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High-Dimensional Manganese(II) Compounds with Noncovalent and/or Covalent Bonds Derived from Flexible Ligands: Self-Assembly and Structural Transformation.
| Content Provider | Semantic Scholar |
|---|---|
| Author | Seop, Chang Son, Sang-Kil Lee, Yong Siang Jun, Moo-Jin Do, Youngkyu |
| Copyright Year | 1999 |
| Abstract | A hydrogen- and covalent-bonded 3D array, [Mn(bpe)(H(2)O)(4)](n)()(ClO(4))(2)(n)()(bpe)(4)(n)()(H(2)O)(2)(n)() (2) [bpe = 1,2-bis(4-pyridyl)ethane], a covalent-bonded 3D network, [Mn(bpe)(1.5)(H(2)O)(tp)](n)()(H(2)O)(n)() (3) [tp = terephthalate], and a covalent-bonded 2D sheet, [Mn(bpe)(N(3))(2)](n)() (4), have been synthesized and characterized by spectroscopic data and single-crystal X-ray diffraction studies. Complex 2 contains two types of packing bpe molecules: One type of bpe molecules (=N31-bpe and symmetry-related bpe) run along the chain direction, and the other type of bpe molecules (=N11-bpe and N21-bpe) are slanted to the chain linked by bridging bpe (=N1-bpe). The chain is coupled with hydrogen bonds via N31-bpe, while hydrogen bonds through packing bpe molecules of N11- and N21-bpe sew the chains, leading to a 3D interlocking network structure. The bpe ligands in 3 have an anti conformation for the bridging bpe and a gauche conformation for the capping bpe with a dihedral angle between the two pyridyl rings of 44.5 degrees. The tp ligand acts as a linker of three metal ions through the unidentate and bridging modes, leading to the formation of a 2D layer. The final molecular dimensionality in 3 is determined from adding bpe ligands to the 2D sheet connected by tp ligands, resulting in a covalent-bonded 3D array where the bridging bpe ligands link the tp-bridged layers. The manganese(II) center in 4 consists of four equatorial azido nitrogen atoms and two axial bpe nitrogen atoms. The one-dimensional chains formed by two azido bridging ligands are interconnected by bpe ligands, each of which has two pyridyl rings with a dihedral angle of 67 degrees, leading to a two-dimensional sheet. Variable-temperature magnetic susceptibility data of 2 and 4 have been fitted to the infinite-chain model (H = -J summation operatorS(A)(i)().S(A)(i)()(+1)) derived by Fisher under the molecular field approximation (J '). Obtained exchange parameters are J = -0.083 cm(-)(1), g = 2.0 for 2 and J = -12.5 cm(-)(1), g = 2.0, J ' = 1.3 cm(-)(1) for 4. In the case of 3, the magnetic nature was interpreted by the dimer model (H = -JS(1).S(2)), affording parameters J = -0.96 cm(-)(1), g = 1.99, J ' = -0.005 cm(-)(1). MO calculations on a hypothetical dimeric unit (NH(3))(5)Mn-bpe-Mn(NH(3))(5) are discussed to evaluate the magnetic nature for the bpe-bridged system 4. |
| Starting Page | 5602 |
| Ending Page | 5610 |
| Page Count | 9 |
| File Format | PDF HTM / HTML |
| DOI | 10.1021/ic990611w |
| PubMed reference number | 11671289 |
| Journal | Medline |
| Volume Number | 38 |
| Issue Number | 24 |
| Alternate Webpage(s) | http://koasas.kaist.ac.kr/bitstream/10203/3268/1/ic990611w.pdf |
| Alternate Webpage(s) | https://doi.org/10.1021/ic990611w |
| Journal | Inorganic chemistry |
| Language | English |
| Access Restriction | Open |
| Content Type | Text |
| Resource Type | Article |
