| 1 |
An electrochromic device based on all-in-one polymer gel through in-situ thermal polymerization
Kao SY, Kung CW, Chen HW, Hu CW, Ho KC
Solar Energy Materials and Solar Cells, 145, 61, 2016 |
| 2 |
An electrochromic device based on Prussian blue, self-immobilized vinyl benzyl viologen, and ferrocene
Lu HC, Kao SY, Chang TH, Rung CW, Ho KC
Solar Energy Materials and Solar Cells, 147, 75, 2016 |
| 3 |
Electrochromic device with Prussian blue and HPC-based electrolyte
Assis LMN, Sabadini RC, Santos LP, Kanicki J, Lapkowski M, Pawlicka A
Electrochimica Acta, 182, 878, 2015 |
| 4 |
Application of triphenylamine dendritic polymer in a complementary electrochromic device with panchromatic absorption
Kao SY, Lin YS, Hu CW, Leung MK, Ho KC
Solar Energy Materials and Solar Cells, 143, 174, 2015 |
| 5 |
High contrast and low-driving voltage electrochromic device containing triphenylamine dendritic polymer and zinc hexacyanoferrate
Kao SY, Lin YS, Chin K, Hu CW, Leung MK, Ho KC
Solar Energy Materials and Solar Cells, 125, 261, 2014 |
| 6 |
A red-to-gray poly(3-methylthiophene) electrochromic device using a zinc hexacyanoferrate/PEDOT:PSS composite counter electrode
Hong SF, Chen LC
Electrochimica Acta, 55(12), 3966, 2010 |
| 7 |
Electrochromic properties of poly(3-chlorothiophene) film electrodeposited on a nanoporous TiO(2) surface via a room temperature ionic liquid and its application in an electrochromic device
Pang YH, Li XY, Shi GY, Wang F, Jin LT
Thin Solid Films, 516(18), 6512, 2008 |
| 8 |
Switching behavior of the Prussian blue-indium hexacyanoferrate electrochromic device using the K+-doped poly-AMPS electrolyte
Huang YH, Chen LC, Ho KC
Solid State Ionics, 165(1-4), 269, 2003 |
| 9 |
The influences of operating voltage and cell gap on the performance of a solution-phase electrochromic device containing HV and TMPD
Ho KC, Fang YW, Hsu YC, Chen LC
Solid State Ionics, 165(1-4), 279, 2003 |
