Manganese(II), iron(II) and nickel(II) chloride complexes with monodeprotonated anionic guanine

Upon refluxing 2:1 mixtures of guanine (guH) and MnCl₂, FeCl₂ or NiCl₂ in a 7:3 (v/v) mixture of ethanol and triethyl orthoformate for 1–2 weeks, partial substitution of gu^? for Cl^? groups occurs, and solid complexes of the M(gu)Cl·2ROH (R = C₂H₅ for M = Mn; R = H for M = Fe, Ni) type are obtained. The new complexes are pentacoordinated and appear to be linear chainlike polymeric species, involving a single-bridged

_n backbone. Coordination number five is attained by the presence of one terminal chloro and two terminal ROH ligands per metal ion. Most probable binding sites of bidentate bridging gu^? are the N(7) and N(9) imidazole ring nitrogens. IR evidence rules out the possibility of coordination of gu^? through any of the exocyclic potential ligand sites (O(6) oxygen or N(2) nitrogen) [1].     

Adducts of guanine with chromium(III), iron(III) and oxovanadium(IV) chlorides

The preparation of well-defined adducts of the M(guH)(₂Cl₃ (M = Cr, Fe) and VO(guH)Cl₂ types (guH = neutral guanine), by refluxing ligand and metal chloride mixtures in ethanol-triethyl orthoformate, is reported. Characterization studies suggest that the new complexes are probably linear chain-like polymeric species, involving single bridges of bidentate guH ligands between adjacent metal ions. Bidentate bridging guH is most probably coordinated through the N(7) and N(9) imidazole nitrogens. The chloro ligands present in the adducts are exclusively terminal. Infrared evidence rules out the possibility of coordination of guanine through either of its exocyclic potential binding sites (i.e., CO oxygen and NH₂ nitrogen) [1].     

Tetrahedral 1:1 adducts of guanine with cobalt(II), copper(II) and zinc(II) chlorides

Adducts of the M(guH)Cl₂ type were prepared by refluxing 2:1 molar mixtures of guanine (guH) and MCl₂ (M = Co, Cu, Zn) in ethanol-triethyl orthoformate for 2–3 days. Characterization studies suggest that all three new complexes involve distorted tetrahedral configurations. A linear chainlike polymeric structural type with a single-bridged (-MguH-)_n backbone and two terminal chloro ligands per metal ion (MN₂Cl₂ chromophore) is proposed for these compounds, in view of their poor solubility in organic media, their stoichiometry in conjunction with their tetrahedral symmetry, and the reported crystal structures of 9-methyladenine analogs (M = Co, Zn), which are polymeric with single bridges of the adenine derivative between adjacent metal ions. Bidentate bridging guH coordinates exclusively through ring nitrogens, and is most probably N(7), N(9)-bonded. The possibility of use of exocyclic potential ligand sites of guH (CO oxygen or NH₂ nitrogen) in coordination is ruled out by the infrared evidence [1].     

The synthesis of some polyether bridged diphosphines and their reaction with Rh(COD)acac

The polyether bridged diphosphines,

(n = 1,2) have been prepared in 60–70% yield by reduction of the corresponding diphosphinedioxides with Si₂Cl₆ or (i-Bu)₂AlH. These diphosphinedioxides have been prepared in 75–90% yield by reaction of two equivalents of the appropriate

with one equivalent of di- and triethylene glycol ditosylate.In general, reaction between the diphosphines, Rh(COD)acac and HClO₄ gives a mixture of species, cis-[Rh(COD)($\text{PP}$)] [ClO₄] being the main complex. This complex reacts with CO to η³-trans- [$\text{Rh(CO)(}\text{PO}$$\text{P}$)] [ClO₄].     

The hydrolysis of α-amino-acid esters in mixed ligand complexes with copper(II)-iminodiacetate

α-Amino-acid esters (EH⁺) interact with [Cu(IMDA)]° to give mixed ligand complexes according to the equilibrium,

where EH⁺ represents the protonated ester ⁺NH₃CH(R)CO₂R′ and IMDA^2? is HN(CH₂CO_2^?)₂. The mixed ligand complexes are only formed over a rather narrow pH range (ca. pH 5.8–6.5). At higher pH there is kinetic evidence for the competing equilibrium,

Rate constants k_OH have been obtained by pH-stat for the hydrolyses [where A^? = NH₂CH(R)CO_2^?]

The complexed α-amino-acid esters undergo base hydrolysis ca. 10⁴ times faster than the free esters E. Values of k_OH show little dependence on the nature of the alkyl substituent R but the normal leaving group effect of methyl esters hydrolyzing at ca. twice the rate of ethyl esters is observed. Activation parameters have been determined for base hydrolysis of [Cu(IMDA)(glyOMe)]°, and possible mechanisms for the reaction are considered.     

Adenine complexes with divalent 3d metal chlorides

Upon refluxing 2:1 mixtures of adenine (adH) and divalent 3d metal chloride hydrates in a 7:3 (v/v) mixture of ethanol-triethyl orthoformate for several days, partial substitution of ad^? for Cl^? ligands occurs, and solid complexes of the M(ad)Cl· 2H₂0 (M = Mn, Zn), Fe₂(ad)(adH)₂Cl₃·2H₂O, M(ad)- (adH)Cl·H₂O (M = Co, Cu) and Ni₂(ad)₃Cl·6H₂O types are eventually isolated [1]. It is probably of interest that during analogous previous synthetic work, involving interaction of ligand and salt in refluxing ethanol, no substitution reactions between Cl^? and ad^? took place, and MCl₂ adducts with neutral adH were reportedly obtained. Characterization studies suggest that the new complexes reported are linear chainlike polymeric species, involving single adenine bridges between adjacent M²⁺ ions. Terminal chloro, adenine and aqua ligands complete the coordination around each metal ion. The new Ni²⁺ complex is hexacoordinated, whilst the rest of the complexes are pentacoordinated. Most likely binding sites are considered to be N(9) for terminal unidentate and N(7), N(9) for bridging bidentate adenine [1].     

Kinetics of the decomposition of hydrogen peroxide in the presence of ethylenediaminetetraacetatocerium(IV) complex

The rate of reaction of [Ce(EDTA)(OH)_nⁿ⁻] with H₂O₂ in 0.10 M KNO₃ solution was investigated at various temperatures. The presence of a peroxy intermediate is inferred from spectrophotometric measurements. The general rate equation,

is valid for pH 7-9 with n= 1 and 2 complexes involved. The rate constants k_l and k₂ were determined at 25 °C to be 0.054 and 0.171 M⁻¹ s⁻¹ respectively. The corresponding activation enthalpies, as calculated from Arrhenius plots, were δH₁^#= 51.3 ± 14.8 and δH₂^#= 41.8 ± 5.3 kJ m⁻¹ and the activation entropies were δS₁^#=-97 ± 47 and ΔS₂^#=−119±17 J K⁻¹ m⁻¹.     

Synthesis, characterization and crystal structure of novel mononuclear peroxotungsten(VI) complexes. Insulinomimetic activity of W(VI) and Nb(V) peroxo complexes

Two new mononuclear peroxo complexes of tungsten of the formula (gu)₂[WO₂(O₂)₂] (1) and (gu)[WO(O₂)₂(quin-2-c)] (2a) (where gu⁺ = guanidinium ion, and quin-2-c = quinoline-2-carboxylate ion) have been synthesized and characterized by elemental analysis, infrared, Raman, UV-visible and ¹H NMR spectroscopies. The crystal structure of (gu)[WO(O₂)₂(quin-2-c)] · H₂O (2b) determined by X-ray diffraction indicates that the side-on peroxo groups and the bidentate quinaldate ligand bind the W(VI) centre leading to an hepta coordination mode. The guanidinium ion occurring as a counterion and the hydrogen-bound interactions stabilize the complexes. The in vitro insulin-mimetic effect of the complexes has been evaluated by the inhibitory effect on free fatty acid release in isolated fat adipocytes treated with epinephrine. Moreover the niobate analogues, synthesized and characterized previously, (gu)₃[Nb(O₂)₄] and (gu)₂[Nb(O₂)₃(quin-2-c)] · H₂O have been tested for the insulin-like activity.     

O,O-Alkylene dithiophosphates of palladium(II) and their adducts with triphenylphosphine

The diamagnetic square-planar, O,O-alkylene dithiophosphates of palladium(II) with the general formula,

(where G(OH)₂  2,3-dimethylbutane-2,3-diol; butane-2,3-diol; 2-methylpentane-2, 4-diol and 2, 2-dimethylpropane-1,3-diol) have been synthesized by the reactions of potassium tetrachloropalladate(II) with ammonium alkylene dithiophosphates or the parent alkylene dithiophosphoric acid in 1:2 molar ratios. These compounds are orange or brown coloured solids and except for bis(neopentylene dithiophosphato)palladium(II), they are soluble in halocarbons (CHCl₃ and CH₂Cl₂). IR, NMR (¹H and ³¹P) and electronic spectra along with magnetic data indicate four-coordinated planar geometry for these derivatives. With triphenylphosphine, the above derivatives form 1:1 solid halocarbon soluble adducts, the structures of which have been elucidated by low temperature ³¹P NMR spectra.     

Nonenzymic hydrolysis of ATP–infrared investigations of intermolecular interactions

The nonenzymic hydrolysis of

and

were studied by infrared (IR) spectroscopy. Protons resulting from hydrolysis of ATP are not bound to the N₁ atoms of the adenine residues. With hydrolysis of

, these protons are partially bound to the terminal phosphate group of ADP, namely,

,

,

, and

, present after hydrolysis. With decreasing pH or when Mg²⁺ ions are present, all hydrolysis protons are attached to the orthophosphate molecules.With hydrolysis of

the pH decreases up to 40% degree of hydrolysis. Then the system becomes self-buffered in the physiological pH region. A similar pH decrease is found with hydrolysis of

. With these systems, however, the pH decreases slightly also at degrees of hydrolysis larger than 40%. No other systems show pronounced pH changes during hydrolysis; in other words, they are buffer systems.The IR bands demonstrate that mesomeric bond resonance in the phosphate groups strongly depends on whether protons are present at these groups. Regarding the equilibria of proton attachment mentioned above, mesomeric bond resonance in these groups strongly depends on pH and on the presence of

ions.With hydrolysis of ATP, two POH groups are formed that bind H₂O molecules via strong hydrogen bonds, changing the solvate structure. Finally, easily polarizable hydrogen bonds are formed, for instance,

bonds with the hydrolysis of

, and

bonds with the hydrolysis of

. These bonds strongly interact with their environment. The formation of these hydrogen bonds strongly depends on pH and the presence of

ions.All these effects, especially the intermolecular ones, contribute to the change of free energy during ATP hydrolysis.     

Axial ligation of nitrogenous bases to five-coordinate chloro-meso-tetraphenylporphyrinatochromium(III)

The axial ligations of nitrogenous bases to the five-coordinate chloro-meso-tetraphenylporphyrinatochromium(III) [Cr(III)(TPP)(Cl)] were studied in a non-coordinating solvent, dichloromethane (CH₂Cl₂), by spectrophotometric methods. A correlation exists between log K for the axial ligation:

and pK_a for the N-donor ligand. This correlation suggests that ligand to metal σ bonding contributes to the complex formation, rather than does metal to ligand π back-donation.     

Ammonia desorption chemical ionization mass spectrometry of phosphatidylsulfocholine-phosphatidylcholine mixtures

Unhydrogenated or hydrogenated phosphatidylsulfocholine (2 μg) of the non-photosynthetic diatom Nitzschia alba was analyzed by ammonia desorption chemical ionization mass spectrometry (NH₃-DCIMS) using a flash heating method. Each molecular species was recognized by its quasi-molecular [M + 18]⁺ ion peak and by a substitution ion which corresponds to the replacement of -

(CH₃)₂ by -

H₃. With unhydrogenated or hydrogenated mixtures (3 μg) of Nitzschia alba phosphatidylsulfocholine and egg yolk phosphatidylcholine, in weight proportions 1:1, 1:2 and 1:5, respectively, the phosphatidylsulfocholine diagnostic [M + 18]⁺ ions appeared ahead of the phosphatidylcholine diagnostic [M + 1]⁺ ions, thus allowing analysis of phosphatidylsulfocholine separately from phosphatidylcholine. These results show that NH₃-DCIMS with fast heating is a suitable technique to study complex phosphatidylsulfocholine-phosphatidylcholine mixtures. This technique should be directly applicable to the detection of phosphatidylsulfocholine in natural phosphatidylsulfocholine-phosphatidylcholine mixtures as well as to the identification of their main molecular species.     

A survey of hydrogen bond geometries in the crystal structures of amino acids

An analysis of the geometries of the hydrogen bonds observed by neutron diffraction in thirt-two crystal structures of amino acids shows the following results. Of the 168 hydrogen bonds in the data set, 64 involve the zwitterion groups 

and $\text{C}$O₂. Another 18 are from

to sulphate or carbonyl oxygens. The majority, 46, of these

H … O bonds are three-centered (bifurcated). Nine are four-centered (trifurcated). The geometry in which the three-centered hydrogen bond involves both oxygens of the same carboxylate group is not especially favoured. When it does occur, one hydrogen bond is generally shorter and the other longer, than when the bonding involves oxygens on different carboxylate groups. The shortest hydrogen bonds are the OH … O $\text{C}$, from a carboxylic acid hydroxyl to a carboxylate oxygen, and NH … O$\text{C}$ when the nitrogen is the ring atom in histidine or proline. Carboxylate groups, on average, accept six hydrogen bonds, with no examples of less than four bonds. The reason for the large number of three-centered

H … O$\text{C}$ bonds is therefore a proton deficiency arising from the disparity between the tripled donor property of the

groups and the sextuple, on average, acceptor property of the carboxylate groups. There is good geometrical evidence for the existence of H … O and H … Cl^? hydrogen bonds, especially involving the hydrogen atoms on α-atoms.     

Synthesis and characterisation of a series of 1,2-phenylenedioxoborylcyclopentadienyl-metal complexes [Ti(IV), Zr(IV), Hf(IV), La(III), Ce(III), Yb(III), Sn(II) and Fe(II)]

The preparation of a series of 1,2-phenylenedioxoborylcyclopentadienyl-metal complexes is described. These are of formula [M{η⁵-C₅H₄(BX)}Cl₃] [M = Ti and X = CAT (2a), CAT^t (2b) or CAT^tt (2c); X = CAT^tt and M = Zr (4a) or Hf (4b)], [M{η⁵-C₅H₄(BX)}₂Cl₂] [M = Zr, X = CAT (3a) or CAT^t (3c); or M = Hf, X = CAT (3b) or CAT^t (3d)], [M{(μ-η⁵-C₅H₃BCAT)₂ SiMe₂}Cl₂] [M = Zr (5a) or Hf (5b)], [M{η⁵-C₅H₃(BCAT)₂}Cl₃] [M = Zr (6a) or Hf (6b)], [M{η⁵-C₅H₄BCAT}₃(THF)] [M = La (7a), Ce (7b) or Yb (7c)], [Sn{η⁵-C₅ H₄(BCAT^t)}Cl](8) and [Fe{η⁵-C₅H₄(BCAT^t)}₂] (9). The abbreviations refer to BO₂C₆H₄-1,2 (BCAT) and the 4-Bu^t (BCAT^t) and the (BCAT^tt) analogues. The compounds 2a-9 have been characterised by microanalysis, multinuclear NMR and mass spectra. The single crystal X-ray structure of the lanthanum compound 7a is presented.     

Synthesis, structure and solution chemistry of mixed-ligand oxovanadium(IV) and oxovanadium(V) complexes incorporating tridentate ONO donor hydrazone ligands

In the title family, the ONO donor ligands are the acetylhydrazones of salicylaldehyde (H₂L¹) and 2-hydroxyacetophenone (H₂L²) (general abbreviation, H₂L). The reaction of bis(acetylacetonato)oxovanadium(IV) with a mixture of tridentate H₂L and a bidentate NN donor [e.g., 2,2′-bipyridine(bpy) or 1,10-phenanthroline(phen), hereafter B] ligands in equimolar ratio afforded the tetravalent complexes of the type [V^IVO(L)(B)]; complexes (1)-(4) whereas, if B is replaced by 8-hydroxyquinoline(Hhq) (which is a bidentate ON donor ligand), the above reaction mixture yielded the pentavalent complexes of the type [V^VO(L)(hq)]; complexes (5) and (6). Aerial oxygen is most likely the oxidant (for the oxidation of V^IV → V^V) in the synthesis of pentavalent complexes (5) and (6). [V^IVO(L)(B)] complexes are one electron paramagnetic and display axial EPR spectra, while the [V^VO(L)(hq)] complexes are diamagnetic. The X-ray structure of [V^VO(L²)(hq)] (6) indicates that H₂L² ligand is bonded with the vanadium meridionally in a tridentate dinegative fashion through its phenolic-O, enolic-O and imine-N atoms. The general bond length order is: oxo < phenolato < enolato. The V-O (enolato) bond is longer than V-O (phenolato) bond by ∼0.07 Å and is identical with V-O (carboxylate) bond. ¹H NMR spectrum of (6) in CDCl₃ solution indicates that the binding nature in the solid state is also retained in solution. Complexes (1)-(4) display two ligand-field transitions in the visible region near 820 and 480 nm in DMF solution and exhibit irreversible oxidation peak near +0.60 V versus SCE in DMSO solution, while complexes (5) and (6) exhibit only LMCT band near 535 nm and display quasi-reversible one electron reduction peak near −0.10 V versus SCE in CH₂Cl₂ solution. The VO³⁺-VO²⁺E_1/2 values shift considerably to more negative values when neutral NN donor is replaced by anionic ON donor species and it also provides better VO³⁺ binding via phenolato oxygen. For a given bidentate ligand, E_1/2 increases in the order: (L²)²⁻ < (L¹)²⁻.     

Polarographic and spectrophotometric studies on the equilibration of Mo(V) species in HCl solutions

The equilibration of Mo(V) species has been investigated in 0.5–5 M HCl (I = 5.0). The equilibria involve the dimer(D₁)-dimer(D₂) interconversion, followed by the decomposition of D₂ to a monomeric form at greater acidities:

The equilibrium constants have been determined as K₁ = 2 ± 0.3 and K₂ = (1.5 ± 0.4) X 10^?8 at 25 °C.     

One-dimensional silver(I) and mercury(II) complexes with 1,4-bis(1-benzyl-benzimidazol-2-yl)cyclohexane (N-BBzBimCH)

The crystal structures of four Ag(I) and Hg(II) complexes of the ligand 1,4-bis(1-benzyl-benzimidazol-2-yl)cyclohexane (N-BBzBimCH) have been described, that is, [Hg₂(N-BBzBimCH)Cl₄] (1), [Hg(N-BBzBimCH)Br₂] (2), [Ag(N-BBzBimCH)](NO₃)(H₂O) (3) and [Ag₂(N-BBzBimCH)(CF₃OCO)₂] (4). All these compounds show 1D polymeric structures in the solid state. In complexes 1 and 4, the chloride ions and the trifluoroacetate groups bridge the [Hg₂(N-BBzBimCH)Cl₂] and [Ag₂(N-BBzBimCH)] fragments, respectively, to generate 1D polymers. While the bromide ions in complex 2 and nitrate groups in complex 3 are only serving as terminal ligands to suffice the coordination geometry of the metal centers. In all cases, weak intermolecular interactions such as C-H?X (X = Cl, Br) contacts, hydrogen bonds, π-π interactions and C-H?π stacking play important roles to extend the 1D chain structures to 2D network. Solid state fluorescence of these compounds was also studied.     

Variations in the coordination environment of Co, Cu and Zn complexes prepared from a tridentate (imino)pyridine ligand and their structural comparisons

The variations in the coordination environment of Co(II), Cu(II) and Zn(II) complexes with the neutral, tridentate ligand bis[1-(cyclohexylimino)ethyl]pyridine (BCIP) are reported. Analogous syntheses were carried out utilizing either the M(BF₄)₂ · xH₂O or MCl₂ · xH₂O metal salts (where M = Co(II), Cu(II) or Zn(II)) with one equivalent of BCIP. When the hydrated metal starting material was used, cationic, octahedral complexes of the type [M(BCIP)₂]²⁺ were isolated as the tetrafluoroborate salt (4, 5). Conversely, when the hydrated chloride metal salt was used as the starting material, only neutral, pentacoordinate [M(BCIP)Cl₂] complexes (1-3) formed. All complexes were characterized by X-ray diffraction studies. The three complexes that are five coordinate have distortions due mainly to the pyridine di-imine bite angle. The [Cu(BCIP)Cl₂] (2) also exhibits deviations in the Cu(II)-Cl bond distances with values of 2.4242(9) and 2.2505(9) Å, which are not seen in the analogous Zn(II) and Co(II) structures. Similarly, the two six coordinate complexes (5, 6) are also altered by the ligand frame bite angle giving rise to distorted octahedral geometries in each complex. The [Cu(BCIP)₂](BF₄)₂ (6) also exhibits Cu(II)-N_imine bond lengths that are on average 0.14 Å longer than those found in the analogous 5 coordinate complex, [Cu(BCIP)Cl₂]. In addition to X-ray analysis, all complexes were also characterized by UV/Vis and IR spectroscopy with ¹H NMR spectroscopy being used for the analysis of the Zn(II) analogue (3).     

Speciation, stability constants and structures of complexes of copper(II), nickel(II), silver(I) and mercury(II) with PAMAM dendrimer and related tetraamide ligands

The acid-base properties and Cu(II), Ni(II), Ag(I) and Hg(II) binding abilities of PAMAM dendrimer, L, and of the simple model compounds, the tetraamides of EDTA and PDTA, L¹, were studied in solution by pH-metric methods and by ¹H NMR and UV-Vis spectroscopy. PAMAM is hexabasic and six pK_a values have been determined and assigned. PAMAM forms five identifiable complexes with copper(II), [CuLH₄]⁶⁺, [CuLH₂]⁴⁺, [CuLH]³⁺, [CuL]²⁺ and [CuLH_-1]⁺ in the pH range 2-11 and three with nickel(II), [NiLH]³⁺, [NiL]²⁺ and [NiLH_-1]⁺ in the pH range 7-11. The complex [CuLH₄]⁶⁺, which contains two tertiary nitrogen and three amide oxygen atoms coordinated to the metal ion, is less stable than the analogous EDTA and PDTA tetraamide complexes [CuL¹]²⁺, which contain two tertiary nitrogen and four amide oxygen atoms, due to ring size and charge effects. With increasing pH, [CuLH₄]⁶⁺ undergoes deprotonation of two coordinated amide groups to give [CuLH₂]⁴⁺ with a concomitant change from O-amide to N-amidate coordination. Surprisingly and in contrast to the tetraamide complexes [CuL¹]²⁺, these two deprotonation steps could not be separated. As expected the nickel(II) complexes are less stable than their copper(II) analogues. The tetra-N-methylamides of EDTA, L¹(b), and PDTA form mononuclear and binuclear complexes with Hg(II). In the case of L¹(b) these have stoichiometries HgL¹(b)Cl₂, [HgL¹(b)H₋₂Cl₂]²⁻, [Hg₂L¹(b)Cl₂]²⁺, Hg₂L¹(b)H₋₂Cl₂ and [Hg₂L¹(b)H₋₅Cl₂]³⁻. Based on ¹H NMR and pH-metric data the proposed structure for HgL¹(b)Cl₂, the main tetraamide ligand containing species in the pH range <3-6.5, contains L¹(b) coordinated to the metal ion through the two tertiary nitrogens and two amide oxygens while the structure of [HgL¹(b)H₋₂Cl₂]²⁻, the main tetraamide ligand species at pH 7.5-9.0, contains the ligand similarly coordinated but through two amidate nitrogen atoms instead of amide oxygens. The proposed structure of [Hg₂L¹(b)Cl₂]²⁺, a minor species at pH 3-6.5, also based on ¹H NMR and pH-metric data, contains each Hg(II) coordinated to a tertiary amino nitrogen, two amide oxygens and a chloride ligand while that of [Hg₂L¹(b)H₋₅Cl₂]³⁻, contains each Hg(II) coordinated to a tertiary amino nitrogen, two amidate nitrogens, a chloride and a hydroxo ligand in the case of one of the Hg(II) ions. The parent EDTA and PDTA amides only form mononuclear complexes. PAMAM also forms dinuclear as well as mononuclear complexes with mercury(II) and silver(I). In the pH range 3-11 six complexes with Hg(II) i.e. [HgLH₄Cl₂]⁴⁺, [HgLH₃Cl₂]³⁺, [Hg₂LCl₂]²⁺, [Hg₂LH₋₁Cl₂]⁺, [HgLH₋₁Cl₂]⁻ and [HgLH₋₂Cl₂]²⁻ were identified and only two with Ag(I), [AgLH₃]⁴⁺ and [Ag₂L]²⁺. Based on stoichiometries, stability constant comparisons and ¹H NMR data, structures are proposed for these species. Hence [HgLH₄Cl₂]⁴⁺ is proposed to have a similar structure to [CuLH₄]⁶⁺ while [Hg₂LCl₂]²⁺has a similar structure to [Hg₂L¹(b)H₋₅Cl₂]³⁻.