General and historic aspects of the spontaneous resolution of coordination compounds

The microscopic world of molecules is three-dimensional, which comprises the field of stereochemistry. The spatial views of molecular chemistry and the stereochemical properties of molecules are determined by the chemical topologies. These are the crucial factors for the microscopic properties of single molecules and of ensembles of molecules, which is their colligative properties appearing in macroscopic units, such as liquids and solids.

This article deals with the stereochemical properties of chiral coordination compounds. Chiral molecules appear in isomeric forms as mirror and mirror images called enantiomers. Many physical and chemical properties of enantiomers are the same. Our hands for instance are also chiral and the shapes of left and right hands are the same; but our hands are distinguished by the inability to be overlayed, a phenomenon named accordingly as chirality or handedness. Chiral molecules exist thus as left-handed and right-handed forms, which at first glance appear easily distinguishable visually, but cannot for instance be differentiated by various spectroscopic methods, like for instance by IR or UV-vis spectroscopy. The shapes of molecules would allow easy physical distinction of left-handed and right-handed molecules, but unfortunately we cannot make the shapes of single molecules easily visible.

Using however polarized light applying the physical method of polarimetry, we can distinguish the left-handed and right-handed forms of molecules, the enantiomers, as single molecules or as an ensemble of a large number of molecules. Polarimetry is an early spectroscopic method of chemistry applied since the early 19th century. It is very helpful to distinguish enantiomers and can support the chemical resolution process of the enantiomers, but can normally not be used to resolve enantiomers, which remains in synthetic chemistry one of the most difficult tasks.

When chiral molecules are generated by chemical reactions, which do not provide chirally discriminating conditions, the left-handed and right-handed molecules have the same probability to be formed. This leads to 1:1 mixtures of left-handed and right-handed molecules called racemates or racemic mixtures. However, in contrast to the gaseous state, ensembles of molecules in the liquid or solid state show attractive interactions among each other, which are in the solid state physically expressed as lattice energies. They depend in magnitude on the specific arrangement of the molecules in the lattice of the crystal. Favourable stereochemical arrangements are of lower lattice energy and consequently have a higher tendency to appear in the crystalline state. In most cases of chiral molecules, the racemates are of lower lattice energy in the solid state causing in nature a preference for the formation of racemates. Only in rare cases the arrangement of molecules with the same handedness is of lower lattice energy than that of the corresponding racemic mixture. Under these circumstances chiral molecules form crystals containing enantiomers of the same handedness, a phenomenon, which is called spontaneous chiral resolution. Spontaneous chiral resolution of chemical compounds played a pivotal role in the development of stereochemistry, the spatial views of the molecules in three dimensions. In the 19th century the discipline of stereochemistry started in the realm of organic chemistry and provided soon the very fundamental understanding of molecular structures and reactions. For organic chemistry this development was connected to a move from two-dimensional views into the third dimension. Thus organic stereochemistry was discovered, which actually culminated in the discovery of Louis Pasteur in 1848 that carbon based organic compounds can spontaneously resolve in the solid state into crystals of the same enantiomer. At the same time this event marked the discovery of the chirality of molecules. Later in the development of stereochemistry, methods were found to resolve racemates into enantiomers using chiral auxiliaries applying appropriate chemical reactions. One of these separation methods - used particularly some 60 years later in the group of Alfred Werner in the field of coordination chemistry - was the conglomerate crystallization of salts, where ions of enantiomers are separated by formation of diastereomeric salts using a chiral counterion as chiral auxiliary.

PhD theses

The cis-[dinitrobis(ethylenediamine)cobalt] X salts (X = Cl, Br) are the one of the rare series of complexes within the thousands of compounds prepared in the Alfred Werner group, which as revealed by X-ray crystallography were found in modern times as spontaneously crystallizing chiral solids crystallizing in the chiral space group P 21 (Bernal et al., 1993; Kostyanovsky et al., 2001). It is worth entioning that the corresponding iodide salt cis-[dinitrobis(ethylenediamine)cobalt] I crystallizes in a centrosymmetric space and can therefore not appear in spontaneously resolved chiral crystals. The cis-[dinitrobis(ethylenediamine)cobalt]X salts (X = Cl, Br) were subject of the PhD theses of several of Alfred Werner's coworkers in the period of time from 1901 to 1904 and came back later from 1913 to 1914 in a sort of revival of the theme:

These PhD theses on cis-[dinitrobis(ethylenediamine)cobalt]X salts should be considered as milestones with regard to the development of chiral octahedral complexes (see head pages of the most important theses in Fig. 3). Apart from the chiral [dinitrobis(ethylenediamine)cobalt]X salts these dissertations report in some cases also on racemic salts from the [dinitrobis(ethylenediamine)cobalt]⁺ cation possessing anions, which do not give rise to spontaneous chiral resolutions.

Figure 3 Head pages of the most important dissertations of the Alfred Werner group dealing with the [cis-dinitrobis(ethylenediamine)cobalt]X (X=Cl, Br) salts: from left to right and from top to bottom the dissertations of Adolf Grün, Edith Humphrey, Ernst Zinggeler, Heinrich Schwarz, Paul Larisch and Richard Hessen. 

[cis-Dinitrobis(ethylenediamine)cobalt]X (X = Cl, Br) complexes from the Werner collection of the University of Zurich investigated in PhD theses between 1901 and 1904 and 1913 and 1914

Even though [dinitrobis(ethylenediamine)cobalt]X salts are by far not the only types of complexes, which were studied in Alfred Werner's group. They were indeed a central theme of the group and are running like a thread through Alfred Werner's scientific achievements in coordination chemistry. The [dinitrobis(ethylenediamine)cobalt] cations appear in cis- and trans-isomeric forms, all thoroughly investigated in Alfred Werner's group. Alfred Werner denoted these isomeric forms also as 1,2- or 1,6-forms or in the very early days of his research also as flavo- and croceo-derivatives according to their colours (see Fig. 4, early notations as annotations in brackets).

Figure 4 Isomers of the [dinitrobis(ethylenediamine)cobalt]+ cation. 

The cis-configured cations, which are the subject of this report, go together in salts with counteranions, from which only the chloride and bromide are spontaneously crystallizing in chiral crystals. Other salts with mono- or dianionic counterions crystallize in centrosymmetric space groups as racemates showing image and mirror image in the same crystal.

Spontaneous chiral separation of [cis-dinitrobis(ethylenediamine)cobalt]Br prepared by Edith Humphrey in the group of Alfred Werner

In the group of Alfred Werner the PhD work of Edith Humphrey dealt with the preparation of various [dinitrobis(ethylenediamine)cobalt]X salts, among them X = Cl, Br (Fig. 4) with the spontaneously separating enantiomeric crystals, but containing also other complexes with X = NO₃, X = 1/2SO₄ and 1/2[PtCl₄], crystallizing in achiral space groups. The preparations of these complexes are all well described in her PhD thesis. A major aspect of the work of Edith Humphrey could have been the resolution of enantiomorphic crystals of the [cis-dinitrobis(ethylenediamine)cobalt]Br salt by manual crystal picking carried out in the same way as Louis Pasteur had done it for a tartaric acid derivative in 1848. This aspect of her work has been reviewed several times by various authors and had been themed 'the missed opportunity', since Edith Humphrey had not attempted separation by the Louis Pasteur method. Based on modern time's work of Ivan Bernal, who carried out an X-ray diffraction analysis of the [cis-dinitrobis(ethylenediamine)cobalt]Br salt, the chance was given that Edith Humphrey's crystals could have been separated into enantiomorphs (^{Bernal, 1999}).

We once again had a close inspection the vial of Edith Humphrey containing crystals of the [cis-dinitrobis(ethylenediamine)cobalt]Br complex stored in the Alfred Werner collection of original samples at the University of Zurich. We examined Edith Humphrey's crystal batch (Fig. 5(left)) and searched again for enantiomorphic crystals. We did not find enantiomorphic crystals with the [cis-dinitrobis(ethylenediamine)cobalt] cation other than those two we had already published in an earlier paper (Ernst & Berke, 2011; Ernst, Wild, Blacque, & Berke, 2011). Anyway we expected that only crystals containing the [cis-dinitrobis(ethylenediamine)cobalt]⁺ cation in enantiomerically pure form could be enantiomorphs and such crystals are expected to be very rare in any spontaneous crystallization batch of the [cis-dinitrobis(ethylenediamine)cobalt]Br salt (^{Bernal et al., 1993}). Also based on the related structural study and on the crystallization behaviour of the [cis-dinitrobis(ethylenediamine)cobalt]Cl salt to be reported later, this complex tends to undergo synthetical twinning, which was found to lead to enrichment of one of the enantiomers. Twinned such crystals may not necessarily have enantiomorphic shapes. Synthetical twinning should also occur for Edith Humphrey's [cis-dinitrobis(ethylenediamine)cobalt]Br salt. Non-twinned single crystals of the pure enantiomer are expected to show enantiomorphic faces, but they are expected to be formed very rarely in these crystallization batches. Therefore in the case of the [cis-dinitrobis(ethylenediamine)cobalt]Br salt, we can clear Edith Humphrey of the criticism that she would have 'missed the opportunity' to achieve chiral resolution by manual crystal picking (Bernal & Kauffman, 1987; Kauffman & Bernal, 1988), because it would have been very difficult by an accidental glance at the crystals to find enantiomorphs of the [cis-dinitrobis(ethylenediamine)cobalt]Br salt. The 'omission', which she can be accused of, is more that she apparently was not aware of the possibility for spontaneous chiral resolution of her complex and had the chance to prove the existence of enantiomorphic crystals analytically by measuring optical rotation using a polarimeter, a technique well-established at her times already (^{Lyle & Lyle, 1964}). In modern times we were able to use X-ray diffraction studies, which indeed provided evidence that the investigated crystals were enantiomerically enriched due to the synthetical twinning effect in space group P 2₁, but we were unable to detect enantiomerically pure crystals by X-ray diffraction analysis. Enantiomeric enrichment in twinned crystals of the [cis-dinitrobis(ethylenediamine)cobalt]Br salt could however definitely be determined via the Flack parameter (Avalos, Babiano, Cintas, Jimenez, & Papacios, 2004; Flack, 1983; Flack & Bernardinelli, 1999). The quantitative estimate of the enantiomeric enrichment could be obtained from the Flack parameters of X-ray diffraction studies for two crystals of the [cis-dinitrobis(ethylenediamine)cobalt]Br salt, which amounted to Δ:λ ratios of 71: 29 and 41: 59, which corresponded to 42 and 18% ee's, respectively.

Figure 5 Photograph of Edith Humphrey's original vials and crystals of [cis-dinitrobis(ethylenediamine)cobalt]Br (left). Photograph of Edith Humphrey's original vials and the weathered crystals of the [cis-dinitrobis(ethylenediamine)cobalt]Cl·2H2O salts (right). Both samples from the Alfred Werner collection of original samples at the University of Zurich. 

It should be mentioned at this point that the [cis-dinitrobis(ethylenediamine)cobalt]Cl complex was also prepared by Edith Humphrey, but was crystallized as a dihydrate (Fig. 5 (right)) presumably due to the fact that she applied recrystallization from dilute water solutions (see prescription Fig. 6 (left)). The vial of this complex could be found in the Alfred Werner collection of original samples. The hydrate is apparently not stable and undergoes weathering (photograph of the weathered crystals in Fig. 5 (right)). Due to this circumstance we expected complications in X-ray diffraction studies and refrained from the determination of the crystal structure of this [cis-dinitrobis(ethylenediamine)cobalt]Cl·2H₂O compound and preferred to investigate the non-hydrated [cis-dinitrobis(ethylenediamine)cobalt]Cl for spontaneous chiral resolution into enantiomorphic crystals taken from a vial of the contemporary PhD student Adolf Grün (see section "Spontaneous chiral separation of [cis-dinitrobis(ethylenediamine)cobalt]Cl prepared by Adolf Grün in the group of Alfred Werner").

Figure 6 Edith Humphrey's (left) and Adolf Grün's prescription (right) for the preparation of [cis-dinitrobis(ethylenediamine)cobalt]Cl·2H2O and [cis-dinitrobis(ethylenediamine)cobalt]Cl, respectively, applying recrystallizations from water. Original texts from the corresponding PhD theses. 

From the vials of Edith Humphrey in the Alfred Werner collection we then studied two complexes of [cis-dinitrobis(ethylenediamine)cobalt]₂X salts possessing dianionic counterions (X = SO₄, [PtCl₄]) (see Figs. 7 and 8) to see whether these compounds would reveal crystals with spontaneously resolved chiral [cis-dinitrobis(ethylenediamine)cobalt]⁺ cations. This idea did however not prove true. The X-ray diffraction studies of both complexes revealed crystals of hydrates consisting of racemic mixtures in the unit cell (space groups Cc and C2/c). We can only speculate that this changed crystallization behaviour with respect to [cis-dinitrobis(ethylenediamine)cobalt]Cl may have to do with a changed hydrogen bonding scheme in the crystal lattice (^{Kostyanovsky et al., 2001}) or has to do with the stoichiometry of the salts. The 'excess' of cations forces in the solid state two cations getting in closer vicinity to each other, which may be the cause for the energetically prefered crystal packing of optical antipodes.

Figure 7 Photograph of the original vials of Edith Humphrey containing the cis-dinitrobis(ethylenediamine)cobalt]2SO4·H2O and the cis-dinitrobis(ethylenediamine)cobalt]2[PtCl4]·H2O from the Alfred Werner collection of original samples at the University of Zurich. 

Figure 8 Models of the molecular structures of [cis-dinitrobis(ethylenediamine)cobalt]2SO4·H2O (left) and of [cis-dinitrobis(ethylenediamine)cobalt]2[PtCl4]·H2O (right) as determined by X-ray diffraction studies from crystals prepared by Edith Humphrey stored in the Alfred Werner collection of the University of Zurich. The full data sets of the X-ray diffraction studies are deposited at the Cambridge Crystallographic Data Centre. 

Spontaneous chiral separation of [cis-dinitrobis(ethylenediamine)cobalt]Cl prepared by Adolf Grün in the group of Alfred Werner

We then had a closer look at the vials of Adolf Grün in the Alfred Werner collection of original samples and found one vial containing also the [cis-dinitrobis(ethylenediamine)cobalt]Cl salt (Fig. 9), which had also been prepared by Edith Humphrey (see Fig. 6 (left)). Adolph Grün was a contemporary of Edith Humphrey in the group of Alfred Werner, at least their times for preparing their PhD thesis were strongly overlapping. Maybe Adolf Grün had started his PhD work in Alfred Werner's group even somewhat earlier than Edith Humphrey, but both finished their PhD work in 1901. It is therefore remarkable that in this research group two PhD candidates had to tackle the synthesis of the same complex in about the same period of time. They perhaps got in competition with their task or what is quite probable in this case that they did not know from each other's work. Quite surprisingly, a closer look into the PhD theses of both candidates showed that the [cis-dinitrobis(ethylenediamine)cobalt]Cl salts were prepared in somewhat different ways (see the relevant text of the PhD theses of Fig. 6). Edith Humphrey applied dilute water solutions for recrystallization, while Adolf Grün applied '8-10' consecutive crystallizations. Apparently this was done from concentrated water solutions, which apparently led to non-hydrated crystals. The preparative procedure to obtain the non-hydrated crystals of Adolf Grün was therefore quite tedious (Fig. 6).

Figure 9 Top: The vial of Adolf Grün containing the [cis-dinitrobis(ethylenediamine)cobalt]Cl complex. Bottom left: The crystals of the vial of Adolf Grün. The crystals (see boxes) show a remarkable striation of the larger crystals indicating a layered growth process by twinning. Each striation stripe is supposed to correspond to a twinning layer. Bottom right: Edith Humphrey's crystals of [cis-dinitrobis(ethylenediamine)cobalt]Br do not show visible striation. The twinning layers of Edith Humphrey's bromide have apparently thicknesses below the visibility range. 

From Adolf Grün's vial of [cis-dinitrobis(ethylenediamine)cobalt]Cl we took four crystals, which were investigated by single crystal X-ray diffraction studies. The results with regard to spontaneous chiral resolution are shown in Table 1. The chiral enrichment of the enantiomers in the crystals was again based on twinning analyses within the X-ray diffraction analyses using Flack's method (Flack, 1983; Flack & Bernardinelli, 1999).

Table 1 X-ray diffraction studies and determination of the Flack parameters of four crystals selected from the Grün vial and one crystal was taken from a Hessen vial (conglomerate crystallization) of enantiomerically pure [Λ-,cis-dinitrobis(ethylenediamine)cobalt]Cl of the Alfred Werner collection of original samples at the University of Zurich. Cl counterions are omitted in the drawing of the Δ-,Λ-structural representations. The full data sets of the X-ray diffraction studies are deposited at the Cambridge Crystallographic Data Centre. . 

The [cis-dinitrobis(ethylenediamine)cobalt]X complexes (X = Cl, Br) were grown from racemic solutions leading for the majority crystals to synthetical twinning (^{Klockmann, 1967}) and in addition to prevalence of one enantiomer in the crystals. Naturally the twinned crystals do not possess enantiomorphic faces and may therefore show crystal habits quite different from those of the enantiomorphs (see also section "Spontaneous and conglomerate resolution of [cis-dinitrobis(ethylenediamine)cobalt]Cl carried out by Richard Hessen (PhD thesis 1914) in the group of Alfred Werner").

Spontaneous chiral separation of [cis-dinitrobis(ethylenediamine)cobalt]Cl prepared by Heinrich Schwarz in the group of Alfred Werner (PhD thesis in 1903)

Two years after the described work of Adolf Grün and Edith Humphrey, PhD student Heinrich Schwarz prepared in Alfred Werner's group again the [cis-dinitrobis(ethylenediamine)cobalt]Cl salt. Although the main task of his PhD work was to prepare new chromium complexes, Heinrich Schwarz (PhD thesis 1903) described in an appendix to his PhD thesis the syntheses of [cis- and trans-dinitrobis(ethylenediamine)cobalt]Cl complexes, which he separated by manual crystal picking. We found the vial containing the [cis-dinitrobis(ethylenediamine)cobalt]Cl compound in the Alfred Werner collection (vial Fig. 10) and studied several crystals of the vial by single crystal X-ray diffraction. Among the crystals were many of very big size (Fig. 10), which we cut into pieces to analyze their macroscopic inhomogeneity concerning their synthetical twinning structure.

Figure 10 Vial and crystals of [cis-dinitrobis(ethylenediamine)cobalt]Cl of PhD student Heinrich Schwarz taken from the Alfred Werner collection of the University of Zurich. The inserted picture shows a crystal found in the vial of Heinrich Schwarz supposed to be enantiomorphic. 

The Flack parameters were used for resolving the twin reflections and from these parameters the enantiomeric excesses of the macroscopic crystals were calculated (Flack, 1983; Flack & Bernardinelli, 1999).

Table 2 demonstrates not only that all the crystals chosen from the Heinrich Schwarz batch had chirality. Very large crystals were cut into pieces and the pieces were investigated by single crystal X-ray diffraction to demonstrate that the crystals consist of macroscopic domains of twinning layers with different chiralities. Two, cut crystals (HS2111 and HS0212) were found to be enantiomorphs of opposite chirality. A microscopic search for enantiomorphic crystals was carried out, which rendered a crystal supposedly possessing enantiomorphic faces (see inserted picture of Fig. 10), and which could well be a single crystal. We anticipated that Heinrich Schwarz's crystal batch consists of more of these enantiomorphs strengthening the notion that the [cis-dinitrobis(ethylenediamine)cobalt]Cl salt has a greater tendency for 'full' spontaneous chiral resolution than has the [cis-dinitrobis(ethylenediamine)cobalt]Br salt. The type of twinning of the enantiomerically enriched crystals (HS0711, HS1211, HS2611, HS2711, HS0312, HS0412, HS0912) is generally denoted as synthetical twinning (^{Klockmann, 1967}). For some crystals the weights were additionally determined as denoted in Table 2, because we wanted to see whether there is a dependence between size of the crystals and their enantiomeric enrichment, but apparently there is no such simple relationship. In contrast to Adolf Grün's crystals (Table 1) we found among Heinrich Schwarz's crystals no racemic crystal. This observation may be accidental, but may on the other hand indicate that Heinrich Schwarz and Adolf Grün used somewhat different crystallization procedures. As we will see in section "Spontaneous and conglomerate resolution of [cis-dinitrobis(ethylenediamine)cobalt]Cl carried out by Richard Hessen (PhD thesis 1914) in the group of Alfred Werner" the temperature of crystallization could play a prominent role and maybe there was a slight difference in temperature in the crystallization procedures of the two PhD students causing the given difference in the crystal habits.

Table 2 X-ray diffraction studies of Heinrich Schwarz's crystals of the [cis-dinitrobis(ethylenediamine)cobalt]Cl salt (Fig. 10) with the main crystal parameters determined. Very large crystals were cut into pieces. The pieces investigated by single crystal X-ray diffraction showing different enantiomeric enrichments. The full data sets of the X-ray diffraction studies were deposited at the Cambridge Crystallographic Data Centre. . 

* Weight of the parent crystal

** The numbers in brackets denote different cuts of the large parent crystal

Conglomerate resolution of [cis-dinitrobis(ethylenediamine)cobalt]Cl carried out by Ernst Zinggeler and Paul Larisch in the group of Alfred Werner (PhD theses 1902 and 1904)

A closer inspection of the archive of the PhD theses of the Alfred Werner group brought up a somewhat unexpected observation. As a matter of fact it was up to now generally accepted that the first conglomerate resolution of enantiomeric complexes was carried out in the group of Alfred Werner by PhD student Victor King (PhD thesis of 1911) (Werner & King, 1911; King, 1942). The question arose, why such chiral resolution experiments appeared so late in the group of Alfred Werner, particularly in view of the fact that chirality as a general phenomenon and the method of conglomerate resolution of diastereomeric salts were known for long. Alfred Werner apparently knew about these facts (see also Chapter "Alfred Werner and the stereochemistry of coordination compounds"), since he had postulated earlier that complexes could exist as right-handed and left-handed structures appearing as enantiomers and perhaps also as enantiomorphs.

Much to our surprise we learned from the work of Ernst Zinggeler (PhD thesis 1902) and Paul Larisch (PhD thesis 1904) that they both could separate out one enantiomer of the [cis-dinitrobis(ethylenediamine)cobalt]⁺ cation successfully by chiral conglomerate resolution using the S-(D-,d-)camphorsulfonate anion as the counterion and producing diastereomeric salts with the [Δ-(d-) and Λ-(l-)cis-dinitrobis(ethylenediamine)cobalt]⁺ cation. In many cases the diastereomeric salts have drastically distinguished solubility properties and allow separation of the diastereomers by crystallization. Ernst Zinggeler was to prepare in his thesis rhodano complexes of the [bis(ethylenediamine)cobalt] molecular fragment using the [cis-dinitrobis(ethylenediamine)cobalt]⁺ cation among others as a starting material, which in the synthetic procedure had to be separated from the [trans-dinitrobis(ethylenediamine)cobalt]⁺ cation. Paul Larisch, as the title of his PhD thesis denotes, was to measure solubilities of a series of complexes among them also the [cis- and trans-dinitrobis(ethylenediamine)cobalt]X salts. In the same way as Adolf Grün and Edith Humphrey, Ernst Zinggeler and Paul Larisch were indeed confronted with the problem to separate [cis- and trans-dinitrobis(ethylenediamine)cobalt]X compounds by crystallization and to produce pure isomers, which Heinrich Schwarz had accomplished by manual crystal picking. It looks like an incredible story that Ernst Zinggeler and Paul Larisch had chosen to use a somewhat obscure looking procedure applying quasi the method of conglomerate separation to separate the [cis- and trans-dinitrobis(ethylenediamine)cobalt]Cl mixture using the S-camphorsulfonate as the anion, an experiment, which however inevitably, but apparently unintentionally, led to chiral conglomerate separation of the rac-[cis-dinitrobis(ethylenediamine)cobalt]X salts producing the diastereomers of the Δ- or the Λ-forms. Ernst Zinggeler and Paul Larisch were apparently not aware of the chirality of the cis-complexes. Their main intention was to probe a new anion as a better separation agent for the cis- and trans-isomers of [cis-dinitrobis(ethylenediamine)cobalt]Cl hoping for enhanced solubility differences of the new salts with the S-camphorsulfonate anion (see cut-out text of Paul Larisch's PhD thesis, Fig. 11). The cis- and trans-dinitro cobalt S-camphorsulfonate salts were indeed found to have a 19-fold difference in water solubilities (almost 35 g difference per 100 g water); still as an unintentious 'side effect' of this synthetic procedure they prepared the enantiomerically pure [cis-,Λ-dinitrobis(ethylenediamine)cobalt][S-camphorsulfonate] complex, and based on this a series of [cis-,Λ-dinitrobis(ethylenediamine)cobalt]X salts.

Figure 11 Solubilities of the conglomerates of the cis- and trans-isomers of [dinitrobis(ethylenediamine)cobalt][camphorsulfonate] salts at 16.5°C in water taken from the PhD thesis of Paul Larisch. The enantiomeric cis-isomer is expected to possess the Λ-configuration when the S-camphorsulfonate anion is applied. 

Adolf Grün and Edith Humphrey developed special procedures to achieve relatively high purity of the cis-[dinitrobis(ethylenediamine)cobalt]Cl complex, but Ernst Zinggeler and Paul Larisch apparently were not content with the accomplishable purities along the synthetic lines of Adolf Grün and Edith Humphrey, particularly with regard to a complete separation of the [cis- and trans-dinitrobis(ethylenediamine)cobalt]⁺ isomers. Ernst Zinggeler and Paul Larisch had therefore chosen to use conglomerate formation for separation of the cis- and trans-isomers. Paul Larisch had quantitatively determined the solubilities of several [cis- and trans-dinitrobis(ethylenediamine)cobalt]X salts prepared from the camphorsulfonate salts (see Fig. 12 as taken from Paul Larisch's PhD thesis).

Figure 12 Solubilities of the cis- and trans- isomers of [Co(NH3)4(NO2)2]X (X=Cl, SO4) and [dinitrobis(ethylenediamine)cobalt]X salts (X=NO3, I) complexes at different temperatures in water taken from the PhD thesis of Paul Larisch, p. 61. 

These experiments were successful, because as mentioned already the solubilities of the diastereomeric Δ- or Λ-cis-derivatives with the S-camphorsulfonate anion are very different and are expected to lead to the [Λ-,cis-dinitrobis(ethylenediamine)cobalt][S-camphorsulfonate] complexes as the least soluble conglomerate salt (see also Chapter "Spontaneous and conglomerate resolution of [cis-dinitrobis(ethylenediamine)cobalt]Cl carried out by Richard Hessen (PhD thesis 1914) in the group of Alfred Werner"), while the [cis-,Δ-dinitrobis(ethylenediamine)cobalt][S-camphorsulfonate] and the [trans-dinitrobis(ethylenediamine)cobalt][S-camphorsulfonate] complexes possess high solubilities in water and stayed in solution. This is an incredible story of another missed opportunity of Alfred Werner and his group. Ernst Zinggeler was thus the first one to carry out chiral resolution of chiral complexes in the field of coordination compounds. His experiments were presumably run in 1901 at a time when Adolf Grün and Edith Humphrey were still in the group of Alfred Werner, but apparently these experiments did quite astonishingly not have any impact on the late works of Adolf Grün and Edith Humphrey.

We found the vials of [Λ-,cis-dinitrobis(ethylenediamine)cobalt][S-camphorsulfonate] salts of Ernst Zinggeler and Paul Larisch (Fig. 13) and determined exemplarily the absolute configuration of Paul Larisch's [dinitrobis(ethylenediamine)cobalt][camphorsulfonate] via an X-ray diffraction study, which indeed revealed the Λ-,cis-configuration for the [dinitrobis(ethylenediamine)cobalt]⁺ cation and the S-configuration for the camphorsulfonate anion (see Fig. 14).

Figure 13 Original vials [Λ-,cis-dinitrobis(ethylenediamine)cobalt][S-camphorsulfonate] salts of the Alfred Werner collection at the University of Zurich prepared by the PhD students Ernst Zinggeler (left vial) and Paul Larisch (right vial) in the group of Alfred Werner (PhD theses of 1902 and 1904, respectively). 

Figure 14 Structural model of [Λ-,cis-dinitrobis(ethylenediamine)cobalt][S-camphorsulfonate] obtained by a X-ray diffraction study, which demonstrates the Λ-,cis-configuration of the [dinitrobis(ethylenediamine)cobalt]+ cation and the S-configuration of the camphorsulfonate anion prepared by Paul Larisch in the group of Alfred Werner. The full data set of the X-ray diffraction study was deposited at the Cambridge Crystallographic Data Centre. 

It should be mentioned at this point that Richard Hessen also prepared the [Λ-,cis-dinitrobis(ethylenediamine)cobalt][S-camphorsulfonate] complex as an intermediate system to transform eventually this compound via conglomerate crystallization into several [Λ-,cis-dinitrobis(ethylenediamine)cobalt]X salts (see Chapter "Spoontaneous and conglomerate resolution of [cis-dinitrobis(ethylenediamine)cobalt]Cl carried out by Richard Hessen (PhD thesis 1914) in the group of Alfred Werner"). Ernst Zinggeler and Paul Larisch also prepared various [Λ-,cis-dinitrobis(ethylenediamine)cobalt]X salts from the [Λ-,cis-dinitrobis(ethylenediamine)cobalt][S-camphorsulfonate], but these derivatives could not be identified anymore in the Alfred Werner collection. We found however the [trans-dinitrobis(ethylenediamine)cobalt][S-camphorsulfonate] salt of Paul Larisch (Fig. 15) confirming his successful endeavour of separating cis- and trans-isomers of the [dinitrobis(ethylenediamine)cobalt]⁺ cations. To summarize this section, Ernst Zinggeler and Paul Larisch had deliberately chosen to use a chiral auxiliary for non-chiral purposes: the separation of cis- and trans isomers, what one might denote also as an excessive misuse of a precious chiral agent. Only the final success of their endeavours eventually could justify this somewhat mysterious approach.

Figure 15 Vial and crystals of [trans-dinitrobis(ethylenediamine)cobalt][S-camphorsulfonate] of Paul Larisch from the Alfred Werner collection of original samples at the University of Zurich. 

Spontaneous and conglomerate resolution of [cis-dinitrobis(ethylenediamine)cobalt]Cl carried out by Richard Hessen (PhD thesis 1914) in the group of Alfred Werner

From 1910 onwards, the group of Alfred Werner became very active in attempts to resolve chiral complexes via conglomerate resolutions. The awareness that complexes could be chiral and could exist in solution and in solid state as separable enantiomers (for octahedral complexes showing the Δ and Λ forms) matured in Alfred Werner's perception of coordination chemistry long before that time, since in the years before 1900 Alfred Werner had already set the grounds for such ideas creating his three-dimensional views of coordination chemistry (Ernst & Berke, 2011; Ernst et al., 2011), which was part of 'Alfred Werner's Coordination Theory' (Berke, 2009; Werner, 1893). In addition, the section "Conglomerate resolution of [cis-dinitrobis(ethylenediamine)cobalt]Cl carried out by Ernst Zinggeler and Paul Larisch in the group of Alfred Werner (PhD theses 1902 and 1904)" witnessed that chiral auxiliaries, like the S-camphorsulfonate salt (^{Werner, 1918}), were available for chiral conglomerate resolutions in the group of Alfred Werner.

The stereochemical views of Alfred Werner reached in those days of Alfred Werner's career, at the University of Zurich (around 1910), such a high level of abstraction and matched reality so well that the presumption of enantiomers of coordination compounds became an inevitable asset to his views of Coordination Theory. As expressed in the introductory part of this paper already, it is somewhat of an enigma why Alfred Werner's group then did not start to deal with his chirality endeavours in coordination chemistry already in the years of around 1900. Alfred Werner also started to publish on the asymmetric cobalt atom only in 1911. When Alfred Werner and his group could then also give experimental proof to his chirality concept of coordination compounds, Alfred Werner's Coordination Theory got then quite comprehensive and was generally accepted, and due to its experimental verification, the distinction with the Nobel Prize (1913) seemed to be in reach (Kauffman, 1968; Werner, 1912, 1918; Werner & King, 1911). As said already, polarimetry (^{Lyle & Lyle, 1964}) as an analytical tool for tracing chirality of compounds was known for long and had reached at Alfred Werner's time a high level of sophistication in its application, which became then also heavily applied in Alfred Werner's laboratory.

The first conglomerate resolution of chiral complexes was carried out in Alfred Werner's group by PhD student Victor King (PhD thesis 1911, Fig. 17) (Ernst & Berke, 2011; Ernst et al., 2011) separating the cis-[amminechlorobis(ethylenediamine)cobalt]⁺ cation (Fig. 17) as camphorsulfonate salts. Many resolutions of chiral complexes followed then in the group of Alfred Werner. Among those was also the resolution of [Δ- and Λ-dinitrobis(ethylenediamine)cobalt]Cl carried out mainly by PhD student Richard Hessen again via diastereomeric salt formation using the silver S- and D-camphorsulfonates. In Richard Hessen's nomenclature the [Δ-(d-) and Λ-(l-)dinitrobis(ethylenediamine)cobalt]Cl compounds are called the compounds of the 'd-' and 'l-Reihe' (see also Figs. 16 and 17). The two vials of Fig. 16 mark the successful resolution into the enantiomers. On the labels of the vials we find also polarimetric information. As a X-ray study of one crystal of the 'l-Reihe' vial of Fig. 16 revealed, the complex was determined to be optically pure [Λ-cis-dinitrobis(ethylenediamine)cobalt]Cl complex (see Table 1).

Figure 16 Two vials of PhD student Richard Hessen containing the [Δ-(d-) and Λ-(l-)dinitrobis(ethylenediamine)cobalt]Cl compounds obtained by conglomerate chiral resolution with S- and R-camphorsulfonate salts. Vials from the Alfred Werner collection of the University of Zurich. 

Figure 17 Selected pairs of complexes (image and mirror image) separated in the group of Alfred Werner by conglomerate resolution in the period of time from 1910 to 1914. 

The PhD thesis of Richard Hessen reviews at a very high level the stereochemical knowledge of chiral organic compounds and their resolution methodologies accumulated since the discovery of chirality by Louis Pasteur in 1848. In addition he also gave detailed information on the conditions of spontaneous chiral resolution, where the main point was that the crystallization temperatures play a decisive role marking a transition temperature, above which a spontaneous chiral resolution can no longer be achieved and racemates are obtained. For instance for Louis Pasteur's sodium potassium tartarate this temperature lies at 3 °C. Richard Hessen does not report the transition temperature for the spontaneous resolution of the dinitrobis(ethylenediamine)cobalt]Cl compound, but from his resolution experiments one can conclude that this temperature should not lie far above 24 °C. Since he had the optically active complexes in hand, he had also realized that the racemic crystals of [dinitrobis(ethylenediamine)cobalt]Cl have a much higher solubility than the corresponding enantiomeric forms and he reported in his thesis that under 'normal circumstances' the racemates of compounds have lower solubilities. He observed that the crystals of the [dinitrobis(ethylenediamine)cobalt]Cl compound have a striated surface appearance showing a 'twinning striation' (see Fig. 9, bottom (left)), which he interpreted in terms of the crystals being racemic by 'intergrowth of d- and l-crystals'. On this basis he devised seeding experiments taking a(n) (over)saturated solution of rac-[dinitrobis(ethylenediamine)cobalt]Cl and seeded this with [Δ-(d-) or Λ-(l-)dinitrobis(ethylenediamine)cobalt]Cl crystals, which he denoted as a spontaneous resolution experiments. In these cases of experiments Richard Hessen did not get purely enantiomeric crystals, but strong enrichment of one enantiomeric form, the form of the seeding crystal. The crystals showed the feature of full transparency and were nicely shaped plates (Fig. 18).

Figure 18 Crystals of [Λ-dinitrobis(ethylenediamine)cobalt]Cl obtained by Richard Hessen via seeding of a saturated solution of the racemic [dinitrobis(ethylenediamine)cobalt]Cl complex with crystals of the [Λ-dinitrobis(ethylenediamine)cobalt] chloride.