Recent Advances in Crystalline Oxidopolyborate Complexes of d-Block or p-Block Metals: Structural Aspects, Syntheses, and Physical Properties

Abstract

Crystalline materials containing hybrid inorganic–organic metal borates (complexes with oxidoborate ligands) display a variety of novel framework building blocks. The structural aspects of these hybrid metallaoxidoborates containing Cd^(II), Co^(II), Cu^(II), Ga^(III), In^(III), Mn^(II), Ni^(II) or Zn^(II) metal centers are discussed in this review. The review describes synthetic approaches to these hybrid materials, their physical properties, their spectroscopic properties and their potential applications.

1. Introduction

In borate chemistry (n.b. oxidoborate is the recommended IUPAC name for oxidized oxygen containing borates [1]) the boron centers are bound to oxygen atoms as sp² hybridized triangular {BO₃} (Δ) or sp³ hybridized {BO₄} tetrahedral (T) structural units [2,3,4]. These fundamental units can be aggregated, employing organic cations or transition-metal cations as templating agents [5], with condensation and oxygen atom corner sharing into larger oxidoborate clusters. In these structures, terminal oxygen atoms (i.e., those not corner shared) are generally also bound to hydrogen atoms as hydroxy groups [2,3,4]. Such oxidoborates are often described as hydrated borates [6] and these compounds are readily formed under relatively mild conditions [2,3,4,5,6]. Harsher conditions can lead to anhydrous borates and although very rare, even to the possibility of edge sharing oxygen atoms [7]. Descriptors have been developed by Christ and Clark [2] and by Burns and co-workers [4] to designate reoccurring structural motifs as framework building blocks (FBBs) and Christ and Clark’s descriptors [2] are used in this review. Hydrated oxidiborates may enter the primary coordination shell of metals, with formation of O-donor coordinate bonds with the result of even more complex and diverse species. Coordination compounds containing oxidopolyborate ligands are therefore an important sub-class of synthetic oxidoborate compounds and recent progress in this area is the subject of this review. Since insular oxidopolyborate anions partnered by cationic transition-metal complexes do not contain oxidoborates as ligands they are not within the scope of this review and are excluded. Metal complexes often contain more than one ligand type and those that contain oxidoborate ligands and conventional organic ligands with typical donor atoms may also be classified as inorganic–organic hybrid materials [8,9]. Such hybrid compounds may potentially have unique and useful properties as a result of combining and/or enhancing properties associated with non-hybrid single materials.

This review is designed to be comprehensive within the defined topic and covers recently reported (twenty-first century) literature. It reports on structural chemistry, synthetic methods, physical properties and possible applications and focusses on complexes containing oxidoborate ligands. The following d-block and p-block metal ions form such complexes: Cd^(II), Co^(II), Cu^(II), Ga^(III), In^(III), Mn^(II), Ni^(II) and Zn^(II) and subsections are dedicated to each metal. Oxidoborate ligands are discussed by increasing boron number within these metal borate subsections. Compounds containing oxidoborates ligands were first reported in the twentieth century and for information on such compounds the reader is referred to an earlier review [3] which surveys general structural aspects of oxidoborate chemistry.

2. Structural (XRD) Studies

2.1. Cadmium(II) Borates

Several oxidoborate coordination compounds of Cd^(II) have been reported during the review period: [Cd(dab)_0.5(dab’)_0.5{B₅O₇(OH)₃}]_n (1) (dab = 1,4-diaminobutane) [8], [Cd(dap)_0.5(dap’)_0.5{B₅O₈(OH)}]_n·nH₂O (2) (1,3-diaminopropane) [9], [Cd(tren){B₈O₁₁(OH)₄}]_n (3) (tren) = tris(2-aminoethyl)amine) [10], [Cd(pn){B₆O₇(OH)₆}]_n·nH₂O (4) (pn = 1,2-diaminopropane) [11], [{Cd₃(H₂O)₄(NO₃)₂}{B₆O₉(OH)₂}₂]_n (5) [12] and four related compounds, exemplified by [pyH]₂[Cd(py)₂{B₁₄O₂₀(OH)₆}](6) (py = pyridine) [13].The FBB’s in these compounds are mostly complex with the pentaborate(2-) unit in 1 is based on a FBB of 4(4-1) with a pendant -B(OH)₂ unit (FBB = 1) replacing a terminal H atom on a T unit of the larger FBB and can be designated a compounded descriptor 5:[4:(2Δ+2T)+Δ]. The FBB for 2 is based on the pentaborate(2-) unit 5:(3Δ+2T). The octaborate(2-) and the tetradecaborate(4-) FBBs in 3 and 6 are also best designated as compounded descriptors 8:[5:(4Δ+T)+3:(2Δ+T)] and 14:[{7:(5Δ+2T)}₂] respectively, with the latter dimer based on a FBB unit of 7. The condensed hexaborate(2-) units in 4 and 5 have a more standard descriptor based on a FBB unit of 6 i.e., 6:(2Δ+3T).

Compound 1 is a hybrid inorganic–organic 3-D coordination polymer [8]. The 22-electron Cd^(II) center adopts a distorted six-coordinate octahedral complex with two trans N-donor from two different 1,4-dab ligands (forming a 1-D chain) and four O-donor atoms from two oxidoborate network ligands (Figure 1a).

Compound 2 is also a hybrid inorganic–organic 3-D coordination polymer [9]. In 2 the 2-D layers of repeating neutral [Cd{B₅O₈(OH)}] units are linked by bridging dap units into a 3-D structure, with each 20-electron Cd^(II) center being 5-coordinate and ligated by two monodentate N-donor dap ligands and three O-donors from the oxidoborate framework.

Compound 3 is a Cd^(II) complex comprised of an anionic oxidoborate ligand {B₈O₁₁(OH)₄}²⁻ fragment coordinated to a supporting {Cd(tren)}²⁺ fragment (Figure 1b) [10]. The 20-electron Cd^(II) center in 3 is five-coordinate and is coordinated by four N-donors from the tren ligand and one O-donor from the bridging O atom from the {B₃O₆(OH)} sub-unit of the octaborate(2-) anion. These {B₃O₄(OH)} sub-units, with additional pendant {B₅O₇(OH)₃} sub-units, link together into a 1-D chain polymer. These 1-D chains are joined together into a 3-D framework via extensive H-bond interactions.

Compound 4 is an octahedral 22-electron Cd^(II) complex with a cis-pn ligand and four O-donors from two hexaborate(2-) ligands, forming a 1-D coordination polymer chain [11]. One of the hexaborate ligands is coordinated fac to the Cd^(II) center via the three OH groups bound to tetrahedral boron atoms and the final coordination bond is formed from a trigonal boron OH group from another hexaborate(2-) unit (Figure 1c). The structure of this complex is described as [Cd(1,2-dap)][B₆O₁₁(OH)₂]·H₂O in [11] but is better formulated as [Cd(pn){B₆O₇(OH)₆}]_n·nH₂O (4). The hexaborate(2-) units in 4 not only bridge two Cd^(II) centers but are also further linked together to form an extended network which is interconnected via a strong H-bonding.

Compound 5 has a unique structure, and it is comprised of 2-D planes of condensed {B₆O₉(OH)₂}²⁻ units coordinated to the terminal 22-electron Cd^(II) centers of a linear {Cd₃(H₂O)₄(NO₃)₂}⁴⁺ unit (Figure 2a) is such a way as to form a crosslinked 3-D network [12]. The central 22-electron Cd^(II) center of the centrosymmetric {Cd₃(H₂O)₄(NO₃)₂}⁴⁺ sub-unit (marked Cd* in Figure 2a) has two trans NO₃⁻ ligands and all three Cd^(II) centers are octahedral with remaining sites occupied by terminal or bridging H₂O ligands or oxidoborate O-donor centers.

Compound 6 is typical of a series of four hybrid Cd^(II) oxidoborates that exhibit 3-D open-framework with novel topologies [13]. All the networks are comprised of a novel Cd^(II) centered complex trans-[Cd(py)₂{B₁₄O₂₀(OH)₆}]²⁻ and there are further interionic links via H-bonding interactions. As shown in Figure 2b, the [B₁₄O₂₀(OH)₆]⁴⁻ coordinates by four O-donors from the four boroxole {B₃O₃} rings to the Cd^(II) center in a square planar arrangement, with two additional axial N-donor ligands, resulting in a 22-electron octahedral complex.

2.2. Cobalt(II) Borates

The triborate(1-) ligand with the FBB unit of a 6-membered boroxole ring with two {BO₃} units and one {BO₄} unit i.e., 3:(2Δ+T) (Figure 3a) is present in the recently synthesized salt [Co(H₂O)₆]₂[NO₃]₂·[Co(H₂O)₄{B₃O₃(OH)₄}₂]·2H₂O (7) [14]. The 19-electron Co^(II) centers are both octahedral and the two [B₃O₃(OH)₄]⁻ ligands in the neutral [Co(H₂O)₄{B₃O₃(OH)₄}₂] complex are trans and are coordinated by hydroxy O-donors bound to tetrahedral boron atoms.

A diagram of the structure of [Co(dap)_0.5(dap’)_0.5{B₄O₇}]_n (8) [8] (Figure 3b) shows a five-coordinate trigonal-bipyramidal coordination geometry at the 17-electron Co^(II) center with two N-donor coordinate bonds, from two different dap ligands and forming a 1-D chain, and three O-donor atoms from three anionic {B₄O₇}²⁻ tetraborate units. The Christ and Clark descriptor for these units with a FBB of 4 is 4-1:(2Δ+2T).

The basic building unit of [Co(tren){OB₅O₆(OH)₃}] (9) is shown in Figure 4a [15]. The [OB₅O₆(OH)₃]²⁻ ligand can be described as 5:(4Δ+T) with one of four trigonal units deprotonated. The 17-electron Co^(II) center exhibits a trigonal-bipyramidal coordination geometry, with four N-donor atoms and one O-donor atom. Compound 9 forms 3-D supramolecular network through extensive H-bond interactions.

The homoleptic bis(hexaborate(2-))cobalt(II) complexes [piperazine-1,4-dium] [Co{B₆O₇(OH)₆}₂]·6H₂O (10) [16] and [1-cyanopiperazinium][Co{B₆O₇(OH)₆}₂]·4H₂O (11) [17] have been recently synthesized and characterized crystallographically. The oxidoborate ligands in 10 and 11 are designated 6:(3Δ+3T) and it is the three hydroxyl O atoms on the three {BO₄} centers that coordinate in fac- geometries to the octahedral 19-electron Co^(II) centers (Figure 4b). In both these structures there are strong templating interionic H-bond interactions.

The derivatized hexaborate(2-) ligand observed in [Co{(NH₂CH₂CH₂O)₃B₆O₇(OH)₃}] (12) [18] has three 2-amino ethoxy groups in place of the three -OH groups on the tetrahedral boron centers of a hexaborate(2-) ion found in 10 and 11. It functions as a hexadentate ligand through the three O-donors, bound to the aminoethyl substituents and the three amino N-donors to the 19-electron Co^(II) center (Figure 4c).

2.3. Copper(II) Borates

Oxidoborates coordinated to Cu^(II) centers are not uncommon and are available for diborate(2-), pentaborate(1-), hexaborate(2-) and icosaborate(12-) anions. The diborate(2-) anion is observed as part of the templated oxidoborate found in [H₃O]₄[Cu₇(NH₃)₂(H₂O)₄{B₂₄O₃₉(OH)₁₂}]·13H₂O (13) [19] and this will be discussed later in this sub-section.

As shown in Figure 5a, [Cu(pn)₂{B₅O₆(OH)₄}][B₅O₆(OH)₄]·4H₂O (14) [20] is an ionic compound comprised of a cationic hybrid Cu^(II) complex containing a pentaborate(1-) ligand based on a FBB of 5:(4Δ+T). This +1 cation is partnered with an additional insular [B₅O₆(OH)₄]⁻ anion. The 19-electron Cu^(II) ion in 14 has a distorted square-based pyramidal geometry with four N-donor atoms, and an axial O-donor pentaborate(1-) with a T⁵ [21] of 0.87. A sixth O-donor H₂O potential ‘ligand’ is axially trans to the pentaborate(1-) ligand, but the Cu-O distance is not within normal (or even long) bonding distances.

Coordinated hexaborate ligands are well represented in Cu^(II) coordination chemistry as illustrated by the following examples: [Cu(NH₃)₂{B₆O₇(OH)₆}]_n·2nH₂O (15) [22], [Cu(en){B₆O₇(OH)₆}]_n·3nH₂O (16) (en = 1,2-diaminoethane) [23], [Cu(dmen){B₆O₇(OH)₆}]·4H₂O (17) (dmen = N,N-dimethyl-1,2-diaminoethane) [20], [Cu(tmeda){B₆O₇(OH)₆}]·6H₂O (tmeda = N,N,N’,N’-tetramethyl-1,2-diaminoethane) (18) [20], and [Cu(deen){B₆O₇(OH)₆}]·5H₂O (19) (deen = N,N-diethyl-1,2,-diaminoethane) [22]. The organic N-donor ligands in 17, 18 and 19 are relatively sterically demanding and the resulting neutral coordination complexes have square-based pyramidal 5-coordinate 19-electron Cu^(II) geometries. Each Cu^(II) center is coordinated by two N-donors and three O-donors from the oxidohexaborate(2-) ligands. This is illustrated in Figure 5b for 19. The organic N-donor ligands in 15 and 16 are relatively small and this permits the Cu^(II) centers to adopt 6-coordinate tetragonally distorted octahedral geometries with the formation of additional Cu-O coordinate bonds from bridging oxidoborate ligands, in a similar way to that observed in the Cd^(II) complex, 4. These 21-electron Cu^(II) centers are coordinated by two N-donors ligands, three O-donors from the fac-hexaborate(2-) ligand with a sixth site from an O-donor of an ‘adjacent’ hexaborate(2-) by formation of a 1-D coordination polymeric chain.

Three new examples of Cu^(II) complexes containing oxidoicosaborate(12-) ligands have been prepared: [H₃O]₄[Cu₇(NH₃)₂(H₂O)₄{B₂₄O₃₉(OH)₁₂}]·13H₂O (13) [19], H₆[Cu₄O{B₂₀O₃₂(OH)₈}]·25H₂O (20) [24] and H₆[Cu₄O{B₂₀O₃₂(OH)₈}]·34H₂O·8B(OH)₃ (21) [24]. These three compounds are fundamentally structurally identical to Cu^(II)/oxidoicosaborate(6-) complexes HM₅[Cu₄O{B₂₀O₃₂(OH)₈}]·32H₂O (M = Na, K) first synthesized by Heller and described in his early (1986) borate structural chemistry review [3]. The structure of the anion in 13, 20 and 21 is drawn in Figure 6. It is best described as comprised on four square planar 17-electron Cu^(II) ions and a central μ₄-O²⁻ ion supporting and surrounded by large oxidoicosaborate(12-) ring structure. This ring structure itself is ‘tetrameric’ with four alternating FBB’s of {B1} and {B4} sub-units linked into a larger 24-membered ring with a compound designation of 20:{4:(2Δ+2T)+Δ}₄. Compound 21 has 8 additional B(OH)₃ molecules per oxidoicosaborate(12-) moiety, and these are situated within channels which are available within the giant structure formed by close-packing the large multi-metallic oxidoborate anions [24].

Compound 13 is unique and contains seven Cu^(II) centers. It can be considered to be a large anion based on two ‘layers’: the ‘lower layer’ is as is illustrated in Figure 6a and this layer supports a linear {Cu₃}⁶⁺ unit in an ‘upper layer’. The {Cu₃}⁶⁺ unit is further supported by two peripheral diborate(2-) anions, and all seven 19-electron Cu^(II) centers are 5-coordinate square-based pyramids. This ‘top layer’ of 13 is illustrated in Figure 6b. Structurally, compound 13 has another unusual feature: the presence of B-O⁻ groups. It is very rare for oxidiborates prepared and crystallized from aqueous solution to display B-O⁻ groups arising from trigonal B centers [2]. It is also interesting to note that all such B-O⁻ groups in the ‘upper layer’ of 13 are found bridging two (μ₂-) or three (μ₃-) Cu^(II) centers and that the central O²⁻ ion bridges five (μ₅-) Cu^(II) centers [19]. There are also four B-O⁻ groups in the ‘lower layer’ of 13, and in 20 and 21 that each bridge (μ₂-) two Cu^(II) centers.

2.4. Gallium(III) and Indium(III) Borates

Ga^(III) and In^(III) borates are conveniently considered together. The hybrid oxidoborate, [Ga(en)₂{B₅O₈(OH)₂}]_n·nH₂O (22) was first synthesized in 2012 [25]. The two en N-donor bidentate ligands occupy four coordination sites around an octahedral 22-electron Ga^(III) center and the two remaining cis- coordination sites are connected to two different {B₅O₈(OH)₂}³⁻ anions forming a 1-D chain structure (Figure 7a). Two recently reported compounds [Ga(teta){B₅O₈(OH)₂}]_n·nH₂O (23) (teta = tetraethylenetriamine) and [In(teta){B₅O₈(OH)₂}]n·1.5nH₂O (24) have similar structures [11]. Compound 22 was also reported in 2013 together with three other related compounds: [In(en)₂{B₅O₈(OH)₂}]·H₂O (25), [In(dap)₂{B₅O₈(OH)₂}]·H₂O (26), and [In(dien){B₅O₈(OH)₂}]_n (27) [26]. The structures of 25 and 26 are essentially the same as 22 with a change of metal (to In^(III) in 25) or ligand and metal (to In^III and dap in 26). Compounds 22–27 contain {B₅O₈(OH)₂}³⁻ anions and these anions are based on the frequently observed 5:(4Δ+T) pentaborate(1-) anion, [B₅O₆(OH)₄]⁻, but is additionally double deprotonated. The related compound Rb_2n[Ga{B₅O₁₀}]_n·4nH₂O (28) has also been reported [25]. Here, the 5:(4Δ+T) building block is deprotonated 4 times to form the [B₅O₁₀]⁵⁻ anion with four of these anions coordinated to a tetrahedral 18-electron Ga^(III) center in chain-like 2-D structures.

Compound 27 is unique and features octahedral In^(III) centers coordinated by a tridentate dien ligand (fac-) and three monodentate {B₅O₈(OH)₂}³⁻ ligands which bridge to other In^(III) centers in such a way as to produce a ‘dimeric’ 1-D chain with oxidoborate O-bridges between two In^(III) centers (Figure 7b). The H-bonding interactions between adjacent chains leads to a supramolecular H-bonded network.

2.5. Manganese(II) Borates

One 15-electron five-coordinate trigonal-bipyramidal Mn^(II) complex with a coordinated oxidoborate ligand has been reported, K₇[(BO₃)Mn{B₁₂O₁₈(OH)₆)}]·H₂O (29) [27]. The structure of this will be discussed in Section 2.7 since 29 is isostructural with an analogous 20-electron Zn^(II) complex and forms part of a family of structurally related of Zn^(II) compounds.

2.6. Nickel(II) Borates

The recently synthesized salt [Ni(H₂O)₆]₂[NO₃]₂·[Ni(H₂O)₄{B₃O₃(OH)₄}₂]·2H₂O (30) [14] is isostructural with 7. The two [B₃O₃(OH)₄]⁻ ligands in the neutral [Ni(H₂O)₄{B₃O₃(OH)₄}₂] complex are trans on octahedral 20-electron Ni^(II) centers and are coordinated by hydroxy O-donors bound to tetrahedral boron atoms of the triborate(1-) anion.

Two Ni^(II) hexaborate(6-) complexes have recently been synthesized during the review period: [Ni(en)(H₂O)₂{B₆O₇(OH)₆}]·H₂O (31) [28] and [Ni(dmen)(H₂O){B₆O₇(OH)₆}]·5H₂O (32) [28]. These compounds are neutral molecules and contain the [B₆O₇(OH)₆]²⁻ ligand as described earlier for 4, 10, 11 and 15–19 (Section 2.1, Section 2.2 and Section 2.3). These ligands are also found in Zn^(II) chemistry (Section 2.7). Both 31 and 32 are octahedral about the 20-electron Ni^(II) centers but differ in the denticity of the hexaborate(2-) ligands which are bidentate in 31 (Figure 8a) and tridentate in 32. Both compounds demonstrate numerous intermolecular and intramolecular solid-state structure directing H-bond interactions.

The derivatized hexaborate(2-) ligand, with three 2-amino ethoxy groups, in place of the three -OH groups on the tetrahedral boron centers, functions as a hexadentate ligand in the 20-electron Ni^(II) complex, [Ni(NH₂CH₂CH₂O)₃{B₆O₇(OH)₃}] (33) [18]. Compound 33 is isostructural with 12.

2.7. Zinc(II) Borates

There have been more oxidoborate complexes reported for Zn^(II) than for any other metal. The coordinated oxidoborate ligands range in size from triborate(1-) to dodecaborate(6-).

The recently synthesized salt [Zn(H₂O)₆]₂[NO₃]₂·[Zn(H₂O)₄{B₃O₃(OH)₄}₂]·2H₂O (34) [14] is isostructural with 7 and 30. The two [B₃O₃(OH)₄]⁻ ligands in the neutral [Zn(H₂O)₄{B₃O₃(OH)₄}₂] complex are trans on octahedral 22-electron Zn^(II) centers and are coordinated by hydroxy O-donors bound to tetrahedral boron atoms.

Structural characterization of the commercially important Zn^(II) triborate, [Zn{B₃O₄(OH)₃}]_n (35), revealed that it was a crosslinked 1-D coordination chain polymer of Zn^(II) [29]. The oxidoborate forms a 1-D polymeric chain (Figure 8b) and each 18-electron Zn^(II) center is coordinated by two oxygen atoms from two adjacent monomeric unit of the chain, and completes its tetrahedral arrangement by coordination from two hydroxide O-donors from a neighboring chain to crosslink the structure into a 2-D network. The network also has numerous interchain H-bond interactions. Each triborate(2-) FBB unit is a 6-membered boroxole ring with one {BO₃} and two {BO₄} units, i.e., 3:(Δ+2T).

Tetraborate ligands based on the 4(4-1) FBB are represented by the following compounds [Zn(pn){B₄O₆(OH)₂}]_n (36) [30], [Zn(dap)_0.5(dap’)_0.5{B₄O₆(OH)₂}]_n·nH₂O (37) [30], and [Zn(dab)_0.5(dab’)_0.5{B₄O₆(OH)₂}]_n·nH₂O (38) [31]. Compounds 36-38 have identical Zn^(II)/ligand/borate stoichiometries with similar, but non-identical, structures. All three contain tetrahedral 18-electron Zn^(II) centers with two N-donor amine and two O-donor tetraborate ligands, with the latter condensed into 1-D tetraborate chains. Compound 36 contains a chelating pn ligand (Figure 8c) whereas 37 (and 38) has two dap (or dab) ligands on each Zn^(II) center both bridging other Zn^(II) centers and forming a 1-D coordination polymer chains in crosslinked inorganic–organic 2-D layered structures.

The FBB of 5:(4Δ+T) is present in [Zn(tren){B₅O₇(OH)₃}] (39) [32] and this ligand is identical to that found in 9 (Section 2.2). [Zn(dab)_0.5(dab’)_0.5{B₅O₇(OH)₃}]_n (40) [8] and [Zn(appip){B₄O₆(OH)(OB{OH}₂})]_n·3nH₂O (41) (appip = trans-1,4-bis(3-aminopropyl)piperazine) [30] are based on a FBB of 4 with a pendant -OB(OH)₂ replacing a hydroxyl group on a tetrahedral boron center of the tetraborate moiety with a 5:[4:(2Δ+2T)+Δ] framework and are isostructural with 1 (Section 2.1).

The 6:(3Δ+3T) FBB, described in Section 2.1, Section 2.2, Section 2.3 and Section 2.6, is also observed as a hexaborate(2-) ligand in Zn^(II) complexes. The following complexes have been prepared [Zn(dien){B₆O₇(OH)₆}]·0.5H₂O (42) [33], (NH₄)₂[Zn(H₂O)₂{B₆O₇(OH)₆}₂]·2H₂O (43) [33], [Zn(en){B₆O₇(OH)₆}]_n·2nH₂O (44) [34] and [Zn(pn){B₆O₇(OH)₆}]_n·1.5nH₂O (45) [34]. The 22-electron Zn^(II) centers in 42-45 are all octahedral with N₃O₃, O₆, N₂O₄ and N₂O₄ donor sets, respectively. The hexaborate(2-) ligands in 42, 44 and 45 are tridendate but are bis(bidentate) and trans in the centrosymmetric anion in 43 (Figure 9a). Compounds 44 and 45 are 1-D coordination polymers with a -OH group of a trigonal boron of the coordinated hexaborate(2-) anion bridging onto another Zn^(II) center. This configuration has also been observed in Cd^(II) (4, Section 2.1) and Cu^(II) (15 and 16, Section 2.3) chemistry.

{{Zn(en)₂B₇O₁₀(OH)₃}₂]_n (46), also formulated as [Zn(en)₂{B₇O₁₂(OH)}] in Ref. [9], is a 3-D coordination polymer comprised of an octahedrally coordinated 22-electron Zn^(II) center based on square planar [Zn(en)₂] units axially coordinated by a O-donor condensed oxidoheptaborate framework. The oxidoborate FBB in 46, [B₇O₁₀(OH)₃}]_n²ⁿ⁻, can be described by a compounded descriptor 7:[(3:2Δ+T)+(3:2Δ+T)+Δ] with triangular BO₂(OH) cross-linking units (Figure 9b).

[Zn(en)₂{B₈O₁₁(OH)₄}]_n (47) [10] was reported in 2017 and has a similar stoichiometry to 3 but is isomeric, with a different oxidoborate condensation mode and a 1-D polymer chain. (Figure 10a). Nevertheless, the octaborate(2-) anion is best designated by the compounded descriptor 8:[5:(4Δ+T)+3:(2Δ+T)].

[Zn₂(dap)(dap’){B₈O₁₃(OH)₂}]_n (48) [30] has a similar structure to 37 and 38 with the 18-electron Zn^(II) centers tetrahedral with 2 monodentate bridging dap N-donor ligands. The octaborate(4-) O-donor ligands are based on two condensed tetraborate(2-) building blocks via an O bridge, 8:{4(2Δ+2T)}₂. However, this now results in 2-D layers rather than 1-D chains and the 2-D layers are further crosslinked into 3-D networks, by the amines.

The large insular anion [B₁₂O₁₈(OH)₆]⁶⁻ has been reported in K₇[(BO₃)Zn{B₁₂O₁₈(OH)₆)}]·H₂O (49) [35], [(Hen)Zn{B₁₂O₁₈(OH)₆}Zn(en)(Hen)]·8H₂O (50) [36] and (H₂dap)₃[(Hdap)Zn{B₁₂O₁₈(OH)₆}]₂·14H₂O (51) [33]. The dodecaborate(6-) anion is based on a hexameric FBB of 3 i.e., 12:{3:(Δ+2T)}₆, with all tetrahedral boron centers linking boroxole {B₃O₃} rings, generating a larger inner 12-membered B/O alternating B₆O₆ ring. Stereochemically, three of these potential O-donor atoms point to one side of the large ring and three face towards the other side. The anion in 51, [(Hdap)Zn{B₁₂O₁₈(OH)₆}]³⁻, which is typical of the oxidoborate building blocks contained within these structures, has a tetrahedral 18-electron Zn^(II) center coordinated by fac O-donors from the dodecaborate(6-) ligand and a monodentate N-donor from a protonated 1,3-diamminopropane ligand (Figure 10b). There is extensive H-bonding between anions forming a supramolecular 3-D H-bonded lattice.

3. Synthetic Methods

3.1. Slow Crystallization by Solvent Evaporation

This method involves slow crystallization from aqueous or a miscible aqueous/organic solution which originally contained B(OH)₃ and metal precursor complexes. The oxidoborate compounds are templated by the transition-metal/p-block metal complexes present in the dynamic combinatorial library (DCL) of oxidoborate anions that are present in solution in equilibrium concentrations [37]. Products are generally under thermodynamic control especially when metal-ligand exchange equilibria (and hydroxyoxidoborate-H₂O equilibria) are fast. The solvents used for evaporation in the boric acid solution are often H₂O or H₂O/EtOH or H₂O/MeOH. Crystallization of the product may take a few hours to several weeks. This is illustrated for the preparation of [Cu(en){B₆O₇(OH)₆}]_n·3nH₂O (16) from [Cu(en)₂]SO₄ and B(OH)₃ [20]. [Cu(en)₂]SO₄ (3.6 mmol) and BaSO₄·8H₂O (3.6 mmol) were dissolved in H₂O (20 mL). The solution was stirred for 20 min at room temperature and the precipitate that formed (BaSO₄) was removed by filtration. B(OH)₃ (25 mmol) was added to the filtrate which was then stirred for 40 min. The resulting solution was left in several small vials to crystallize. After standing for 35 days the product 16 was collected by filtration as blue crystals in 31% yield. Compounds 11, 13–19, 31, 32, 35, 42–45, 50 and 51 were prepared by a method similar to this. Oxidopolyborates prepared by this method are often insular salts and are often less condensed than those prepared by the methods described below, which generally use more forcing conditions.

3.2. Solvothermal/Hydrothermal Methods

Many organic-inorganic oxidoborates described in this article are synthesized by solvothermal (or hydrothermal) methods. In this method the non-aqueous solvent (or H₂O) is placed in a sealed reaction vessel together with boron containing materials, transition-metal/p-block metal salts and organic ligands and heated to a specific temperature (usually 100–250 °C) for a set time period. Solvothermal reactions can lead to metastable, kinetically controlled, products. This method is illustrated by the preparation of [Cd(dap)_0.5(dap’)_0.5{B₅O₈(OH)}]_n·nH₂O (2) [9]. H₃BO₃ (5 mmol) and Cd(NO₃)₂·4H₂O (1 mmol) were slowly added to a N,N-dimethylformamide (2 mL) and 1,3-dap (1 mL) solution with stirring. The white emulsion was then sealed in a Teflon-lined 25 mL autoclave reactor and heated at 180 °C for 7 days. After cooling to room temperature, crystals of 2 (36% yield based on H₃BO₃) were collected by filtration, washed with H₂O, and dried in air. Compounds 1–6, 8, 9, 12, 20–29, 33, 36–41 and 46–49 were prepared by this general method. This relatively low temperature hydrothermal method is popular among many researchers since the necessary autoclave reactors are widely available in both academic and industrial laboratories.

3.3. Molten Salt Methods

In this method a molten salt (120–250 °C) is used as both solvent and reactant and the reaction vessel is charged with B(OH)₃ and any other necessary reaction materials. This is illustrated by the preparation of [Co(H₂O)₆]₂[NO₃]₂·[Co(H₂O)₄{B₃O₃(OH)₄}₂]·2H₂O (7) [14]. Co(NO₃)₂·6H₂O (1 mmol) was placed in a 25 mL beaker and heated in an oil bath at 120 °C until fully molten (ca. 1 min). H₃BO₃ (0.8 mmol) was then added, and the mixture was stirred until the H₃BO₃ was completely dissolved (ca. 30 min). The solution was then allowed to cool to room temperature and left to crystallize. After 14 days, transparent colorless crystals of 7 (30% based on H₃BO₃) were deposited on the bottom of the beaker. Compound 7 was isolated by filtration. Compounds 30 and 34 were also prepared by this method.

4. Physical, Spectroscopic Properties and Potential Applications

The oxidoborate complexes described in this manuscript are all crystalline solids with high melting (or decomposition) points. Techniques used to characterize the oxidoborates and to study their possible applications include structural studies (single-crystal XRD, powder-XRD, TEM), optical properties (diffuse reflectance spectroscopy, nonlinear optical studies (NLO), photoluminescence), magnetic properties, vibrational spectroscopy, thermal studies and catalytic investigations.

Oxidoborate complexes derived from transition-metals are generally colored but the d¹⁰ ions (Cd^(II), Zn^(II), Ga^(III) and In^(III)) are colorless. UV/Vis absorption properties of several oxidopolyborate complexes (1, 4, 5–8, 22–24, 28, 30, 34, 36, 37, 40, 41) have been studied by diffuse reflectance spectroscopy and band-gaps with energies of ranging from 3.1 eV for [(Cd₃){B₆O₉(OH)₂}₂(NO₃)₂(H₂O)₄]_n (5) to 5.9 eV for [Cd(dab)_0.5(dab’)_0.5{B₅O₇(OH)₃}]_n (1) have been noted.

The band-gaps of [Cd(pn){B₆O₇(OH)₆}]_n·nH₂O (4), [Ga(teta){B₅O₈(OH)₂}]_n·nH₂O (23) and [In(teta){B₅O₈(OH)₂}]n·1.5nH₂O (24) show interesting but different temperature effects. Compounds 23 and 24 exhibited blue maximum luminescence at 446 and 472 nm, respectively, when excited at 352 and 342 nm, respectively. The luminescence intensity of these two compounds increased with a decreasing temperature and was at its most intense at 80 K. Compound 4 exhibited the maximum luminescence at 444 nm with a 360 nm excitation light source, and the luminescence intensity increased with the decrease of temperature to 230 K where it was at its most intense. The luminescence intensity of 4 decreased when the temperature was further lowered to 80 K [11]. Compounds [M(dab)_0.5(dab’)_0.5{B₅O₇(OH)₃}]_n (M = Cd, (1); M = Zn (40)) have been shown to display blue luminescence with maximum fluorescent emission at 423 and 412 nm, when excited at and 356 or 384 nm, with lifetimes of 4.67 and 4.09 ns, for 1 and 40, respectively [8]. It is reported that the blue luminescence of two compounds originates from their inorganic oxidoborate frameworks.

Nonlinear optical (NLO) effects are also displayed by the following hybrid metal oxidoborates Rb_2n[Ga{B₅O₁₀}]_n·4nH₂O (28) [25], K₇[(BO₃)Mn{B₁₂O₁₈(OH)₆)}]·H₂O (29) [27], [Zn(pn){B₄O₆(OH)₂}]_n (36) [30] and [Zn(appip){B₄O₆(OH)(OB{OH}₂})]_n·3nH₂O (41) [30]. For example, compound 41 belongs to the space group P2₁, and since this point group is non-centrosymmetric 41 might be expected to exhibit second order nonlinear optical effects; indeed, powdered 41 does exhibit SHG behavior with a response of 29 mV using a laser of beam energy with 2.83 mJ/pulse [30]. Compound 36 had a response of 24 mV while the response of the SHG standard, KH₂PO₄ (KDP), was 175 mV under similar conditions [30]. Compound 28 crystallizes in chiral space group C222₁. SHG measurements on a Q-switched Nd:YAG laser with sieved powdered samples (70−100 mesh) revealed that compound 28 displays a moderately strong SHG response approximately equal to that KDP [25]. The SHG response of 29 was again moderate and equal to that of KDP [27].

Many of the compounds described within this review are diamagnetic but those containing Cu^(II) (13–21) and Ni^(II) (31–32) centers are paramagnetic. The magnetic properties of the Ni^(II) complex 30 have not been reported. Magnetic properties of the Co^(II) (7–12) and the Mn^(II) (29) oxidoborate complexes were also not reported, although these would be expected to be paramagnetic. The μ_eff values (per Cu^(II) atom) of the multi-metallic complexes [H₃O]₄[Cu₇(NH₃)₂(H₂O)₄{B₂₄O₃₉(OH)₁₂}]·13H₂O (13), H₆[Cu₄O{B₂₀O₃₂(OH)₈}]·25H₂O (20) and H₆[Cu₄O{B₂₀O₃₂(OH)₈}]·34H₂O·8B(OH)₃ (21) are much lower than expected by the spin-only formula and 20 and 21 are temperature dependent and display anti-ferromagnetic behavior [24].

A complex borate, [Ni(en)₃]_n[Hen]_n[B₉O₁₃(OH)₄]_n·nH₂O, containing isolated cations and a partially condensed anionic a one-dimensional oxidoborate chain has ferroelectric properties at room temperature [38]. The electrical hysteresis loop was observed when an electric field between −28 and +28 kV was applied to the sample. Spontaneous polarization (P_s of about 52 nCcm⁻²) also occurred during the measurement with remnant polarization (P_r of about 30 nCcm⁻²) and a coercive field (E_c) of about 28 kVcm⁻¹. The P_s of this compound is very close to that of KH₂PO₄⁻ type ferroelectrics. The related compound, [Ni(en)₂(pip)][B₅O₆(OH)₄]₂, which contains insular oxidoborate anions rather than coordinated oxidoborate ligands, was reported as the first templated oxidoborate with ferroelectric properties [39]. The P_s value for [Ni(en)₂(pip)][B₅O₆(OH)₄]₂ of 20 nCcm⁻² for is significantly higher than that of typical organic ferroelectric compounds, e.g., β-quinol-methanol (P_s = 6 nCcm⁻²). A related pentaborate derivative, [Zn(dab)_0.5(dab’)_0.5{B₅O₇(OH)₃}]_n (40), has been prepared more recently, and exhibits a wide E_c value of ca. 6 kV cm⁻¹ to 11 kV cm⁻¹ [8].

Vibrational (IR) data are commonly reported for oxidoborate complexes. In addition to diagnostic bands associated with organic ligands (O-H, N-H, C-C, C-N, C-C etc. stretches and bends) strong absorptions associated with ligand-M and B-O stretches (1400–1000 cm⁻¹) are often observed but usually are not diagnostic since they are in the IR fingerprint region. In general, B-O stretching modes can be subdivided into four specific regions (asymmetric stretches: B_trig-O, 1450–1300 cm⁻¹; B_tet-O, 1150–1000 cm⁻¹; symmetric stretches: B_trig-O, 960–890 cm⁻¹, B_tet-O, 890–740 cm⁻¹) with bending and deformation modes at lower energy [40]. Nevertheless, Li and co-workers have tabulated diagnostic wavenumbers for specific smaller oxidoborate anions [40]. Hexaborate(2-) derivatives, with a FBB of 6:(3D+3T), are fairly common as oxidoborate ligands (e.g., compounds 4, 5, 10–12, 15–20, 42–45) and diagnostic bands at 955 and 808 cm⁻¹ have been proposed for this anion [20,40]. Tentative diagnostic bands (1047, 952, 902 and 857 cm⁻¹) have also been reported for icosaborate(6-) derivatives (49–51) [33].

The most studied property of inorganic–organic hybrid borates is their thermal behavior. Indeed, all compounds described within this review, except 10, 12, 33 (which are reported in crystallographic journals [16,18]), have their thermal properties documented. Many of the thermal studies have been undertaken in air from room temperature up to 800 °C, although a few (4, 23, 24) report data obtained through heating under N₂ to a similar temperature. Generally, thermal decomposition is a multistage process which includes a low temperature loss of interstitial molecules (where present), a moderate temperature dehydration and cross-linking of oxidoborate hydroxyl groups, and a high temperature oxidation process (or removal of volatile organics) to generate a glassy borate residual solid. This solid can be formulated as an anhydrous metal borate (i.e., a mixed metal/boron oxide) with a M:B ratio that maintains the M:B ratio of the original oxidoborate complex. These principles are illustrated for compounds [Cd(pn){B₆O₇(OH)₆}]_n·nH₂O (4), [H₃O]₄[Cu₇(NH₃)₂(H₂O)₄{B₂₄O₃₉(OH)₁₂}]·13H₂O (13) and [Zn(en){B₆O₇(OH)₆}]_n·2nH₂O (44). Compound 44 decomposes thermally (in air) by the loss of 2 interstitial H₂O (100–180 °C), condensation of hydroxyoxidoborate with loss of 3H₂O (180–320 °C) and oxidation of the en ligand (320–470 °C) to leave as a residue ZnB₆O₁₀ (= ZnO·3B₂O₃) [34]. Compound 13 thermally decomposes in air by the loss of 21 (interstitial and coordinated) H₂O and 4 (coordinated) NH₃ molecules (at 70–160 °C) and condensation of hydroxyoxidoborate groups with loss of 8H₂O (at 160–300 °C) to afford Cu₇B₂₄O₄₃ (= 7CuO·12B₂O₃) [19]. Occasionally, the individual processes overlap but the endpoint is the same. Thus, 4 losses weight continuously in one step upon heating, under N₂, from room temperature to 800 °C [11]. In this process the guest water molecules are removed together with pn ligands and the oxidopolyborate fully condenses to afford CdB₆O₁₀ (= CdO·3B₂O₃) [11]. Non-metal cation polyborates have been considered to be thermal precursors to porous materials [5]. To date this has not been successful [41,42,43] but recent studies on H₆[Cu₄O{B₂₀O₃₂(OH)₈}]·25H₂O (20) and H₆[Cu₄O{B₂₀O₃₂(OH)₈}]·34H₂O·8B(OH)₃ (21), which contain large 3-D intersecting channel systems with PLATON calculated solvent accessible voids of ca. 60%, suggest that mesoporous materials may be available from hybrid organic oxidoborates [24].

Fire retardancy is often linked to a compound’s thermal properties and [Zn{B₃O₄(OH)₃}]_n (35) [31] is well known for this property and has been commercially exploited. Many zinc borates also possess such properties [44] and the recently prepared hybrid oxidoborate complex [Zn(H₂O)₆]₂[NO₃]₂·[Zn(H₂O)₄{B₃O₃(OH)₄}₂]·2H₂O (34) [14] has also been reported as a promising flame retardant, at 15 wt.% loading, for ABS (acrylonitrile butadiene styrene), an important engineering thermoplastic material.

Hybrid metal-organic oxidoborates have been used as precursors to thermally prepared catalysts [9] e.g., carbon material catalysts derived from thermal treatment of [Cd(dap)_0.5(dap’)_0.5{B₅O₈(OH)}]_n·nH₂O (2) and [{Zn(en)₂{B₇O₁₀(OH)₃}₂]_n (46) have been used to electrochemically reduce CO₂ to CO. Initial results indicate that the oxidoborate is a useful catalyst precursor since at 1.4V CO formation is 51% higher than that of RHE. This may be a promising development as a low-cost alternative to traditional noble metal catalysts.

5. Conclusions

Since metals generally have multiple coordination sites, they often can form coordination linkages with organic (N-donor) and oxidoborate (O-donor) ligands. These organic/inorganic oxidopolyborate hybrid complexes are structurally diverse and often have polymeric structures based on unique frameworks. The hybrid organic oxidoborate materials in such integrated structures can afford materials with unique properties and which may overcome possible deficiencies inherently present in related single component systems. Hybrid inorganic−organic oxidoborates have attracted considerable recent research attention, and interesting properties such as photoluminescence, ferroelectric and NLO and catalytic properties have been discovered and these are summarized within the review. Initial results indicate that these properties can be tailored and manipulated by adjusting the organic ligands, the oxidoborate motif and/or the central metallic ion, and that such compounds are a promising area for future research.