Incorporation of chirality into transition metal coordination complexes has attracted a lot of interest, because such compounds can be applied for chiral catalysis and chiral sensor as well as chiral magnetism. [1][2][3][4][5][6][7][8] Thus it has been an important subject to design and/or prepare such complexes. As an example, we have synthesized monomeric copper(II) complexes with chiral bidentate ligand R-ppme or S-ppme. 9 The chiral diamine ligands are coordinated to copper(II) ions in bis and tris fashions. The enantiopure copper(II) complexes have clearly been verified by the analyses of crystal structure and chiral properties. In particular, the tris form, [Cu(R/S-ppme) 3 ](ClO 4 ) 2 , is a unique geometry in regard to the Jahn-Teller effect. 10,11 Thus, we tried to make novel coordination complexes using zinc(II) ion and bidentate chiral ligand. Generally, zinc(II) ion is d 10 transition metal and shows various geometric structures from 4-to 6-coordinate. 12,13 As chiral bidentate ligands, N 1benzylcyclohexane-1,2-diamine (bcd, L1) and N 1 -(4-methoxybenzyl)cyclohexane-1,2-diamine (mbcd, L2) have been used for desired coordination complexes. 14,15 By controlling the molar ratio between zinc(II) ion and the chiral ligand and using chloride anion, we have prepared two chiral monomeric zinc(II) complexes with one bcd or mbcd, respectively. They are potentially expected to be displayed interesting chiral catalytic effects. Here we present the preparation, circular dichroism, crystal structure, and photoluminescence properties of [Zn(bcd)Cl 2 ] (1) and [Zn (mbcd)Cl 2 ] (2) including bidentate chiral ligands, N 1benzylcyclohexane-1,2-diamine and N 1 -(4-methoxybenzyl) cyclohexane-1,2-diamine, respectively (Scheme 1).The chiral tetrahedral zinc(II) complexes, [Zn(bcd)Cl 2 ] (1) and [Zn(mbcd)Cl 2 ] (2), were obtained by the reaction of ZnCl 2 and L1 or L2 in ethanol in quantitative yields (94 and 91%). Both compounds are colorless and stable in air as solid. The IR spectra of the complexes show three peaks at 3268, 3245, and 3214 cm −1 in 1 and 3259, 3247, and 3227 cm −1 in 2, respectively, that are assigned to the primary aliphatic amines (Figures S3 and S6). 16 The infrared spectra of [Zn(bcd)Cl 2 ] and [Zn(mbcd)Cl 2 ] exhibit single peaks at 3158 cm −1 in [Zn(bcd)Cl 2 ] and 3145 cm −1 in [Zn(mbcd)Cl 2 ], respectively, that are allocated to the secondary -NH 2 moieties. 16 The infrared spectrum of [Zn(bcd)Cl 2 ] shows ν CH(aromatic) of bcd at 3024 cm −1 and ν CH(aliphatic) of bcd at 2940 and 2862 cm −1 . The infrared spectrum of [Zn (mbcd)Cl 2 ] exhibits ν CH(aromatic) of mbcd at 3040 cm −1 and ν CH(aliphatic) of mbcd at 2934 and 2861 cm −1 .The UV/Vis spectra of [Zn(bcd)Cl 2 ] and [Zn(mbcd)Cl 2 ] show strong absorptions at 259 and 273 nm, respectively, depending on the functional groups ( H, -OMe) ( Figure S7). That is, -OMe is much stronger electron donating group than H. 17 The L2 in 2 is much more stabilized than the L1 in 1, thus the absorption band of 2 displays red-shift to that of 1. Contrary to the so...