The goal of this research is to synthesize homopolyfluorene P1 and copolyfluorene P2 containing bromoalkyl side chains, followed by ionic exchange reaction to obtain ionic polyfluorene materials including P1-Br, P1-BF4, P1-PF6, P2-Br, P2-BF4, and P2-PF6, and to study the influence of different anionic groups on thermal, optical, and electrochemical properties. Those materials were used as electron transporting layer to fabricate multilayer polymer light emitting devices. Besides, orange emitting monomer 2,1,3-benzoselenadiazole was introduced to synthesis white light polymer P3, and ionic exchange reaction was carried out to obtain ionic polyfluorene materials P3-Br, P3-BF4, and P3-PF6 for the fabrication of white light electrochemical cells. The thermal stability of Br-containing ionic polyfluorenes was decreased because of Hofmann elimination. By replacing Br with BF4 and PF6 ions, the thermal stability of polymers was raised. UV-visible absorption and photoluminescence spectra show that Br-containing ionic polymers generate blue shift in methanol, and BF4 and PF6 ionic polymers generate blue shift in acetonitrile. This is because higher solubility of polymer was found in the solvent, resulting in longer distance to decrease molecular interaction between polymer chains. Two emission peaks were found for the white light polymer P3 series located at 430 and 560 nm. Electrochemical analysis shows that oxidation potential of BF4 and PF6-containing ionic polymers was significantly decreased, resulting in increase in HOMO and LUMO of materials. Multilayer polymer light emitting devices were fabricated by using ionic polyfluorenes as electron transporting layer in this research. MEH-PPV, HMM, HDM, and HPM were used as emission layer. Experimental results demonstrated that introduction of ionic polyfluorenes indeed enhanced brightness and efficiency of light emitting devices significantly, especially for P1-BF4. Characters of low operation voltage, high brightness and high efficiency were obtained for blue and white light electrochemical cells by using ionic polyfluorenes, without additional add of salts or poly(ethylene oxide). The above experimental results indicate that these ionic polyflourene materials have highly potential application in light-emitting devices.