluorine, boron, and sulfur. In further embodiments, the SOF is a boroxine-, borazine-, borosilicate-, and boronate ester-free SOF.
The SOFs of the present disclosure comprise molecular building blocks also referred to as building block segments having a segment (S) and functional groups (Fg). Molecular building blocks require at least two functional groups (x≥2) and may comprise a single type or two or more types of functional groups. Functional groups are the reactive chemical moieties of molecular building blocks that participate in a chemical reaction to link together segments during the SOF forming process. A segment is the portion of the molecular building block that supports functional groups and comprises an atoms that are not associated with functional groups. Further, the composition of a molecular building block segment remains unchanged after SOF formation.
Functional groups are the reactive chemical moieties of molecular building blocks that may participate in a chemical reaction to link together segments during the SOF forming process. Functional groups may be composed of a single atom, or functional groups may be composed of more than one atom. The atomic compositions of functional groups are those compositions normally associated with reactive moieties in chemical compounds. Non-limiting examples of functional groups include halogens, alcohols, ethers, ketones, carboxylic acids, esters, carbonates, amines, amides, imines, ureas, aldehydes, isocyanates, tosylates, alkenes, alkynes and the like. Other examples can include, but are not limited to haloformyls, oxygen containing groups (e.g. hydroxyls, anhydrides, carbonyls, carboxyls, carbonates, carboxylates, aldehydes, esters, hydroperoxy, peroxy, ethers, and orthoesters), nitrogen-containing groups (e.g. carboxamides, amines, imines, imides, azides, azos, cyanates, isocyanates, nitrates, nitriles, isonitriles, nitro so s , nitros, nitrosooxy), sulfur-containing groups (sulfhydryls, sulfides, disulfides, sulfinyls, sulfos, thiocyanates, isothiocyanates, and carbonothioyls), phosphorous-containing groups (e.g. phosphinos, phosphonos, and phosphates), silicon-containing groups (Si(OH)3, Si(SH)4, silanes, silyls, and siloxanes), boron containing groups (e.g. boronic acid, boronic esters, and boronic ethers), metal or metalloid-containing groups (e.g. Ge(OH)3, Ge(SH)4, AsO3H, AsO4H, As(SH)3, Sn(OH)3, Sn(CH3)3, and Sn(Bu)3), or combinations thereof.
Molecular building blocks contain a plurality of chemical moieties, but only a subset of these chemical moieties are intended to be functional groups during the SOF forming process. Whether or not a chemical moiety is considered a functional group depends on the reaction conditions selected for the SOF forming process. Functional groups (Fg) denote a chemical moiety that is a reactive moiety, that is, a functional group during the SOF forming process.
In the SOF forming process the composition of a functional group will be altered through the loss of atoms, the gain of atoms, or both the loss and the gain of atoms; or, the functional group may be lost altogether. In the SOF, atoms previously associated with functional groups become associated with linker groups, which are the chemical moieties that join together segments. Functional groups have characteristic chemistries and those of ordinary skill in the art can generally recognize in the present molecular building blocks the atom(s) that constitute functional group(s). It should be noted that an atom or grouping of atoms that are identified as part of the molecular building block functional group may be preserved in the linker group of the SOF. Linker groups are described below.
Capping segments of the present disclosure are molecules that ‘interrupt’ the regular network of covalently bonded building blocks normally present in an SOF, and may further incorporate an ionic charging functionality into the SOF network. An SOF including one or more capping segments may also be referred to as capped SOFs. The differences between a SOF and SOFs having capping segments, capping segments having ionic functionality, or molecular building blocks having ionic functionality are illustrated in
Capped SOF compositions or SOF compositions having ionic groups in either the segments or molecular building blocks, or capping segments can provide tunable materials whose properties can be varied through the type and amount of ionic groups introduced. Conventional membranes used in IEC or charged membrane applications are typically made by providing a polymer or network backbone, followed by subsequent introduction of a charge functionality. Examples of the present disclosure provide structured organic networks where during synthesis, ionic or charged capping segments or alternatively ionic or charged molecular building blocks are incorporated into the structured organic network. As noted previously, in certain examples, charge can be either present upon network formation or induced after network formation by a chemical reaction or post-processing step such as, but not limited to those as described herein. For purposes of the present disclosure, a capping segment having an ionic group prior to processing or after processing or formation may be referred to as an ionic capping segment. Furthermore, a molecular building block having an ionic group prior to processing or after processing or formation may be referred to as an ionic molecular building block or ionic building block or ionic segment.
In embodiments, the capping segments have a structure that is unrelated to the structure of any of the molecular building blocks that are added into the SOF formulation, which (after film formation) ultimately becomes the SOF. In other words, a capping segment is the portion of a capping group or capping unit that supports functional groups and comprises atoms that are not associated with functional groups. Further, the composition of a capping segment remains unchanged after SOF formation.
A capping segment molecule has one functional group that has suitable or complementary functional groups (as described above) to participate in a chemical reaction to link to another segment during the SOF forming process. A second chemical moiety that is not suitable or complementary to participate in the specific chemical reaction to link together segments during the SOF forming process and thus cannot bridge any further adjacent molecular building blocks. However, after the SOF is formed such functional groups may be available for further reaction with additional components and thus allowing for the further refining and tuning of the various properties of the formed SOF.
Cationic species such as cationic molecular building block segments and capping groups for use in SOF films useful for anion exchange membranes of the present disclosure can include piperidinium containing SOF films having improved alkaline stability. Illustrative examples of piperidinium compounds useful for providing IEC and alkaline stability to SOF films for anion exchange membranes include bicyclic piperidinium groups, piperidinium-based N-cyclic ammonium, or combinations thereof. Illustrative examples can include, but are not limited to, 3-methanol-6-Azoniaspiro[5.5]undecane bromide (MeASUBr). Additional illustrative examples include piperidinium-based groups having counterions other than bromide, such a chloride, hydroxide, fluoride, bicarbonate, nitrate, acetate, or combinations thereof. Thus, 3-methanol-6-Azoniaspiro[5.5]undecane (MeASU) may be reacted with counterions other than bromide, as described herein. Other illustrative examples include spirobipyrrolidinium and spirobipiperidinium compounds. In other examples, the ionic group can include compounds where the ring structure includes a (CH2)n, where n is a number from 4 to 8. It should be noted that ring stability may be impacted in certain compounds within the range of 4 to 8. In one general example, if n is equal to 5, the compound could be classified as a spirobipyrrolidinium instead of a spirobipiperidinium. In other examples, the compound may include variates of hydroxyl group positions, counter ion salts, and alkyl appendages. Alkyl appendages can be linear or branched, and on any C-position on the rings, or can be a plurality of appendages on a ring. Appendages can include heteroatoms such as nitrogen, oxygen, sulfur, or combinations thereof.
SOFs having capping segments or capping segment precursors may further include capping segments that directly provide an ionically charged functionality, or alternatively can be capping segments that can be induced to have ionic charge during or after film formation processes. While such reactions are possible with piperidinium, spirobipiperidinium, and spirobipyrrolidinium compounds, the charged N+ ion is inherent. In certain examples, various counter ions may be exchanged with the ionically charged functionality.
In embodiments, the SOF may comprise a mixture of capping segments, such as any combination of a first capping segment, a second capping segment, a third capping segment, a fourth capping segment, etc., where the structure of the capping segment varies. In embodiments, the structure of a capping segment or a combination of multiple capping segments may be selected to either enhance or attenuate the chemical and physical properties of SOF; or the identity of the chemical moieties or functional group(s) on that are not suitable or complementary to participate in the chemical reaction to link together segments during the SOF forming process may be varied to form a mixture of capping segments. Thus, the type of capping segment introduced into the SOF framework may be selected to introduce or tune a desired property of SOF.
In embodiments, a SOF contains segments, which are not located at the edges of the SOF, that are connected by linkers to at least three other segments and/or capping groups. For example, in embodiments the SOF comprises at least one symmetrical building block selected from the group consisting of ideal triangular building block segments, distorted triangular building block segments, ideal tetrahedral building block segments, distorted tetrahedral building block segments, ideal square building block segments, and distorted square building block segments. In embodiments, Type 2 and 3 SOFs contains at least two segment types, which are not located at the edges of the SOF, where at least one segment type is connected by linkers to at least three other segments and/or capping groups. For example, in embodiments the SOF comprises at least one symmetrical building block selected from the group consisting of ideal triangular building block segments, distorted triangular building block segments, ideal tetrahedral building block segments, distorted tetrahedral building block segments, ideal square building block segments, and distorted square building block segments.
In embodiments, the SOF comprises a plurality of segments, where all segments have an identical structure, and a plurality of linkers, which may or may not have an identical structure, wherein the segments that are not at the edges of the SOF are connected by linkers to at least three other segments and/or capping groups. In embodiments, the SOF comprises a plurality of segments where the plurality of segments comprises at least a first and a second segment that are different in structure, and the first segment is connected by linkers to at least three other segments and/or capping groups when it is not at the edge of the SOP.
In embodiments, the SOF comprises a plurality of linkers including at least a first and a second linker that are different in structure, and the plurality of segments either comprises at least a first and a second segment that are different in structure, where the first segment, when not at the edge of the SOF, is connected to at least three other segments and/or capping groups, wherein at least one of the connections is via the first linker, and at least one of the connections is via the second linker; or comprises segments that all have an identical structure, and the segments that are not at the edges of the SOF are connected by linkers to at least three other segments and/or capping groups, wherein at least one of the connections is via the first linker, and at least one of the connections is via the second linker.
In embodiments, the capping segments have a structure that substantially corresponds to the structure of one of the molecular building blocks (such as the molecular building blocks for SOFs that are detailed in U.S. Pat. Nos. 8,093,347; 8,436,130; 8,357,432; 8,394,495; 8,389,060; 8,318,892; and 9,097,995, which have been incorporated by reference) that is added to the SOF formulation, but one or more of the functional groups present on the building block is either missing or has been replaced with a different chemical moiety or functional group that will not participate in a chemical reaction (with the functional group(s) of the building blocks that are initially present) to link together segments during the SOF forming process.
A capping segment having a structure unrelated to the molecular building block or segment in the SOF may be, for example, an alkyl moiety (for example, a branched or unbranched saturated hydrocarbon group, derived from an alkane and having the general formula CnH2n+1, in which n is a number of 1 or more) in which one of the hydrogen atoms has been replaced by an —OH group. In such a formulation, a reaction between the capping segment and the molecular building block or segment, for example, a reaction between the alcohol (—OH) groups, would link the capping segment and the molecular building blocks together through the formation of (linking) ether groups. Other functional group reactions as described herein are applicable as well.
In embodiments, the capping segment molecules are mono-functionalized. For example, in embodiments, the capping segments comprise only a single suitable or complementary functional group (as described above) that participates in a chemical reaction to link together segments during the SOF forming process and thus cannot bridge any further adjacent molecular building blocks (until a building block with a suitable or complementary functional group is added, such as when an additional SOF is formed on top of a capped SOF base layer and a multilayer SOF is formed).
When such capping segments are introduced into the SOF coating formulation, upon curing, interruptions in the SOF framework are introduced. Interruptions in the SOF framework are therefore sites where the single suitable or complementary functional group of the capping segments have reacted with the molecular building block and locally terminate (or cap) the extension of the SOF framework and interrupt the regular network of covalently bonded building blocks normally present in an SOF. The type of capping segments (or structure of the capping segment) introduced into the SOF framework may be used to tune the properties of the SOF.
In embodiments, the capping segment molecules may comprise more than one chemical moiety or functional group. For example, the SOF coating formulation, which (after film formation), ultimately becomes bonded in the SOF may comprise a capping segment having at least two or more chemical moieties or functional groups, such as 2, 3, 4, 5, 6 or more chemical moieties or functional groups, where only one of the functional groups is a suitable or complementary functional group (as described above) that participates in a chemical reaction to link together segments during the SOF forming process. The various other chemical moieties or functional groups present on the molecular building block are chemical moieties or functional groups that are not suitable or complementary to participate in the specific chemical reaction to link together segments initially present during the SOF forming process and thus cannot bridge any further adjacent molecular building blocks. However, after the SOF is formed such chemical moieties and/or functional groups may be available for further reaction (similar to dangling functional groups, as discussed below) with additional components and thus allow for the further refining and tuning of the various properties of the formed SOF, or chemically attaching various other SOF layers in the formation of multilayer SOFs.
In embodiments, the molecular building blocks may have x functional groups (where x is two or more), with at least one molecular building block type having at least three functional groups) and the capping segment molecules may comprise a capping segment molecule having 1 functional groups that are suitable or complementary functional group (as described above) and participate in a chemical reaction to link together segments during the SOF forming process. For example, x would be three for tris-(4-hydroxymethyl)triphenylamine (above), and x would be four for the building block illustrated below, N,N,N′,N′-tetrakis-[(4-hydroxymethyl)phenyl]-biphenyl-4,4′-diamine (THM-TBD):
or
A segment is the portion of the molecular building block that supports functional groups and comprises all atoms that are not associated with functional groups. Further, the composition of a molecular building block segment remains unchanged after SOF formation. In embodiments, the SOF may contain a first segment having a structure the same as or different from a second segment. In other embodiments, the structures of the first and/or second segments may be the same as or different from a third segment, forth segment, fifth segment, etc. A segment is also the portion of the molecular building block that can provide an inclined property. Inclined properties are described later in the embodiments.
In specific embodiments, the segment of the SOF comprises at least one atom of an element that is not carbon, such at least one atom selected from the group consisting of hydrogen, oxygen, nitrogen, silicon, phosphorous, selenium, fluorine, boron, and sulfur.
A description of various exemplary molecular building blocks, linkers, SOF types, strategies to synthesize a specific SOF type with exemplary chemical structures, building blocks whose symmetrical elements are outlined, and classes of exemplary molecular entities and examples of members of each class that may serve as molecular building blocks or other components for SOFs are detailed in U.S. Pat. Nos. 8,093,347; 8,436,130; 8,357,432; 8,394,495; 8,389,060; 8,318,892; and 9,097,995, the disclosures of which are totally incorporated herein by reference in their entireties.
A linker is a chemical moiety that emerges in a SOF upon chemical reaction between functional groups present on the molecular building blocks and/or capping segments.
A linker may comprise a covalent bond, a single atom, or a group of covalently bonded atoms. The former is defined as a covalent bond linker and may be, for example, a single covalent bond or a double covalent bond and emerges when functional groups on all partnered building blocks are lost entirely. The latter linker type is defined as a chemical moiety linker and may comprise one or more atoms bonded together by single covalent bonds, double covalent bonds, or combinations of the two. Atoms contained in linking groups originate from atoms present in functional groups on molecular building blocks prior to the SOF forming process. Chemical moiety linkers may be well-known chemical groups such as, for example, esters, ketones, amides, imines. ethers, urethanes, carbonates, and the like, or derivatives thereof.
For example, when two hydroxyl (—OH) functional groups are used to connect segments in a SOF via an oxygen atom, the linker would be the oxygen atom, which may also be described as an ether linker. In embodiments, the SOF may contain a first linker having a structure the same as or different from a second linker. In other embodiments, the structures of the first and/or second linkers may be the same as or different from a third linker, etc.
A capping segment may be bonded in the SOF in any desired amount as long as the general SOF framework is sufficiently maintained. For example, in embodiments, a capping segment may be bonded to at least 0.1% of all linkers, but not more than about 40% of all linkers present in an SOF, such as from about 0.5% to about 30%, or from about 2% to about 20%. In embodiments, substantially all segments may be bound to at least one capping segment, where the term “substantially all” refers, for example, to more than about 95%, such as more than about 99% of the segments of the SOF. In the event capping segments bond to more than 50% of the available functional groups on the molecular building blocks (from which the linkers emerge), oligomers, linear polymers, and molecular building blocks that are fully capped with capping segments may predominately form instead of a SOF. In certain examples of SOFs, capping segments may be quantitatively expressed in terms of mol %, concentration, or as ratios compared to either a segment composition or of an entire SOF composition.
In specific embodiments, the linker comprises at least one atom of an element that is not carbon, such at least one atom selected from the group consisting of hydrogen, oxygen, nitrogen, silicon, phosphorous, selenium, fluorine, boron, and sulfur.
SOFs have any suitable aspect ratio. In embodiments, SOFs have aspect ratios for instance greater than about 30:1 or greater than about 50:1, or greater than about 70:1, or greater than about 100:1, such as about 1000:1. The aspect ratio of a SOF is defined as the ratio of its average width or diameter (that is, the dimension next largest to its thickness) to its average thickness (that is, its shortest dimension). The term ‘aspect ratio,’ as used here, is not bound by theory. The longest dimension of a SOF is its length and it is not considered in the calculation of SOF aspect ratio.
Generally, SOFs have widths and lengths, or diameters greater than about 500 micrometers, such as about 10 mm, or 30 mm. The SOFs have the following illustrative thicknesses: about 10 Angstroms to about 250 Angstroms, such as about 20 Angstroms to about 200 Angstroms, for a mono-segment thick layer and about 20 nm to about 5 mm, about 50 nm to about 10 mm for a multi-segment thick layer.
SOF dimensions may be measured using a variety of tools and methods. For a dimension about 1 micrometer or less, scanning electron microscopy is the preferred method. For a dimension about 1 micrometer or greater, a micrometer (or ruler) is the preferred method.
A SOF may comprise a single layer or a plurality of layers (that is, two, three or more layers). SOFs that are comprised of a plurality of layers may be physically joined (e.g., dipole and hydrogen bond) or chemically joined. Physically attached layers are characterized by weaker interlayer interactions or adhesion; therefore physically attached layers may be susceptible to delamination from each other. Chemically attached layers are expected to have chemical bonds (e.g., covalent or ionic bonds) or have numerous physical or intermolecular (supramolecular) entanglements that strongly link adjacent layers.
Therefore, delamination of chemically attached layers is much more difficult. Chemical attachments between layers may be detected using spectroscopic methods such as focusing infrared or Raman spectroscopy, or with other methods having spatial resolution that can detect chemical species precisely at interfaces. In cases where chemical attachments between layers are different chemical species than those within the layers themselves it is possible to detect these attachments with sensitive bulk analyses such as solid-state nuclear magnetic resonance spectroscopy or by using other bulk analytical methods.
In the embodiments, the SOF may be a single layer (mono-segment thick or multi-segment thick) or multiple layers (each layer being mono-segment thick or multi-segment thick). “Thickness” refers, for example, to the smallest dimension of the film. As discussed above, in a SOF, segments are molecular units that are covalently bonded through linkers to generate the molecular framework of the film. The thickness of the film may also be defined in terms of the number of segments that is counted along that axis of the film when viewing the cross-section of the film. A “monolayer” SOF is the simplest case and refers, for example, to where a film is one segment thick. A SOF where two or more segments exist along this axis is referred to as a “multi-segment11 thick SOF.
An exemplary method for preparing physically attached multilayer SOFs includes: (1) forming a base SOF layer that may be cured by a first curing cycle, and (2) forming upon the base layer a second reactive wet layer followed by a second curing cycle and, if desired, repeating the second step to form a third layer, a fourth layer and so on. The physically stacked multilayer SOFs may have thicknesses greater than about 20 Angstroms such as, for example, the following illustrative thicknesses: about 20 Angstroms to about 10 mm, such as about 1 nm to about 10 mm, or about 0.1 mm Angstroms to about 5 mm. In principle there is no limit with this process to the number of layers that may be physically stacked. Alternative examples of SOFs according to the present disclosure include free-standing films. The free-standing film thickness can be from about 1 μm to about 500 μm, or from about 10 μm to about 250 μm, or from about 100 μm to about 150 μm.
In embodiments, a multilayer SOF is formed by a method for preparing chemically attached multilayer SOFs by: (1) forming a base SOF layer having functional groups present on the surface (or dangling functional groups) from a first reactive wet layer, and (2) forming upon the base layer a second SOF layer from a second reactive wet layer that comprises molecular building blocks with functional groups capable of reacting with the dangling functional groups on the surface of the base SOF layer. In further embodiments, a capped SOF may serve as the base layer in which the functional groups present that were not suitable or complementary to participate in the specific chemical reaction to link together segments during the base layer SOF forming process may be available for reacting with the molecular building blocks of the second layer to form a chemically bonded multilayer SOF. If desired, the formulation used to form the second SOF layer should comprise molecular building blocks with functional groups capable of reacting with the functional groups from the base layer as well as additional functional groups that will allow for a third layer to be chemically attached to the second layer. The chemically stacked multilayer SOFs may have thicknesses greater than about 20 Angstroms such as, for example, the following illustrative thicknesses: about 20 Angstroms to about 10 mm, such as about 1 nm to about 10 mm, or about 0.1 mm Angstroms to about 5 mm. In principle there is no limit with this process to the number of layers that may be chemically stacked.
In embodiments, the method for preparing chemically attached multilayer SOFs comprises promoting chemical attachment of a second SOF onto an existing SOF (base layer) by using a small excess of one molecular building block (when more than one molecular building block is present) during the process used to form the SOF (base layer) whereby the functional groups present on this molecular building block will be present on the base layer surface. The surface of base layer may be treated with an agent to enhance the reactivity of the functional groups or to create an increased number of functional groups.
In an embodiment the dangling functional groups or chemical moieties present on the surface of an SOF or capped SOF may be altered to increase the propensity for covalent attachment (or, alternatively, to disfavor covalent attachment) of particular classes of molecules or individual molecules, such as SOFs, to a base layer or any additional substrate or SOF layer. For example, the surface of a base layer, such as an SOF layer, which may contain reactive dangling functional groups, may be rendered pacified through surface treatment with a capping chemical group. For example, a SOF layer having dangling hydroxyl alcohol groups may be pacified by treatment with trimethylsiylchloride thereby capping hydroxyl groups as stable trimethylsilylethers. Alternatively, the surface of base layer may be treated with a non-chemically bonding agent, such as a wax, to block reaction with dangling functional groups from subsequent layers.
Molecular building block symmetry relates to the positioning of functional groups (Fgs) around the periphery of the molecular building block segments. Without being bound by chemical or mathematical theory, a symmetric molecular building block is one where positioning of Fgs may be associated with the ends of a rod, vertexes of a regular geometric shape, or the vertexes of a distorted rod or distorted geometric shape. For example, the most symmetric option for molecular building blocks containing four Fgs are those whose Fgs overlay with the comers of a square or the apexes of a tetrahedron.
Use of symmetrical building blocks is practiced in embodiments of the present disclosure for two reasons: (1) the patterning of molecular building blocks may be better anticipated because the linking of regular shapes is a better understood process in reticular chemistry, and (2) the complete reaction between molecular building blocks is facilitated because for less symmetric building blocks errant conformations/orientations may be adopted which can possibly initiate numerous linking defects within SOFs.
In embodiments, a Type 1 SOF contains segments, which are not located at the edges of the SOF, that are connected by linkers to at least three other segments. For example, in embodiments the SOF comprises at least one symmetrical building block selected from the group consisting of ideal triangular building blocks, distorted triangular building blocks, ideal tetrahedral building blocks, distorted tetrahedral building blocks, ideal square building blocks, and distorted square building blocks. In embodiments, Type 2 and 3 SOF contains at least one segment type, which are not located at the edges of the SOF, that are connected by linkers to at least three other segments. For example, in embodiments the SOF comprises at least one symmetrical building block selected from the group consisting of ideal triangular building blocks, distorted triangular building blocks, ideal tetrahedral building blocks, distorted tetrahedral building blocks, ideal square building blocks, and distorted square building blocks.
In embodiments linking chemistry may occur wherein the reaction between functional groups produces a volatile byproduct that may be largely evaporated or expunged from the SOF during or after the film forming process or wherein no byproduct is formed. Linking chemistry may be selected to achieve a SOF for applications where the presence of linking chemistry byproducts is not desired. Linking chemistry reactions may include, for example, condensation, addition/elimination, and addition reactions, such as, for example, those that produce esters, imines, ethers, carbonates, urethanes, amides, acetals, and silyl ethers.
In embodiments the linking chemistry via a reaction between function groups producing a non-volatile byproduct that largely remains incorporated within the SOF after the film forming process. Linking chemistry in embodiments may be selected to achieve a SOF for applications where the presence of linking chemistry byproducts does not impact the properties or for applications where the presence of linking chemistry byproducts may alter the properties of a SOF (such as, for example, the electroactive, hydrophobic or hydrophilic nature of the SOF). Linking chemistry reactions may include, for example, substitution, metathesis, and metal catalyzed coupling reactions, such as those that produce carbon-carbon bonds.
For all linking chemistry the ability to control the rate and extent of reaction between building blocks via the chemistry between building block functional groups is an important aspect of the present disclosure. Reasons for controlling the rate and extent of reaction may include adapting the film forming process for different coating methods and tuning the microscopic arrangement of building blocks to achieve a periodic SOF, as defined in earlier embodiments.
COFs have innate properties such as high thermal stability (typically higher than 400° C. under atmospheric conditions); poor solubility in organic solvents (chemical stability), and porosity (capable of reversible guest uptake). In embodiments, SOFs may also possess these innate properties.
Added functionality denotes a property that is not inherent to conventional COFs or SOFs and may occur by the selection of molecular building blocks wherein the molecular compositions provide the added functionality in the resultant SOF. Added functionality may arise upon assembly of molecular building blocks and/or capping segments having an “inclined property” for that added functionality. Added functionality may also arise upon assembly of molecular building blocks having no “inclined property” for that added functionality but the resulting SOF has the added functionality as a consequence of linking segments (S) and linkers into a SOF. In embodiments, added functionality may also arise upon the addition and assembly of molecular building blocks and capping segments having no “inclined property” for that added functionality but the resulting SOF has the added functionality as a consequence of linking segments, linkers, and capping segments into a SOF. Furthermore, emergence of added functionality may arise from the combined effect of using molecular building blocks bearing an “inclined property” for that added functionality whose inclined property is modified or enhanced upon linking together the segments and linkers into a SOF.
The term “inclined property” of a molecular building block refers, for example, to a property known to exist for certain molecular compositions or a property that is reasonably identifiable by a person skilled in art upon inspection of the molecular composition of a segment. As used herein, the terms “inclined property” and “added functionality” refer to the same general property (e.g., hydrophobic, electroactive, etc.) but “inclined property” is used in the context of the molecular building block and “added functionality” is used in the context of the SOF.
The hydrophobic (superhydrophobic), hydrophilic, lipophobic (superlipophobic), lipophilic, photochromic and/or electroactive (conductor, semiconductor, charge transport material) nature of an SOF are some examples of the properties that may represent an “added functionality” of an SOP. These and other added functionalities may arise from the inclined properties of the molecular building blocks or may arise from building blocks that do not have the respective added functionality that is observed in the SOF.
The term hydrophobic (superhydrophobic) refers, for example, to the property of repelling water, or other polar species such as methanol, it also means an inability to absorb water and/or to swell as a result. Furthermore, hydrophobic implies an inability to form strong hydrogen bonds to water or other hydrogen bonding species. Hydrophobic materials are typically characterized by having water contact angles greater than 90° and superhydrophobic materials have water contact angles greater than 150° as measured using a contact angle goniometer or related device.
The term hydrophilic refers, for example, to the property of attracting, adsorbing, or absorbing water or other polar species, or a surface that is easily wetted by such species. Hydrophilic materials are typically characterized by having less than 20° water contact angle as measured using a contact angle goniometer or related device. Hydrophilicity may also be characterized by swelling of a material by water or other polar species, or a material that can diffuse or transport water, or other polar species, through itself. Hydrophilicity, is further characterized by being able to form strong or numerous hydrogen bonds to water or other hydrogen bonding species.
The term lipophobic (oleophobic) refers, for example, to the property of repelling oil or other non-polar species such as alkanes, fats, and waxes. Lipophobic materials are typically characterized by having oil contact angles greater than 90° as measured using a contact angle goniometer or related device.
The term lipophilic (oleophilic) refers, for example, to the property attracting oil or other non-polar species such as alkanes, fats, and waxes or a surface that is easily wetted by such species. Lipophilic materials are typically characterized by having a low to nil oil contact angle as measured using, for example, a contact angle goniometer. Lipophilicity can also be characterized by swelling of a material by hexane or other non-polar liquids.
The term photochromic refers, for example, to the ability to demonstrate reversible color changes when exposed to electromagnetic radiation. SOF compositions containing photochromic molecules may be prepared and demonstrate reversible color changes when exposed to electromagnetic radiation. These SOFs may have the added functionality of photochromism. The robustness of photochromic SOFs may enable their use in many applications, such as photochromic SOFs for erasable paper, and light responsive films for window tinting/shading and eyewear. SOF compositions may contain any suitable photochromic molecule, such as a difunctional photochromic molecules as SOF molecular building blocks (chemically bound into SOF structure), a monofunctional photochromic molecules as SOF capping segments (chemically bound into SOF structure, or unfunctionalized photochromic molecules in an SOF composite (not chemically bound into SOF structure). Photochromic SOFs may change color upon exposure to selected wavelengths of light and the color change may be reversible.
SOF compositions containing photochromic molecules that chemically bond to the SOF structure are exceptionally chemically and mechanically robust photochromic materials. Such photochromic SOF materials demonstrate many superior properties, such as high number of reversible color change processes, to available polymeric alternatives.
SOFs having a rough, textured, or porous surface on the sub-micron to micron scale may be hydrophobic. The rough, textured, or porous SOF surface can result from dangling functional groups present on the film surface or from the structure of the SOF. The type of pattern and degree of patterning depends on the geometry of the molecular building blocks and the linking chemistry efficiency. The feature size that leads to surface roughness or texture is from about 100 nm to about 10 μm, such as from about 500 nm to about 5 μm.
The process for making ionic SOFs (which may be referred to as an “SOF” below) typically comprises a similar number of activities or steps (set forth below) that are used to make a non-ionic SOF. The ionic segment may be added during either step a, b or c depending the desired distribution of the ionic segment in the resulting SOF. For example, if it is desired that the ionic segment distribution is substantially uniform over the resulting SOF, the ionic segment may be added during step a. Alternatively, if, for example, a more heterogeneous distribution of the ionic segment is desired, adding the ionic segment (such as by spraying it on the film formed during step b or during the promotion step of step c) may occur during steps b and c. Alternatively, the ionic segment may be innately ionic, or can be subjected to an additional post-processing step, e.g., after step c) to add or react with a capping segment or molecular building block to provide an ionic group.
The process for making SOFs typically comprises a number of activities or steps (set forth below) that may be performed in any suitable sequence or where two or more activities are performed simultaneously or in close proximity in time:
The above activities or steps may be conducted at atmospheric, super atmospheric, or subatmospheric pressure. The term “atmospheric pressure” as used herein refers to a pressure of about 760 torr. The term super atmospheric, refers to pressures greater than atmospheric pressure, but less than 20 atm. The term “subatmospheric pressure” refers to pressures less than atmospheric pressure. In an embodiment, the activities or steps may be conducted at or near atmospheric pressure. Generally, pressures of from about 0.1 atm to about 2 atm, such as from about 0.5 atm to about 1.5 atm, or 0.8 atm to about 1.2 atm may be conveniently employed. Further considerations related to the aforementioned process steps or processes for preparing or fabricating SOFs are detailed in U.S. Pat. Nos. 8,093,347; 8,436,130; 8,357,432; 8,394,495; 8,389,060; 8,318,892; and 9,097,995, the disclosures of which are totally incorporated herein by reference in their entireties.
Examples of the present disclosure include various CEM and AEM-type SOFs which have been made to evaluate the ion exchange capacity (IEC) of these materials. The IEC is a parameter that provides the number of cationic groups for AEMs or the number of anionic groups for CEMs based on number of equivalents (frequently milliequivalents) per gram of dry membrane. IEC is an ion-exchange capacity, also referred to as a charge per mass of polymer expressed either in milliequivalents of charge per gram of polymer, meq/g. In certain examples, a doubly charged ion within the polymer has twice the equivalents of charge as compared to a singly charged ion.
As described herein, a variety of ionic molecules, or ionic molecule precursors, that can be used as molecular building blocks or capping groups can be combined with one of the two aromatic building block molecules (THM-TBD or TME-TBD) as described previously. The reaction mechanisms employed in the examples are based on the formation of ether linkages (transetherification) but the reaction linkages can be extended to B—O (boroxine, boronate ester, spiroborate, and borosilicate), C═N (imine, hydrazone, and squaraine), C—N (β-ketoenamine, imide, and amide), in other examples. Examples of the present disclosure include ionic capping segments added to SOFs based on molar equivalents. A molar equivalent is a ratio of moles of a capping segment, such as 3-methanol-6-Azoniaspiro[5.5]undecane bromide, to moles of a molecular building block, such as THM-TBD. This ratio or concentration of capping segments to segments can be from about 0.5, to about 10.0, or from about 1.0 to about 5.0, or from about 1.0 to about 2.5, based on a total concentration of segments in the SOF. This ratio or concentration of capping segments to segments can be from about 0.5, to about 10.0, or from about 1.0 to about 5.0, or from about 1.0 to about 2.5. Molar equivalents of ionic capping segments as compared to non-ionic segments, or nonionic segments, can also be from about 0.5, to about 10.0, or from about 1.0 to about 5.0, or from about 1.0 to about 2.5. The upper limit of ionic capping group segments depends on the number of reactive functional group sites on a given molecular building block segment. It cannot exceed n−2, where n is the number of reactive functional groups on a molecular building block segment, otherwise a linear polymer or small molecules can form.
Comparative Example 1 describes anion exchange membranes made from poly-(p-phenyleneoxide) polymers with N-cyclic quaternary ammonium cations. The synthetic process to produce an alkyne containing ammonium functional group followed by polymerization is a labor intensive and lengthy process. The resulting materials provide good alkaline stability and IEC values comparable with commercially available materials, with IEC values ranging from about 1.2 to about 2.0 meq/g.
An example synthetic route of alkynyl-terminated structural unit is shown in the following reaction scheme:
An example reaction scheme for a synthesis of N-cyclic ammonium containing polymers is shown below. 4-ethynyl-piperidine-1-carboxylic acid tert-butyl ester (EP-Boc) and its hydrochloride salt (4-ethynyl-piperidine hydrochloride, EP-HCl) were synthesized by the “Ohira-Bestmann” reaction. The alkyne-terminated piperidinium (4-ethynyl-1,1-dimethyl-piperidinium iodide, EDMP) or N-spirobicyclic quaternary ammonium (3-ethynyl-6-azonia-spiro[5.5]undecan-6-ium bromide, EASU) were prepared:
Azided poly (2,6-dimethyl phenylene oxide) (PPO-N3) with different degrees of functionalization (DF) in the range of 20%-40% were prepared. Anion-conductive PPOs having pendent piperidinium (PPO-DMP) and N-spirocyclic QA (PPO-ASU) groups were then prepared via Cu(I)-catalyzed click chemistry.
Comparative Example 2 1 describes Sustainion®, a commercially available AEM, which is based on the free radical polymerization of styrene and vinyl benzyl chloride that is then functionalized with 1,2,4,5-tetramethylimidazole in a Dowanol PM (1-methoxy-2 propanol) solvent. Divinylbenzene is also added as a crosslinker to help improve the membrane's strength. This membrane class from Dioxide Materials™ is reported to have typical IECs ranging from 0.6 to 1.2 mEq/g depending on the grade chosen. A representative reaction scheme is depicted below:
Control Example 1—SOF Synthesized from THM-TBD Building Block and No Charged Species: Dowanol PM (1-methoxy-2-propanol, 9.0190 g), Nacure 5225 (0.0127, 0.25 wt. %), Silclean 3700 (0.0501, 1.0 wt. %) and THM-TBD (0.9878 g, 98.75 wt. %) were added to a 4 dram vial in the stated order. The vial was placed in a block heater and heated at 65° C. for 90 minutes. Three grams of solution was then cured at 120° C. for 40 minutes in an aluminum pan. The IEC value of this film was 0 mEq/g (measured by manual titration), as expected due to an absence of charged groups.
A 200 mL bomb flask was purged with argon. To the flask was added 1,2,4,5-tetramethylimidazole (3.73 g, 30 mmol), 60 mL dry toluene and 2-bromoethanol (4.87 g, 39 mmol). The flask was sealed, heated to 75° C. and stirred for 72 hours. After the reaction time, there was an oil phase (product) at the bottom of the flask. To the reaction mixture was added 20 mL of deionized (DI) water. The aqueous phase was collected and washed with 2×20 mL of ethyl acetate to give light yellow oil. Oil triturated with 20 mL of ethyl acetate to give white powder (6.88 g, 92% yield). Films using the NEtTMImBr as an ionic capping segment, Control Example 2, were produced according to the details listed in Table 1.
A 200 mL bomb flask was purged with argon. To the flask was added 4-methanolpiperidine (2.3 g, 20 mmol), 1,5-dibromopentane (22.99 g, 100 mmol), potassium carbonate (5.11 g, 37 mmol), 37.5 mL dry toluene and 12.5 mL dry methanol. The flask was sealed, heated to 60° C. and stirred for 20 hours. After the reaction time, the potassium carbonate was removed via filtration. To the filtrate was added 100 mL of ethyl acetate with stirring to precipitate the product. The precipitate was then filtered to afford a white powder (4.47 g, 85%).
THM-TBD (1.08 g, 1.82 mmol) and MeASUBr (0.47 g, 1.82 mmol) dissolved in 6.4 g DMSO. Sonicated for 20 min to ensure dissolution. After the sonication of the THM-TBD solution, the pTSA catalyst (0.048 g, 0.28 mmol) was then added to vial and shaken until fully dissolved. Further details of the formulation are listed in Table 2.
The preceding reaction scheme of network formation with THM-TBD and piperidinium ionic capping segment is shown, as well as the reaction that occurs during the curing process of the SOF formulations. Upon addition of an acid catalyst and exposure to heat, the building block and capping group undergo a condensation reaction to produce an ether-linked cationic network.
MeASUBr-containing SOF formulations, as described in Example 1, were coated using slot die coating onto 2 PEEK fiber screens. The two screens can be classified as 35 μm (fine) and 220 μm (coarse), which refers to the distance between adjacent fibers. The 35 μm screen has an open area of 22% while the 220 μm screen has an open area of 56%. Samples as described in Table 3, below, such as EXP-21-AC1586, were coated on 220 um PEEK screen with flow rate of 20 μL/s and speed of 3 mm/s, then cured at 180° C. for 30 minutes. It can be observed in general that the formulation with the MeASUBr building block, denoted as, AC1586 provides exemplary continuous films on the highly porous 220 um PEEK screens, with few to no defects observed in the cured films.
As shown in Table 3, the coatings made with NEtTMImBr showed very good IEC values with 0.94 meq/g at 2 equivalents loading of the ionic capping segment. However, these materials can be prone to degradation when exposed to alkaline conditions. The SOF coatings made with MeASUBr show similar, or slightly better, IEC values (1.26 meq/g at 2 equivalents loading) while also possessing exceptional alkaline stability. Other THM-TBD films functionalized with cationic groups such as methyl triethanol ammonium hydroxide (MTEAH) have reached IEC values as high as 0.357. This shows the potential for high ion exchange capabilities of these N-cyclic ammonium cations in highly crosslinked SOF networks. By comparison, the commercial AEM, tetramethylimidazolium chloride functionalized Sustainion has an IEC value of 1.16. The ionic SOF materials comprised within show similar ion conductivity with relatively low imidazolium content and enhanced mechanical and resistive properties due to the crosslinked network of the film. It should be noted that mixtures of cationic groups, such as, but not limited to NEtTMImBr, MeASU, MeASUBr, MTEAH, or combinations thereof may be used in a single SOF film composition. In embodiments, the present SOF can include ionic capping segments that include one type of piperidium group, other ionic capping segments that include a different piperidinium group or a non-piperidium cationic species, or both. Additional illustrative examples include piperidinium-based or non-piperidinium based groups having counterions other than bromide, such a chloride, hydroxide, fluoride, bicarbonate, nitrate, acetate, or combinations thereof.
Examples of the present disclosure provide structured organic films (SOF) composed of building blocks where at least one building block or segment is uncharged with 4 functional groups for linking and a second building block or capping segment containing a charged (or ionic), or ionic precursor species and at least one functional group for linking. The charged species can have 1 to 4 functional groups, where in certain examples the Fg is —OH, creating either an network with charged end-capped species or else can be part of the internal SOF network if fg>1. Structured organic films for use as anionic exchange membranes including N-cyclic quaternary ammonium based cationic species with ion exchange capacity (IEC) according to the present disclosure have been demonstrated. The free-standing SOF films are able to facilitate the preferential transport of counter-ions as measured by IEC, and in some examples are advantaged over commercially known materials, and are chemically stable in highly alkaline solutions and organic solvents such as THF. Applications of SOFs of the present disclosure include systems for electrochemical energy conversion and separation devices such as fuel cells, redox flow batteries, electrodialysis, reverse electrodialysis, water electrolysis and electrosynthesis.
While the present teachings have been illustrated with respect to one or more implementations, alterations and/or modifications may be made to the illustrated examples without departing from the spirit and scope of the appended claims. For example, it may be appreciated that while the process is described as a series of acts or events, the present teachings are not limited by the ordering of such acts or events. Some acts may occur in different orders and/or concurrently with other acts or events apart from those described herein. Also, not all process stages may be required to implement a methodology in accordance with one or more aspects or embodiments of the present teachings. It may be appreciated that structural objects and/or processing stages may be added, or existing structural objects and/or processing stages may be removed or modified. Further, one or more of the acts depicted herein may be carried out in one or more separate acts and/or phases. Furthermore, to the extent that the terms “including,” “includes,” “having,” “has,” “with,” or variants thereof are used in either the detailed description and the claims, such terms are intended to be inclusive in a manner similar to the term “comprising.” The term “at least one of” is used to mean one or more of the listed items may be selected. Further, in the discussion and claims herein, the term “on” used with respect to two materials, one “on” the other, means at least some contact between the materials, while “over” means the materials are in proximity, but possibly with one or more additional intervening materials such that contact is possible but not required. Neither “on” nor “over” implies any directionality as used herein. The term “conformal” describes a coating material in which angles of the underlying material are preserved by the conformal material. The term “about” indicates that the value listed may be somewhat altered, as long as the alteration does not result in nonconformance of the process or structure to the illustrated embodiment. The terms “couple,” “coupled,” “connect,” “connection,” “connected,” “in connection with,” and “connecting” refer to “in direct connection with” or “in connection with via one or more intermediate elements or members.” Finally, the terms “exemplary” or “illustrative” indicate the description is used as an example, rather than implying that it is an ideal. Other embodiments of the present teachings may be apparent to those skilled in the art from consideration of the specification and practice of the disclosure herein. It is intended that the specification and examples be considered as exemplary only, with a true scope and spirit of the present teachings being indicated by the following claims.
