A 9-fluorenone bridged and a benzophenone bridged biscalix[4]arene, 20, 21 and their control compound 22, 23 were synthesized through click reaction. Their gelation behavior in twenty one organic solvents were investigated. CGC (critical gelation concentration) tests showed compound 20, 22, and 23 can form gel. However, the compound 21 can not gelate in any solvents. Only the compound 20 can gelate in isopropanol at 0.13 w/w %, such low concentration called ”supergelators”. On the basis of these results, indicating the calix[4]arene and π-π stacking play important role in their self-assembling process. The SEM images showed the aggregates of 20 in isopropanol can form spheres between 10-20 nm in diameter at 10-5 M. As the concentration increase, the spheres gradually become coralloid fiber. In addition, self-assembling process was investigated via nuclear magnetic resonance (NMR) spectroscopy, ultraviolet-visible spectroscopy (UV), fluorescence spectroscopy (PL), infrared spectroscopy (IR), and powder X-ray diffraction technique (PXRD). The gelation results of compound 20 can be rationalized due to the van der Waals interation and H-bonding from calix[4]arene, dipole-dipole interaction from triazole, and π-π stacking form 9-fluorenone. It is known that the 9-fluorenone can be redox, so gel-to-sol transition by adding redox agent was conducted; however, the gelator 20 was suffered irreversible reaction. Furthermore, considering the fact that the weak interaction based self-assembly, evaluating the 17 metal-ion sensing abilities of gel were proceeded. Gel collapsed only after the addition of 1 eq. of Ag+, Fe3+, and Hg2+ perchlorates, while the rest of the metal ions had no effect. It may provide new routes for preparing a metal-ion sensing system. Since the compound 21 had no gelation behavior, a H-abstraction via UV irradiation was utilized to increase the interactions, (e.g., van der Waals, H-bonding). But, the desired results still can not be obtained.