Enantioselective magnetochiral photochemistry

Many chemical and physical systems can occur in two forms distinguished solely by being mirror images of each other. This phenomenon, known as chirality, is important in biochemistry, where reactions involving chiral molecules often require the participation of one specific enantiomer (mirror image) of the two possible ones. In fact, terrestrial life utilizes only the L enantiomers of amino acids, a pattern that is known as the ‘homochirality of life’ and which has stimulated long-standing efforts to understand its origin. Reactions can proceed enantioselectively if chiral reactants or catalysts are involved, or if some external chiral influence is present. But because chiral reactants and catalysts themselves require an enantioselective production process, efforts to understand the homochirality of life have focused on external chiral influences. One such external influence is circularly polarized light, which can influence the chirality of photochemical reaction products. Because natural optical activity, which occurs exclusively in media lacking mirror symmetry, and magnetic optical activity, which can occur in all media and is induced by longitudinal magnetic fields, both cause polarization rotation of light, the potential for magnetically induced enantioselectivity in chemical reactions has been investigated, but no convincing demonstrations of such an effect have been found. Here we show experimentally that magnetochiral anisotropy—an effect linking chirality and magnetism—can give rise to an enantiomeric excess in a photochemical reaction driven by unpolarized light in a parallel magnetic field, which suggests that this effect may have played a role in the origin of the homochirality of life.

[1]  Tachibana,et al.  Nonlinear optical spectroscopy on one-dimensional excitons in silicon polymer, polysilane. , 1992, Physical review letters.

[2]  Uchida,et al.  Magnetic susceptibility of ideal spin 1/2 Heisenberg antiferromagnetic chain systems, Sr2CuO3 and SrCuO2. , 1996, Physical review letters.

[3]  L D Barron,et al.  Can a magnetic field induce absolute asymmetric synthesis? , 1994, Science.

[4]  A. Lyne Astrophysics: Origins of the magnetic fields of neutron stars , 1984, Nature.

[5]  Ray H. Baughman,et al.  Optical Nonlinearities in One-Dimensional-Conjugated Polymer Crystals. , 1976 .

[6]  Y. Tokura,et al.  Optical spectra in polydiacetylene crystals substituted with fluorobenzenes , 1986 .

[7]  Tokura,et al.  Singularities in optical spectra of quantum spin chains. , 1996, Physical review letters.

[8]  L. Barron,et al.  Magneto-chiral birefringence and dichroism , 1984 .

[9]  G. Rikken,et al.  Observation of magneto-chiral dichroism , 1997, Nature.

[10]  R. Woody,et al.  [4] Circular dichroism , 1995 .

[11]  G. Rikken,et al.  PURE AND CASCADED MAGNETOCHIRAL ANISOTROPY IN OPTICAL ABSORPTION , 1998 .

[12]  G. Wagnière,et al.  Interferometric detection of magnetochiral birefringence , 1998 .

[13]  M. Leclerc,et al.  Resonant degenerate four wave mixing and scaling laws for saturable absorption in thin films of conjugated polymers and Rhodamine 6G , 1991 .

[14]  S. Macko,et al.  Isotopic evidence for extraterrestrial non- racemic amino acids in the Murchison meteorite , 1997, Nature.

[15]  George I. Stegeman,et al.  All-optical waveguide switching , 1990 .

[16]  B. Seraphin Optical Field Effect in Silicon , 1965 .

[17]  Yoshihisa Inoue,et al.  Asymmetric Photochemical Reactions in Solution , 1992, Organic Molecular Photochemistry.

[18]  D. Bradley,et al.  Spectroscopic investigation of the electro‐optic nonlinearity in poly(2,5‐thienylene vinylene) , 1992 .

[19]  D. Roessler,et al.  Kramers-Kronig analysis of reflection data , 1965 .

[20]  Oka,et al.  Electronic structure of the quasi-one-dimensional halogen-bridged Ni complexes , 1996, Physical review. B, Condensed matter.

[21]  P. Stephens,et al.  Magnetic optical activity of d .fwdarw. d transitions. Octahedral chromium (III), cobalt (III), cobalt (II), nickel (II), and manganese (II) complexes , 1967 .

[22]  J. E. Rowe,et al.  Resonant Nonlinear Optical Susceptibility: Electroreflectance in the Low-Field Limit , 1972 .

[23]  Pedro Cintas,et al.  Absolute Asymmetric Synthesis under Physical Fields: Facts and Fictions. , 1998, Chemical reviews.

[24]  Masatoshi Imada,et al.  Metal-insulator transitions , 1998 .

[25]  S. Mason,et al.  519. Optical rotatory power of co-ordination compounds. Part III. The absolute configurations of trigonal metal complexes , 1965 .

[26]  Menard,et al.  Circular polarization in star- formation regions: implications for biomolecular homochirality , 1998, Science.

[27]  D. Moses,et al.  Conjugated polymers with degenerate ground state. The route to high performance third-order nonlinear optical response , 1992 .

[28]  Phillips,et al.  Electroabsorption of polyacetylene. , 1989, Physical review. B, Condensed matter.

[29]  George I. Stegeman,et al.  Nonlinear materials for information processing and communications , 1996, Philosophical Transactions of the Royal Society of London. Series A: Mathematical, Physical and Engineering Sciences.

[30]  E. Burstein,et al.  Magneto-spatial dispersion effects on the propagation of electro-magnetic radiation in crystals , 1971 .

[31]  N. Baranova,et al.  Electrical analog of the Faraday effect and other new optical effects in liquids , 1977 .

[32]  M. Yamashita,et al.  Nonlinear optical study of quasi‐one‐dimensional platinum complexes: Two‐photon excitonic resonance effect , 1991 .

[33]  N. Baranova,et al.  Theory of a new linear magnetorefractive effect in liquids , 1979 .

[34]  K. Ishikawa,et al.  Analysis of excitonic resonant effect in the third-order nonlinear optical susceptibility of polydiacetylene films , 1991 .

[35]  Laurence D. Barron,et al.  True and false chirality and absolute asymmetric synthesis , 1986 .

[36]  Hermann Rau ASYMMETRIC PHOTOCHEMISTRY IN SOLUTION , 1984 .