de Meijere Armin, Khlebnikov Alexander F, Kozhushkov Sergei I, Yufit Dmitrii S, Chetina Olga V, Howard Judith A K, Kurahashi Takuya, Miyazawa Kazutoshi, Frank Daniel, Schreiner Peter R, Rinderspacher B Christopher, Fujisawa Mari, Yamamoto Chiyo, Okamoto Yoshio
Institut für Organische und Biomolekulare Chemie der Georg-August-Universität Göttingen, Tammannstrasse 2, 37077 Göttingen, Germany.
Chemistry. 2006 Jul 24;12(22):5697-721. doi: 10.1002/chem.200600111.
(P)-(+)-Hexaspiro[2.0.0.0. 0.0.2.1.1.1.1.1]pentadecane [(P)-17] as well as (M)-(-)- and (P)-(+)-octaspiro[2.0.0.0.0.0.0.0.2.1.1.1.1.1.1.1]nonadecanes [(M)- and (P)-25]-enantiomerically pure unbranched [7]- and [9]triangulanes-have been prepared starting from racemic THP-protected (methylenecyclopropyl)methanol 6. The relative configurations of all important intermediates as well as the absolute configurations of the key intermediates were established by X-ray crystal structure analyses. This new convergent approach to enantiomerically pure linear [n]triangulanes for n=7, 9 was also tested in two variants towards [15]triangulane. Some of the most prominent and unexpected features of the newly prepared compounds are the remarkable modes of self-assembly of the diols (P)-14, (E)-(3S,3'S,4S,4'S,5R,5'R)-21, (P)-(+)-22, and (E)-31 in the solid state through frameworks of intermolecular hydrogen bonds leading to, depending on the respective structure, nanotube- [(P)-14, (P)-(+)-22, and (E)-31], honeycomb-like structures [(E)-(3S,3'S,4S,4'S,5R,5'R)-21] or a supramolecular double helix [(P)-(+)- and (M)-(-)-22]. Liquid crystalline properties of the esters and ethers of the diols (P)-14, (P)-, and (M)-22 have also been tested. Although all of these [n]triangulanes have no chromophore which would lead to significant absorptions above 200 nm, they exhibit surprisingly high specific rotations even at 589 nm with alpha(D)=+672.9 (c=0.814 in CHCl(3)) for (P)-(+)-17, +909.9 (c=0.96 in CHCl(3)) for (P)-(+)-25, -890.5 (c=1.01 in CHCl(3)) for (M)-(-)-25, and -1302.5 (c=0.36 in CHCl(3)) for (M)-(-)-39, and the specific rotations increase drastically on going to shorter wavelengths. This outstanding rotatory power is in line with their rather rigid helical arrangement of sigma bonds, and accordingly these helically shaped unbranched [n]triangulanes may be termed "sigma-[n]helicenes", as they represent the sigma-bond analogues of the aromatic pi-[n]helicenes. Density functional theory (DFT) computations at the B3 LYP/6-31+G(d,p) level of theory for the geometry optimization and time-dependent DFT for determining optical rotations with a triplet-zeta basis set (B3 LYP/TZVP) reproduce the optical rotatory dispersions (ORD) very well for the lower members (n=4, 5) of the sigma-[n]helicenes. For the higher ones (n=7, 9, 15) the computed specific rotations turn out increasingly larger than the experimental values. The remarkable increase of the specific rotation with an increasing number of three-membered rings is proportional neither to the molecular weight nor to the number of cyclopropane rings in these sigma-[n]helicenes.
已从外消旋的四氢吡喃(THP)保护的(亚甲基环丙基)甲醇6出发,制备了(P)-(+)-六螺[2.0.0.0.0.0.2.1.1.1.1.1]十五烷[(P)-17]以及(M)-(-)-和(P)-(+)-八螺[2.0.0.0.0.0.0.0.0.2.1.1.1.1.1.1.1]十九烷[(M)-和(P)-25]——对映体纯的无支链[7] - 和[9]三角烷。通过X射线晶体结构分析确定了所有重要中间体的相对构型以及关键中间体的绝对构型。这种用于制备对映体纯的线性[n]三角烷(n = 7, 9)的新的收敛方法也针对[15]三角烷在两种变体中进行了测试。新制备的化合物一些最显著和意想不到的特征是二醇(P)-14、(E)-(3S,3'S,4S,4'S,5R,5'R)-21、(P)-(+)-22和(E)-31在固态下通过分子间氢键框架进行自组装的显著模式,根据各自的结构,形成纳米管[(P)-14、(P)-(+)-22和(E)-31]、蜂窝状结构[(E)-(3S,3'S,4S,4'S,5R,5'R)-21]或超分子双螺旋[(P)-(+)-和(M)-(-)-22]。还测试了二醇(P)-14、(P)-和(M)-22的酯和醚的液晶性质。尽管所有这些[n]三角烷都没有会导致在200 nm以上有显著吸收的发色团,但它们即使在589 nm处也表现出惊人的高比旋光度,对于(P)-(+)-17,[α](20)(D)= +672.9(c = 0.814,在CHCl₃中);对于(P)-(+)-25,+909.9(c = 0.96,在CHCl₃中);对于(M)-(-)-2,5,-890.5(c = 1.01,在CHCl₃中);对于(M)-(-)-39,-1302.5(c = 0.36,在CHCl₃中),并且比旋光度在波长变短时有急剧增加。这种出色的旋光能力与其相当刚性的σ键螺旋排列一致,因此这些螺旋状的无支链[n]三角烷可以被称为“σ-[n]螺旋烯”,因为它们代表了芳香族π-[n]螺旋烯的σ键类似物。在B3 LYP/6 - 31 + G(d,p)理论水平上进行密度泛函理论(DFT)计算以进行几何优化,并使用三重ζ基组(B3 LYP/TZVP)进行含时DFT以确定旋光性,对于σ-[n]螺旋烯的较低成员(n = 4, 5)能够很好地重现旋光色散(ORD)。对于较高成员(n = 7, 9, 15),计算得到的比旋光度结果比实验值越来越大。在这些σ-[n]螺旋烯中,随着三元环数量增加比旋光度的显著增加既与分子量不成比例,也与环丙烷环的数量不成比例。
