In this thesis, chromogenic and fluorogenic calix[4]arenes bearing lower-rim triazoles as chemosensors for metal cations in polar protic cosolvents were synthesized and studied. Besides, the lower-rim distal triazoles of calix[4]arene as an anionic recognition site and chromogenic group were also explored. In chapter 2, a specific and ratiometric chemosensor for Hg2+ based on triazole coupled ortho-methoxyphenylazocalix[4]arene 4 was synthesized. The complex 4Hg2+ was determined to be 1:1 stoichometry and its association constant was determined to be 1.07(0.32)  104 M-1 in a MeOH/CHCl3 (v/v, 98:2) cosolvent. The functions of azo, hydroxyl, and triazole groups on ligand 4 for sensing Hg2+ were distinguished by the studies of ligands 4 and its derivatives. In chapter 3, a novel fluoroionophore, triazolylpyrene, was developed. Furthermore, a calix[4]arene with lower-rim proximal triazolylpyrenes 18 is a ratiometric fluorescent chemosensor for Ag+ with higher sensitivity compared to that of a calix[4]arene with lower-rim distal triazolylpyrenes 20, and the conventional fluoroionophore with “triazole-CH2-pyrene”. In a MeOH/CHCl3 (v/v, 98:2) cosolvent, the complex 20Ag+ was determined to be 1:1 stoichometry and its association constant was determined to be 1.83(0.33)  104 M-1; however, the complex 18Ag+ was determined to be 1:1 stoichometry and its association constant was determined to be 7.11(0.80)  103 M-1. Even the detection of Ag+ by ligand 18 works in 10% aqueous methanol solution. In chapter 4, calix[4]arenes bearing lower-rim distal p-substituted phenyltriazoles were developed where the electronegativity of triazoles are controlled by its conjugated p-substituted benzene. Especially, a calix[4]arene with lower-rim distal p-nitrophenyltriazoles 30 was explored to be a novel ratiometric and chromogenic chemosensor toward F, CH3COO, H2PO4, and HO in polar solvent as well as in polar protic cosolvents.