Ferrocene compounds. XXXIV. 1′-(tert-Butoxycarbonylamino)ferrocene-1-carboxylic acid

Conjugates of metallocenes with natural amino acids and peptides are of great interest in the field of bioorganometallic chemistry. Over the past five decades, many N– and C-ferrocenylamino acids and their derived peptides have been synthesized and studied. Current investigations have concentrated on 1,1'-ferrocenylenebis(amino acids) and the corresponding peptides, especially as chemical models of β-sheet and α-helix arrays, having interesting electrochemical and chelating properties (Oberhoff et al., 1996; Kraatz et al., 1997; Saweczko et al., 2001; Metzler-Nolte, 2001; Moriuchi et al., 2001; Pal et al., 2001).

Our investigations are directed towards the synthesis and characterization of a series of synthetic amino acids containing a skeletally bonded 1,1'-ferrocenylene unit. The first homologue of this class of heteroannularly substituted ferrocene compounds is 1'-aminoferrocene-1-carboxylic acid. The C– and/or N-protected derivatives of this compound, as well as its conjugates with natural amino acids (Barišić et al., 2002; Rapić et al., 2002; Barišić et al., 2003), can reveal various types of hydrogen bonds, such as N—H···O═C, O—H···O and C—H···O bonds, and a range of hydrogen-bonding patterns (infinite chains, discrete dimers, etc.; Pavlović et al., 2000; Pavlović, Barišić, Rapić & Leban, 2002; Pavlović, Barišić, Lapić & Rapić, 2002; Rapić et al., 2002), which act as models for the study of hydrogen bonding in biological environments. Therefore, such carboxy derivatives can be used as organometallic building blocks for crystal engineering (Braga et al., 2001), where R₂²(8) rings are the most frequent supramolecular synthons formed by carboxyl groups. In this context, the crystal structure of the title compound, (I), is presented here. \sch

Compound (I) crystallizes with Z' = 2 (Fig. 1). The two molecules have different conformations adjacent to the tert-Bu groups. The other parts of the molecules differ slightly. Both molecules exhibit disorder of the carboxylic acid group, with H atoms occurring statistically with equal probability (see Experimental).

Within the ferrocenyl moieties, the mean Fe—C bond distances for substituted and unsubstituted C atoms do not exhibit significant differences, according to the 3σ crystallographic criterion, with mean values for Fe—C(unsubstituted) of 2.044 (3) Å and Fe—C(substituted) of 2.054 (3) Å. The Cp rings are twisted away from the fully eclipsed conformation. The dihedral angles between the corresponding planes calculated through two C atoms and the centroids Cg1, Cg2, Cg3 and Cg4 Please define each of these are in the ranges 11.7 (6)–12.6 (3)° and 12.7 (3)–13.2 (3)° for molecules 1 and 2, containing Fe1 and Fe2, respectively. The distances between the Fe atoms and the centroids are Cg1—Fe1 1.6633 (4), Cg2—Fe1 1.6490 (4), Cg3—Fe2 1.6618 (6) and Cg4—Fe2 1.6487 Å, and the angles are Cg1—Fe1—Cg2 179.15 (3) and Cg3—Fe2—Cg4 179.72 (4)°.

The carboxylic acid moieties are coplanar with the ferrocenyl moieties to which they belong, and the planarity is slightly more pronounced in one molecule than in the other; the dihedral angle between the planes defined by atoms C16—C110 and C116, O3 and O4 is 2.4 (5)°, and the dihedral angle between the planes defined by atoms C26—C210 and C216, O7 and O8 is 4.2 (5)°. The C_ring—C_carboxyl bond distances (C16—C116 and C26—C216) of 1.469 (5) and 1.464 (4) Å, respectively, have significant π character, due to the coupling of the π electrons of the Cp ring and the carboxyl moiety. These bonds are comparable with the analogous value of 1.466 (2) Å in the structure of ferrocene-1,1'-dicarboxylic acid (FDAH; neutron study at 78 K; Takusagawa & Koetzle, 1979), but noticeably longer than the value of 1.407 (15) Å in the structure of ferrocenecarboxylic acid (FCAH; Cotton & Reid, 1985). A later, more precise study of FCAH at low temperature gave a value of 1.462 (2) Å (Reference?), consistent with the calculated value of 1.460 Å for the C_ring—C_carboxyl bond distance (Lin et al., 1998).

The NHCOO⁻ groups are inclined towards the Cp rings by 16.7 (2) and 6.9 (2)°, which is more twisted than the carboxyl groups. This is in accordance with the bulkiness of the ^tBu substituents. π-Delocalization through the NHCOO⁻ groups and Cp rings is indicated by the N1—C111 and N2—C211 bond distances of 1.344 (4) and 1.356 (4) Å, respectively, which are in between values for single and double bonds. The other geometric parameters within the carboxyl and Boc [NHCOOC(CH₃)₃] moieties are normal (Allen et al., 1987).

The two independent molecules in (I) are hydrogen bonded into discrete dimers (Fig. 2). In a similar manner, FCAH (Cotton & Reid, 1985) and FDAH (Takusagawa & Koetzle, 1979) are dimerized in the solid state into units containing O—H···O hydrogen bonds [2.714 (14) Å in FCAH and 2.5997–2.6597 Å for the two independent molecules in FDAH], as is found in most structures of carboxylic acid derivatives (Leiserowitz, 1976). The dimers in (I) are formed by two eight-membered rings. One ring resembles carboxylic acid dimers, with O—H···O intermolecular hydrogen bonds (Table 2) of 2.656 (3) Å for O4···O7 and 2.663 (3) Å for O8···O3. The other ring is formed by N—H···O intermolecular hydrogen bonds between the NHCOO⁻ group and an O atom from the carbamoyl moiety. This N—H···O hydrogen bond is longer, as expected, being 2.827 (3) and 2.854 (3) Å for N1···O6 and N2···O2, respectively. The two eight-membered rings are twisted with respect to each other by 5.9 (6)°.