Synthesis, characterisation, and catalytic application of a soluble molecular carrier of sodium hydride activated by a substituted 4-(dimethylamino)pyridine

Abstract

Recently main group compounds have stepped into the territory of precious transition metal compounds with respect to utility in the homogeneous catalysis of fundamentally important organic transformations. Inspired by the need to promote more sustainability in chemistry because of their greater abundance in nature, this change of direction is surprising since main group metals generally do not possess the same breadth of reactivity as precious transition metals. Here, we introduce the dihydropyridylsodium compound, Na-1,2-tBu-DH(DMAP), and its monomeric variant [Na-1,2-tBu-DH(DMAP)]·Me₆TREN, and demonstrate their effectiveness in transfer hydrogenation catalysis of the representative alkene 1,1-diphenylethylene to the alkane 1,1-diphenylethane using 1,4-cyclohexadiene as hydrogen source [DMAP = 4-dimethylaminopyridine; Me₆TREN = tris(N,N-dimethyl-2-aminoethyl)amine]. Sodium is appealing because of its high abundance in the earth’s crust and oceans, but organosodium compounds have been rarely used in homogeneous catalysis. The success of the dihydropyridylsodium compounds can be attributed to their high solubility and reactivity in organic solvents.

Organosodium compounds are appealing sustainable alternatives to precious transition metal compounds, yet they have rarely been used in homogeneous catalysis. Here, the authors introduce a dihydropyridylsodium compound, Na1,2-tBu-DH(DMAP), and its monomeric variant [Na-1,2-tBuDH(DMAP)]·Me₆TREN, and demonstrate their effectiveness in transfer hydrogenation catalysis of a representative alkene, 1,1-diphenylethylene, using 1,4-cyclohexadiene as a hydrogen source.

Introduction

Throughout the two decades of the 21st century, main group chemistry has been developing in areas previously considered out of bounds for these elements¹. Sometimes these developments have been described collectively as a renaissance, but they are probably more accurately described as new beginnings. Following his discovery of a germanium compound² able to break the strong covalent bond in H₂, Power’s vision of main group compounds imitating transition metal chemistry³ was surely epiphanic in this regard. Since then, the number of main group compounds reported as catalysts or co-catalysts in reactions usually carried out by transition metal complexes has grown significantly, especially main group metal hydride compounds^4,5. In another development the previously barren landscape of low valent aluminium (I) chemistry has been transformed into fertile land^6,7 often realised through alkali metal mediation⁸.

Drilling down the main group chemistry literature, one element that is attracting more recent attention is sodium. Synthetic chemists have rarely considered organosodium compounds as useful chemical reagents, probably because of the success of organolithium reagents that prompted their commercial availability and the greater challenge in handling their perceived more reactive, but significantly less studied heavier sodium congeners. Motivation for the recent upsurge in the study of organosodium chemistry⁹ has been attributed to the World’s ever sharpening focus on sustainability, specifically in this case meaning finding a solution to the rising threat to supplies of lithium (and therefore to organolithium compounds that are ubiquitous in fine chemical manufacture) due to the escalating use of lithium in energy technology¹⁰. Plentiful in the earth’s crust and oceans, and the sixth most abundant element overall, sodium, about 1500 times more abundant than lithium¹¹ is the obvious alternative to make up for any shortfall of lithium in the chemical industry. Therefore, different campaigns are underway to advance the chemistry of sodium organoamides, especially with diisopropylamide (DA), 1,1,3,3-hexamethyldisilazide (HMDS), and 2,2,6,6-tetramethylpiperidide (TMP), the so-called utility amides¹², which have been so prolifically successful in their lithium form. Highlights include detailed studies of NaDA in synthesis¹³, unravelling solvent-modulated aggregation phenomena of NaHMDS¹⁴ and their influences on reactivity¹⁵, and establishing that NaTMP can catalyse perdeuteration of arenes via hydrogen isotope exchange when activated by N,N,N’,N”,N”-pentamethyldiethylenetriamine (PMDETA)¹⁶. Accessed using sodium dispersions and inexpensive arylchlorides, organosodium compounds have also proved effective transmetallating alternatives to organolithium compounds in transition metal catalysed cross-coupling reactions¹⁷. Remarkably, onward reactivity of intermediate organosodium compounds has even been achieved in reaction mixtures containing protic substances such as water, glycerol, deep eutectic solvents (DESs) or air, all generally nemeses of polar organometallic compounds¹⁸. A selection of these and other recent advances has been captured in a mini review¹⁹.

The original research we report herein intersects two important developmental aspects of organosodium chemistry. First, the necessity to expand the number of monomeric compounds within the area^20,21, since such small molecular compounds can be highly reactive and second, to provide exemplars for new catalysts in fundamental organic transformations²². To meet these objectives, we have focused on establishing unique sodium dihydropyridyl compounds. Alkali metal dihydropyridyl compounds, in which the alkali metal and an anionic ligand such as an alkyl have added across the azomethine C-N bond to break the aromaticity of the N-heterocycle are appealing being simple to prepare, and versatile in their reactivity since they can exhibit both protic and (surrogate) hydridic behaviour^23,24. Herein, we report the synthesis of Na-1,2-tBu-DH(DMAP), 1 (we use DH(DMAP) as a trivial acronym for dihydro 4-dimethylamino pyridine), its solvated monomeric derivative [Na-1,2-tBu-DH(DMAP)]·Me₆TREN, 1·Me₆TREN and compare their performances with more common sodium reagents in the transfer hydrogenation catalysis of the model alkene 1,1-diphenylethylene using 1,4-cyclohexadiene (see Fig. 1). Unlike saline sodium hydride, which is generally insoluble in organic solvents, a significant limiting factor in its utilisation, 1·Me₆TREN possesses good solubility in both arene and ether solvents and so can be regarded as a soluble carrier of a molecular NaH unit, a beneficial factor exploited here in our catalytic studies.

Fig. 1. Empirical structures of amides relevant to this catalytic study.

Atoms in each molecule are represented by colours as follows: Carbon (black), nitrogen (blue), silicon (orange) hydrogen (yellow). Note the non-planar DHP rings are shaded in grey.

Results and discussion

Since Davidson and Mahon et al. introduced Me₆TREN to alkali metal chemistry in 2010 and reported a monomeric sodium complex in the aryloxide ArONa·Me₆TREN (Ar is 2,6-tBu₂-4-MeC₆H₂)²⁵ then followed up by us introducing the first Me₆TREN-complexed alkyl sodium monomers in ArCH₂Na·Me₆TREN (Ar is C₆H₅ or 3,5-Me₂C₆H₃)^26,27, we decided to stick to this polyamine as the monomerizing agent in this study. Me₆TREN is also an effective monomerizing agent for other reactive s-block species²⁸. For a potential catalytically active sodium complex we selected a modified dihydropyridyl complex. In previous catalytic transfer hydrogenation studies of imines to amines²⁴ we have shown that 2-tBuC₅H₅NM, M(tBuDHP), complexes (M = alkali metal) can be effective pre-catalysts though results using M = sodium were disappointing in comparison to those of the heavier alkali metals. Therefore in this study we have synthesised [Na-1,2-tBu-DH(DMAP)]·Me₆TREN, in which a NMe₂ substituent replaces a hydrogen atom at the 4-position of the pyridyl ring, in an attempt to see if this group modified the reactivity. This was indeed prepared by an in situ transmetallation reaction of the lithium 1,2-tBu-DH(DMAP) congener and the bulky alkoxide NaOtBu in hexane solution to yield 1·Me₆TREN (Fig. 2) and isolated in an 80% yield as yellow crystals after recrystallisation from hexane/Me₆TREN. A direct route using tBuNa is not viable due to the instability of alkylsodium compounds as previously noted in M(tBuDHP) literature²⁹.

Fig. 2. Synthetic protocol to obtain dihydropyridylsodium complexes.

Reaction of 4-DMAP with tBuLi/NaOtBu in hexane followed by monomerization using Me₆TREN to yield the desired dihydropyridyl sodium complex.

Monomer 1·Me₆TREN has been characterised by solution NMR spectroscopic studies and single crystal X-ray diffraction (SCXRD) studies. Diagnostic of its asymmetric 2-substituted dihydro formulation and loss of aromaticity, resonances appear at 7.23, 4.69, 4.02 and 3.76 ppm in its ¹H NMR spectrum in C₆D₆ solution (see Supplementary Fig. 5 for full details). Estimating the molecular weight of 1·Me₆TREN by diffusion ordered spectroscopy (DOSY) NMR studies³⁰ in C₆D₆ solution strongly suggests that our target of a monomeric sodium complex has been successfully reached. The error in the DOSY data is low at either 4% or -5% assuming the molecule has a dissipated sphere and ellipsoid shape (DSE) or other shape (see the Supporting Information section 2 - Supplementary Figs. 13–16 and Supplementary Tables 2–9). Isolated as a white solid in a 90% yield, [1]_n, made in the absence of Me₆TREN also produced DOSY data consistent with a monomeric species but of formula 1·(d₈-THF)₄, which seems logical from a coordination number perspective given the structure of 1·Me₆TREN.

While there are lithium examples in the literature^23,31, complex 1·Me₆TREN represents the first monomeric dihydropyridyl sodium complex to be characterized crystallographically (Fig. 3). The Me₆TREN ligates sodium via all four Lewis basic nitrogen atoms, consistent with all previously characterized Na/Me₆TREN complexes^32–34. The hydrogen atom on C1 could be located and refined, confirming its quaternary sp³ nature. Bond lengths around the ring are consistent with loss of aromaticity and confirm the conjugated double bond system running through the C₅ unit as is typically the case in such DHP anions. Loss of aromaticity is further confirmed by the non-planar nature of the six-membered ring. The Na1-N1-C3 angle of 130.86(8)^o is consistent with an anionic ligand which has the negative charge localized at the ring nitrogen rather than a neutral Lewis donating ring which would be expected to bind linearly. The description of the DH(DMAP) ligand as a secondary amide is further supported by the Na1-N1 bond distance of 2.344(2) Å, which is intermediate between that of monomeric (HMDS)Na·PMDETA [2.285(1) Å; 4-coordinate Na]³⁵ and Me₆TREN solvated secondary amides generated via methyl deprotonation of picolines followed by relocalization of the negative charge on to the ring nitrogen [2.391(2) Å, 5-coordinate Na]^36,37. Loss of aromaticity is further manifested through loss of planarity at the exocyclic NMe₂ group. Neutral DMAP has a planar NMe₂ on account of resonance stabilization experienced through lone pair donation into the ring and is exemplified by the average sum of bond angles in a recently reported [Li·4DMAP]⁺ moiety of 359.55^o38, in 1·Me₆TREN this value is 342.97^o, deviating considerably from trigonal planarity. The crystal structure of unsolvated 1 could not be determined due to its insolubility in non-Lewis-base donor solvents such as hexane. It is likely that this complex adopts a polymeric arrangement as is commonplace in unsolvated sodium amide chemistry. An infinite network made up of ionic Na-N bonds and non-covalent Na-π-DHP interactions, similar to those seen between alkali-metals and an Al-bound DHP ligand^39,40, is likely.

Fig. 3. Molecular structure of 1·Me₆TREN.

The molecular structure of 1·Me₆TREN with ellipsoids shown at 50% probability and all hydrogen atoms except that on C1 and minor disordered components of Me₆TREN ligand removed for clarity. Selected bond lengths and angles: Na1-N1, 2.344(2); Na1-N3, 2.557(2); Na1-N4, 2.564(2); Na1-N5, 2.484(2); Na1-N6, 2.528(2); N1-C1, 1.480(3); C1-C2, 1.513(3); C2-C3, 1.363(3); C3-C4, 1.425(3); C4-C5, 1.382(4); C5-N1, 1.317(4); C3-N2, 1.428(3); C1-N1-C5, 115.5(2); N1-C1-C2, 112.2(2); C1-C2-C3, 122.2(2); C2-C3-C4, 118.3(2); C3-C4-C5, 116.1(2); C4-C5-N1, 129.0(2); C2-C3-N2, 122.1(2); C4-C3-N2, 119.6(2).

To test whether monomeric sodium dihydropyridyl 1·Me₆TREN showed any catalytic activity we chose the conversion of 1,1-diphenylethylene (DPE) to 1,1-diphenylethane as a representative reduction reaction (see inset reaction in Fig. 4). Previous studies^41–43 have established that 1,4-cyclohexadiene (CHD) is a convenient, easily handled liquid transfer hydrogenation reagent so it was employed as the hydrogen source. Alkali-metal-mediated reactions are often solvent dependent with some of the most distinct behaviours found between low-polarity arene and polar ether solvents, therefore C₆D₆ and d₈-THF respectively were investigated as the medium in this study with the temperature fixed at 70 °C and catalyst loading at 10 mol%. For 1, in the absence of Me₆TREN, the reaction took 24 hours in C₆D₆ to reach quantitative (99%) conversion as measured by consumption of the alkene substrate 1,1-diphenylethylene with virtually quantitative yield of the product,1,1-diphenylethane (Table 1, entry 1). However, in d₈-THF, 99% conversion was accomplished in just 0.5 hours, with essentially no reduction in product yield (entry 3). Solubility is not an issue as 1 is fully soluble at 70 °C in both solvents though its solubility drops in C₆D₆ at 25 °C. Analogous reactions with monomeric 1·Me₆TREN reached full conversion in both solvents in less than one hour though there were small reductions of 6% and 10% in product yields (93% and 89%) in C₆D₆ and THF-d₈ respectively (entries 2 and 4). These results strongly hint that the key factor in catalytic performance is the size of the molecular structure of the catalyst in solution with the aforementioned DOSY studies implicating monomeric structures for both 1·Me₆TREN in C₆D₆ (consistent with its solid-state structure) and 1 in d₈-THF which is likely to be 1·(THF-d₈)₄. These values are far superior to their lithium counterparts demonstrating the importance of sodium in this catalysis. In benzene solution, complete conversion is not achieved after 24 h, with yields of only 24 and 31% witnessed in the absence and presence of Me₆TREN respectively (entries 5 and 6). In THF solution, reactions reach 99% conversion after 6 hours (no Me₆TREN, entry 7) and 3 hours (with Me₆TREN, entry 8) but with inferior yields of 68 and 44%.

Fig. 4. Proposed catalytic mechanism for transfer hydrogenation of 1,1-diphenylethylene with 1,4-cyclohexadiene to yield 1,1-diphenylethane and benzene.

All reactants are shown in red and final products are shown in blue.

Table 1.

Comparison of data for sodium-catalysed conversion of 1,1-diphenylethylene to 1,1-diphenylethane

Entry	Catalyst	Equivalents of Me6TREN	Solvent	T [oC]	Time [h]	Conversion [%]	Yield [%]
1	NaDH(DMAP)	0	C6D6	70	24	99	99
2	NaDH(DMAP)	1	C6D6	70	0.5	99	93
3	NaDH(DMAP)	0	THF-d8	70	0.5	99	98
4	NaDH(DMAP)	1	THF-d8	70	1	99	89
5	LiDH(DMAP)	0	C6D6	70	24	30	24
6	LiDH(DMAP)	1	C6D6	70	24	80	31
7	LiDH(DMAP)	0	THF-d8	70	6	99	68
8	LiDH(DMAP)	1	THF-d8	70	3	99	44
9	NaH	1	C6D6	70	24	0	0
10	NaH	1	THF-d8	70	24	0	0
11	NaHMDS	1	C6D6	70	5	95	79
12	NaHMDS	1	THF-d8	70	24	85	80
13	NaTMP	1	C6D6	70	2.5	99	95
14	NaTMP	1	THF-d8	70	24	99	57
15	nBuNa	1	C6D6	70	3	99	96
16	nBuNa	1	THF-d8	70	3	99	50
17	NaDHP	0	C6D6	70	24	50	29
18	NaDHP	1	C6D6	70	3	99	99
19	NaDHP	0	THF-d8	70	3	99	80
20	NaDHP	1	THF-d8	70	3	99	81

Reactions all carried out with 10 mol% catalyst loading using 0.3 mmole scale reaction in 0.5 mL using 1.5 equivalents of 1,4-CHD. Conversions were calculated by depletion of 1,1-diphenylethylene (integration versus SiMe₄ standard) while yields were calculated on generation of 1,1-diphenylethane (also integration versus SiMe₄ standard).

The next part of our study compared these catalytic performances with those of other related sodium compounds under the same conditions. These comprised NaDHP, [Na-1,2-tBu-DHP], where the 4-substituent has switched from a dimethylamino group in 1 to a hydrogen atom, the aforementioned utility amides NaHMDS and NaTMP, an alkylsodium reagent (nBuNa) and the common bench reagent NaH. The most predictable outcome was the failure of the salt NaH (entries 9 and 10) to generate any product at all due to its insolubility in both organic solvents even in the additional presence of a molar equivalent of Me₆TREN. We note that Chiba recently reduced 1,1-DPE using excess of a NaH/NaI mixture in 87% yield although this required a solvothermal process at 100 ^oC for one day⁴⁴. Sterically more demanding NaTMP is known to be a stronger more reactive Brønsted base than NaHMDS¹², which may give it an advantage in any initial deprotonation of cyclohexadiene (see mechanism discussion, vide infra) but the comparative data in Table 1, though in the expected order of reactivity, are not significantly different (see Supplementary Information section 3 - Supplementary Figs. 17–36, for all related spectra). In the presence of a molar equivalent of Me₆TREN each amide performs well in C₆D₆ with NaTMP having a slight edge in both reaction time and product yield (by 2.5 hours and 16%, respectively, entries 11 and 13), though significantly these reactions are slower than those with 1·Me₆TREN which are complete within 0.5 hours (entry 2). The performances of NaHMDS and NaTMP fall off sharply in THF-d₈ (entries 12 and 14), taking 24 hours to reach completion (in the case of NaHMDS to only 85%) and a degree of decomposition is apparent with NaTMP reflected by a drop in product yield to 57%. Degradation of reaction mixtures of NaTMP in THF have previously been noted⁴⁵ and stoichiometric reaction of NaTMP with DPE shows deprotonative processes occur. NMR spectra show a number of unidentified resonances although some appear to be consistent with formation of 1,1,2-triphenylethane⁴⁶ and display no evidence for dimerization products as witnessed previously by Harder⁴⁷. These substantially longer reaction times suggest that the mechanisms in bulk THF-d₈ medium for both NaTMP and NaHMDS with added Me₆TREN differ substantially from those in C₆D₆. No such large solvent-dependent distinction was witnessed with 1·Me₆TREN, implying that the mechanism/s of its reactions are likely to be similar, though the possibility of different mechanisms due to different aggregations/stabilities of these amides in the solvents employed cannot be ruled out. The strong alkyl base nBuNa was also tested, showing similar results to NaTMP. Specifically, conversion was complete within 3 h, with the yield of the desired product dropping from 96% in C₆D₆ to 50% in THF (entries 15 and 16). Moving to the results for NaDHP, where the Me₂N group has been removed from the dihydropyridyl ring, the trends observed seem more akin to those of NaDH(DMAP) than to those of the utility amides. Entry 17 bears some resemblance to that of entry 1 since in the absence of any Lewis base donor solvent catalytic reaction time is extended considerably in C₆D₆ though the DH(DMAP) pre-catalyst is superior to its less substituted rival in both conversion (99% vs. 50%) and product yield (99% vs. 29%). On addition of monomerising agent Me₆TREN, NaDHP improved by orders of magnitude with 99% conversion achieved in only 3 h in both C₆D₆ and THF-d₈ with product yields high (99% and 81%, entries 18 and 20), though as seen with NaDH(DMAP) some instability of the reaction solution is seen in bulk THF-d₈. NaDHP also performs well in neat THF-d₈ without any Me₆TREN presence, exactly matching its performance in that donor solvent when an equivalent of Me₆TREN is present (entry 19). The data collected for NaDHP in entries 18-20, lie in the same ballpark as those for NaDH(DMAP) in entries 2–4, though in every case NaDH(DMAP) is modestly superior with reactions completed in about 1 hour compared to 3 hours in 93-99% compared to 80-99% product yields. A plausible empirical conclusion at this stage could be that NaDHP and NaDH(DMAP) could be operating in a similar way in these catalytic processes and that the relatively small differences between them could be due to the electronic and/or steric influences of the Me₂N substituent attached to the ring in the latter compound. This is corroborated by preliminary theoretical investigations, wherein comparison of the DHP and DH(DMAP) charge densities reveal minor subtle differences between the two ring systems. CHELPG charges highlight the effect of including an electron donating group, as a slight increase in the negative charge is seen on the nitrogen atom (NaDHP -0.986 vs NaDHDMAP -1.068) in line with the expected increase in nucleophilic character (see Supplementary Information section 5—Supplementary Figs. 40–41 and Supplementary Tables 10–13).

The development of catalysts and pre-catalysts for environmentally benign organic transformations including alkene to alkane transformation is a highly active area of research. Most literature catalysts to date feature transition-metal complexes^48–51, but increasing emphasis is being placed on examples based on main-group elements for the reasons alluded to in the introduction. The specific reduction reaction of 1,1-diphenylethylene to 1,1-diphenylethane investigated here has been studied with several such main group element catalysts, since it is least prone to unwanted side reactions so is a good model alkene^{42,47,52–56}. Most relevant to our present study are those based on sodium’s nearest heavier congener potassium⁵⁷. Guan found that KH (10 mol% loading) afforded less than 5% product when using direct hydrogenation via H₂ at 6 bar in C₆D₆ for 6 h at 60 ^oC, but this improved to a quantitative yield on mixing KH with KHMDS or M(HMDS)₂ where M = Mg, Ca, or Zn under the same conditions. We also used a bimetallic approach via the defined compound KMg(HMDS)₃ (10 mol%) achieving quantitative yield in 1.5 hours at 75 ^oC using transfer hydrogenation from 1,4-cyclohexadiene⁸.

We are therefore able to propose a catalytic cycle, taking the above cited previous literature and our observations into account (Fig. 4). The principal catalytic cycle likely involves reduction of the DPE substrate by the sodium pseudo-Meisenheimer intermediate (step a) which generates 1,1-diphenylethylsodium with concomitant release of benzene. This substituted alkyl sodium can then operate as a Brønsted base in its own right, deprotonating CHD to reform the sodium pseudo-Meisenheimer complex and release the 1,1-diphenylethane product (step b). It is plausible that the variable results discussed above are a consequence of distinct entry points available to the sodium pre-catalysts. Dihydropyridyl complexes have access to two points of entry as they can act as conventional sodium amide bases, deprotonating CHD to generate the intermediate Na pseudo-Meisenheimer complex (path c) or alternatively as a molecular sodium-hydride induced reducing agent for the generation of the alkyl sodium intermediate (path d). Both paths c and d generate rearomatized 2-tbutyl-4-dimethylaminopyridine, as witnessed in their ¹H NMR spectra (see Supplementary Information section 4 - Supplementary Figs. 37-39). The possibility of 1 acting as a reducing agent is supported by its stoichiometric reaction with the unsaturated substrate, which after 2 hours at 70^oC in C₆D₆ solvent results in essentially complete conversion to 1,1-diphenylethylsodium, as evidenced by generation of a singlet representing the methyl group, at 2.34 ppm. We also probed pathway c stoichiometrically and duly observed evolution of H₂ at 4.55 ppm in the ¹H NMR spectrum after one hour at 70 ^oC in THF-d₈ alongside rearomatization of the pyridine, confirming the viability of this alternative entry point. In contrast, the sodium utility amides can act as bases only, accessing the catalytic cycle by deprotonating CHD to give Na pseudo-Meisenheimer complex with concomitant formation of secondary amine (step e). This then introduces the possibility of this non-volatile by-product being preferentially deprotonated at a later stage by the ethylsodium (step f), forming the reduced organic product whilst reforming the sodium utility amide and introducing an alternative catalytic cycle with an additional step.

Conclusions

In this research we have synthesised a target sodium amide complex, but a specialised type in that it is a DMAP-substituted dihydropyridyl complexed by the polydentate polyamine Me₆TREN. As planned for, the reported complex here is a monomer in the solid-state and from DOSY studies appears to retain this state in C₆D₆ solution. The specialness of this sodium amide lies in its twofold reactivity as our observations show that it can act both as a conventional metal amide in performing deprotonating reactions and a molecular hydride source, whereas conventional metal amides only possess the former reactivity. This reactivity of 1·Me₆TREN has proved useful in the representative reduction reaction of the alkene Ph₂C = CH₂ to the alkane Ph₂(H)C-CH₃, in which it has outperformed the common utility amides NaHMDS and NaTMP as well as the insoluble, inert sodium hydride which showed no catalytic reactivity at all (although stoichiometric reactivity is possible under extreme conditions). These results underline that with proper development compounds of earth abundant sodium could begin to join the elite compounds of scarce transition metals with regard to their usefulness in homogeneous catalysis of fundamentally important organic transformations. Future work will examine the scope of this reaction with a library of substrates, probe the mechanisms of the catalyses by theoretical calculations, and extend the use of this sodium amide monomer (and other related dihydropyridyl monomers yet to be synthesised) to other industrially important organic reactions.

Methods

For general experimental procedures see Supplementary Information section 1 - Supplementary Methods, Supplementary Figs. 1–12 and Supplementary Table 1.

Synthesis of Na-1,2-tBu-DH(DMAP) (1)

DMAP (0.366 g, 3 mmol) was added to a Schlenk flask along with hexane (15 ml) and NaOtBu (0.288 g, 3 mmol). The solution mixture was cooled to 0 ^oC using an ice bath and then tBuLi (1.7 M in pentane, 1.76 ml, 3 mmol) was added dropwise via syringe. The resultant cloudy yellow solution was left to stir for 4 hours producing an off-white suspension. The solvent was then removed via cannula filtration and the white solid was dried under reduced pressure. The compound was then transferred into the glove box, weighed and stored at -20 ^oC in the freezer as a white powder material (0.55 g, 90% yield).

¹H NMR [400.03 MHz, 300 K, THF(d₈)]: δ 0.82 (s, 9H, tBu), 2.54 (s, 6H, NMe₂), 3.10 (dd, 1H, C1-H), 3.45 (d, 1H, C2-H), 4.06 (dd, 1H, C4-H), 6.80 ppm (d, 1H, C5-H); ¹³C {¹H} NMR [100.60 MHz, 300 K, THF(d₈)]: δ 152.00 (C5-H), 80.17 (C4-H), 69.59 (C1-H) 68.78 (C2-H), 39.61 (NMe₂), 39.12 (quaternary [DH(DMAP)]), 24.70 ppm (tBu).

Synthesis of [Na-1,2-tBu-DH(DMAP)]·Me₆TREN (1·Me₆TREN)

Na-1,2-tBu-DH(DMAP) (1 mmol, 0.202 g) was added to a vial of hexane (5 ml) in the glovebox. Me₆TREN (1 mmol, 0.26 ml) was subsequently added, and the suspension was left to stir for 5 minutes. The resultant yellow solution was placed into the freezer at −20 ^oC. After 24 hours transparent large block crystals had formed which were isolated and stored in the glovebox freezer (0.34 g, 80% crystalline yield).

¹H NMR [400.03 MHz, 300 K, C₆D₆]: δ 1.45 (s, 9H, tBu), 2.07 (s, 30H, Me₆TREN), 2.95 (s, 6H, NMe₂), 3.76 (dd, 1H, C1-H), 4.02 (d, 1H, C2-H), 4.70 (dd, 1H, C4-H), 7.23 ppm (d, 1H, C5-H); ¹³C {¹H} NMR [100.60 MHz, 300 K, C₆D₆]: δ 153.00 (C5-H), 79.85 (C4-H), 71.79 (C1-H), 70.60 (C2-H), 56.60 (CH₂ Me₆TREN), 50.88 (CH₂ Me₆TREN), 44.58 (CH₃ Me₆TREN), 42.68 (NMe₂), 41.05 (quaternary [DH(DMAP)]), 25.40 ppm (tBu).

Author contributions

Peter A. Macdonald - practical investigation – writing – construction of supporting information. Alan R. Kennedy – crystallographic data acquisition/curation. Robert E. Mulvey – writing – original draft, conceptualization, supervision, project administration, funding acquisition. Stuart D. Robertson – supervision, writing – review and editing. Catherine E. Weetman – theoretical data acquisition/curation.

Peer review

Peer review information

Communications Chemistry thanks the anonymous reviewers for their contribution to the peer review of this work.

Data availability

The datasets generated during and/or analysed during the current study are available in the PURE repository, 10.15129/3fb4efe4-1841-4fa0-a326-cd0e3cbc866b. The X-ray crystallographic coordinates for the structure reported in this study have been deposited at the Cambridge Crystallographic Data Centre (CCDC), under deposition number 2327713. These data can be obtained free of charge from The Cambridge Crystallographic Data Centre via www.ccdc.cam.ac.uk/data_request/cif. General experimental procedures, DOSY NMR spectroscopic details, NMR spectra from catalytic and stoichiometric reactions and computational details are provided in Supplementary Information and cif file for complex 1·Me₆TREN is available as Supplementary Data file 1.

Competing interests

The authors declare no competing interests.

Supplementary information

The online version contains supplementary material available at 10.1038/s42004-024-01184-5.