Department of Chemistry, Northwestern University, 2145 Sheridan Road, Evanston, Illinois 60208, United States.
Department of Chemistry, Haverford College, 370 Lancaster Avenue, Haverford, Pennsylvania 19041, United States.
J Am Chem Soc. 2020 Apr 22;142(16):7555-7566. doi: 10.1021/jacs.0c01239. Epub 2020 Apr 13.
Racemates have recently received attention as nonlinear optical and piezoelectric materials. Here, a machine-learning-assisted composition space approach was applied to synthesize the missing M = Ti, Zr members of the Δ,Λ-[Cu(bpy)(HO)][MF]·3HO (M = Ti, Zr, Hf; bpy = 2,2'-bipyridine) family (space group: 2). In each (CuO, MO)/bpy/HF() (M = Ti, Zr, Hf) system, the polar noncentrosymmetric racemate (M-NCS) forms in competition with a centrosymmetric one-dimensional chain compound (M-CS) based on alternating Cu(bpy)(HO) and MF basic building units (space groups: Ti-CS (), Zr-CS (1̅), Hf-CS (2/)). Machine learning models were trained on reaction parameters to gain unbiased insight into the underlying statistical trends in each composition space. A human-interpretable decision tree shows that phase selection is driven primarily by the bpy:CuO molar ratio for reactions containing Zr or Hf, and predicts that formation of the Ti-NCS compound requires that the amount of HF present be decreased to raise the pH, which we verified experimentally. Predictive leave-one-metal-out (LOO) models further confirm that behavior in the Ti system is distinct from that of the Zr and Hf systems. The chemical origin of this distinction was probed via fluorine K-edge X-ray absorption spectroscopy. Pre-edge features in the F1 X-ray absorption spectra reveal the strong ligand-to-metal π bonding between Ti(3 - ) and F(2) states that distinguishes the TiF anion from the ZrF and HfF anions.
外消旋体最近作为非线性光学和压电材料受到关注。在这里,采用机器学习辅助的组成空间方法合成了缺失的 M = Ti、Zr 成员Δ、Λ-[Cu(bpy)(HO)][MF]·3HO (M = Ti、Zr、Hf;bpy = 2,2'-联吡啶) 家族(空间群:2)。在每个 (CuO、MO)/bpy/HF() (M = Ti、Zr、Hf) 体系中,基于交替的 Cu(bpy)(HO) 和 MF 基本构建单元,竞争形成极性非中心对称外消旋体 (M-NCS) 和中心对称一维链化合物 (M-CS)(空间群:Ti-CS ()、Zr-CS (1̅)、Hf-CS (2/))。基于反应参数训练机器学习模型,以获得对每个组成空间中潜在统计趋势的无偏洞察。一个可由人类解释的决策树表明,相选择主要由含 Zr 或 Hf 的反应中的 bpy:CuO 摩尔比驱动,并预测 Ti-NCS 化合物的形成需要降低 HF 的量以提高 pH 值,我们通过实验验证了这一点。预测性的离开一种金属(LOO)模型进一步证实了 Ti 体系的行为与 Zr 和 Hf 体系的行为明显不同。通过氟 K 边 X 射线吸收光谱探测到这种区别的化学起源。F1 X 射线吸收光谱中的预边缘特征揭示了 Ti(3 - )和 F(2) 态之间强烈的配体到金属 π 键合,这将 TiF 阴离子与 ZrF 和 HfF 阴离子区分开来。
