Your search keyword '"Kin-ya Akiba"' showing total 10 results

1. Synthesis of a Novel Potential Tridentate Anthracene Ligand, 1,8-Bis(dimethylamino)-9-bromoanthracene, and Its Application as Chelate Ligand for Synthesis of the Corresponding Boron and Palladium Compounds

Author

Kin-ya Akiba, Yohsuke Yamamoto, Makoto Yamashita, and Kumiko Kamura

Subjects

Anthracene, Ligand, Stereochemistry, Organic Chemistry, anthracene, chemistry.chemical_element, General Chemistry, Crystal structure, palladium, Medicinal chemistry, Catalysis, chemistry.chemical_compound, N ligands, chemistry, Bromide, Proton NMR, Chelation, Singlet state, boron, Palladium

Abstract

A novel potential tridentate ligand, 1,8-bis(dimethylamino)-9-bromoanthracene, was synthesized. The key steps are as follows: 1) dimethylamination of 1,8-dibromo-9-methoxyanthracene by a modified Buchwald's method to afford 1,8-bis(dimethylamino)-9-methoxyanthracene, and 2) reduction of the methoxy group by LDBB (lithium di-tert-butylbiphenylide) followed by treatment with BrCF2CF2Br. The corresponding 1,8-bis(dimethylamino)-9-lithioanthracene, which should be a useful versatile tridentate ligand, could be generated by treatment of the bromide with one equivalent of nBuLi. The lithioanthracene reacted with B-chloroborane derivatives to give three 9-boryl derivatives. Although we recently reported that the crystal structure of 1,8-dimethoxy-9-B-catecholateborylanthracene was a symmetrical compound with the almost identical two O-B distances (2.379(2) and 2.441(2) A), the newly prepared 1,8-bis(dimethylamino)-9-borylanthracene derivatives clearly have unsymmetrical structures with coordination of only one NMe2 group toward the central boron atom. However, the energy difference between the unsymmetrical and symmeterical structures was found to be very small based on 1H NMR measurements, in which symmetrical anthracene patterns in the aromatic region (two kinds of doublets and a triplet) and a sharp singlet signal of the two NMe2 groups were observed even at -80 degrees C. 1,8-Bis(dimethylamino)-9-bromoanthracene itself can be a versatile ligand for transition metal compounds. In fact, direct palladation of the bromide took place by the reaction with [Pd2(dba)3].CHCl3 in THF to give the 9-palladated product. X-ray crystallographic analysis of the Pd compound showed that the square planar palladium atom was coordinated in a symmetrical fashion by both NMe2 groups (Pd-N bonds are 2.138(5) and 2.146(5) A).

Published

2002

2. Organo Main Group Chemistry

Author

Kin-ya Akiba and Kin-ya Akiba

Subjects

Chemistry, Organic, Organic compounds, Organic compounds--Synthesis, Carbon compounds

Abstract

Forging a new association; main group elements and organic chemistry Covering the essentials of all main group elements in organic chemistry, along with the synthesis and reactions of their organic compounds in just one volume, Organo Main Group Chemistry breaks important new ground. While main group chemistry has traditionally been classified as part of inorganic chemistry, this book establishes the organic chemistry of main group elements for the first time. The organic compounds of elements in the second period of the periodic table, which are centered around carbon, are the major components of animals and plants, while those in the third period and below also play key roles worthy of discussion when studying main group element chemistry. The major chapters describe synthesis and reactivity of organic compounds in the third period and below and are arranged according to the order of the periodic table. Starting with the role of lithium and magnesium cations, the chapters reach fluorine and iodine compounds. The first two chapters summarize the unique and common characteristics of main group elements in relation to carbon. The latter chapters deal with modern topics that address the unique characteristics of organo main group compounds. Suitable for professional researchers, chemistry professors, and advanced students, Organo Main Group Chemistry presents a novel new approach to the way we view both main groups and organic chemistry itself.

Published

2011

3. Experimental Determination of the nN → σ *P-O Interaction Energy of 0-Equatorial C-Apical Phosphoranes Bearing a Primary Amino Group.

Author

Adachi, Takahiro, Matsukawa, Shiro, Nakamoto, Masaaki, Kajiyama, Kazumasa, Kojima, Satoshi, Yamamoto, Yohsuke, Kin-ya Akiba, Re, Suyong, and Nagase, Shigeru

Published

2006

4. A New Method for the Formation of Anti-apicophilic (O-cis) Spirophosphoranes – Kinetic Studies on the Stereomutation of O-cis Arylspirophosphoranes to Their O-trans Isomers.

Author

Kazumasa Kajiyama, Miki Yoshimune, Satoshi Kojima, and Kin-ya Akiba

Published

2006

5. Syntheses and Reactions of Hexavalent Organotellurium Compounds Bearing Five or Six Tellurium—Carbon Bonds.

Author

Masataka Miyasato, Takao Sagami, Mao Minoura, Yohsuke Yamamoto, and Kin-ya Akiba

Published

2004

6. Synthesis of a New Potential Tridentate Anthracene Ligand Bearing Deprotectable Methoxymethoxy (OMOM) Group at 1,8-Positions: Attempt To Synthesize Anionic Hypervalent Carbon Compounds.

Author

Makoto Yamashita, Yukari Mita, Yohsuke Yamamoto, and Kin-ya Akiba

Published

2003

7. The Ligand-Exchange Process of P–Hapical Phosphoranes and the Thermal Formation and Pseudorotation of Anti-Apicophilic Spirophosphoranes.

Author

Satoshi Kojima, Kazumasa Kajiyama, Masaaki Nakamoto, Shiro Matsukawa, and Kin-ya Akiba

Published

2006

8. Synthesis and Structure of a Hexacoordinate Carbon Compound.

Author

Yamaguchi, Torahiko, Yamamoto, Yohsuke, Kinoshita, Daisuke, Kin-Ya Akiba, Yun Zhang, Reed, Christopher A., Hashizume, Daisuke, and Iwasaki, Fujiko

Subjects

*CARBON compounds, *HYPERVALENCE (Theoretical chemistry), *VALENCE (Chemistry), *ORGANIC chemistry, *CHEMISTRY

Abstract

The article discusses the result of a study concerning synthesis and structure of a hexacoordinate carbon compound. The paper reported an example of hexacoordinate carbon with arguable hypervalence and characterized hexacoordinate carbon compounds. It was found that high-coordinate carbon compounds are electric-deficient, having three-center two electron bonds.

Published

2008

9. Cleavage of Tellurium-Carbon Bonds of Hexavalent Organotellurium Compounds by Potassium Graphite This work was supported by a Grant-in-Aid for Scientific Research (No. 11304044 and 12740352) from the Ministry of Education, Science, Sports, and Culture of the Japanese Government. The support of the Nishida Research Fund for Fundamental Organic Chemistry (to M. Minoura) is also acknowledged.

Author

Miyasato M, Minoura M, and Akiba Ky

Published

2001

10. Synthesis and Electrochemistry of Tetraphenylporphyrins Containing an Antimony-Carbon sigma-Bond.

Author

Kadish KM, Autret M, Ou Z, Akiba Ky, Masumoto S, Wada R, and Yamamoto Y

Abstract

The following five antimony(V) tetraphenylporphyrins with sigma-bonded antimony-carbon bonds were synthesized: [(TPP)Sb(CH(3))(2)](+)PF(6)(-), [(TPP)Sb(OCH(3))(OH)](+)PF(6)(-), [(TPP)Sb(CH(3))(OH)](+)ClO(4)(-), [(TPP)Sb(CH(3))(OCH(3))](+)ClO(4)(-), and [(TPP)Sb(CH(3))(F)](+)PF(6)(-). Each compound is stable toward air and moisture and has a high melting point (>250 degrees C). The electrochemistry and spectroelectrochemistry of these sigma-bonded porphyrins were examined in benzonitrile or dichloromethane containing 0.1 M tetrabutylammonium perchlorate as supporting electrolyte and the data compared to those for three previously synthesized OEP derivatives containing similar sigma-bonded and/or anionic axial ligands. Each porphyrin shows two reversible reductions and up to a maximun of one oxidation within the potential window of the solvent. Spectroelectrochemical data indicate formation of a porphyrin pi anion radical upon the first reduction as do ESR spectra of the singly reduced species. However, a small amount of the Sb(III) porphyrin products may be generated via a chemical reaction following electron tranfer. An X-ray crystallographic analysis of [(TPP)Sb(CH(3))(F)](+)PF(6)(-) is also presented: monoclinic, space group C2/c, Z = 8, a = 24.068(5) Å, b = 19.456(4) Å, c = 18.745(3) Å, beta = 94.69(2) degrees, R = 0.056.

Published

1996