TY - JOUR
T1 - Improved Performance and Heat Dissipation of Flip-Chip White High-Voltage Light Emitting Diodes
AU - Wu, Ping Chen
AU - Ou, Sin Liang
AU - Horng, Ray-Hua
AU - Wuu, Dong Sing
PY - 2017/3/1
Y1 - 2017/3/1
N2 - Three types of white light emitting diodes (LEDs) were constructed with micro-cells. The first one is the convectional LED series connected with four cells using the wire-bonding process. The other two devices are 4 1 lateral-type and 4 1 flip-chip high-voltage LEDs (HV-LEDs) using the interconnection technique. The convectional LED, lateral-type HV-LED, and flip-chip HV-LED are denoted as C-LED, L-HV-LED, and FC-HV-LED, respectively. Moreover, the white LEDs were formed by combining the blue LED chips and the phosphor-dispensing method. The thermal resistances (at 20 mA) of C-LED, L-HV-LED, and FC-HV-LED were 14.5, 59.2, and 12.2 K/W, respectively. In addition, the surface temperatures (at 20 mA) of these three devices were 30.74-31.82, 65.93-68.95, and 27.01-27.96 °C, respectively. Obviously, the heat dissipation of L-HV-LED was much worse than that of C-LED. However, via the fabrication of the flip-chip structure, the heat dissipation of HV-LED can be enhanced significantly. At an injection current of 100 mA, the luminous efficiencies of C-LED, L-HV-LED, and FC-HV-LED were 80.8, 81.0, and 91.8 lm/W, respectively. Furthermore, at the same forward voltage, a higher current can be driven in the FC-HV-LED, leading to an apparent improvement in the luminous efficiency. According to our calculation, the emission size of HV-LED was only 84% compared with that of C-LED. On the other hand, the fabrication of HV-LED can be performed without the wire-bonding process. This indicates that the FC-HV-LED possesses not only lower production costs but also higher optoelectronic performance than that of the C-LED.
AB - Three types of white light emitting diodes (LEDs) were constructed with micro-cells. The first one is the convectional LED series connected with four cells using the wire-bonding process. The other two devices are 4 1 lateral-type and 4 1 flip-chip high-voltage LEDs (HV-LEDs) using the interconnection technique. The convectional LED, lateral-type HV-LED, and flip-chip HV-LED are denoted as C-LED, L-HV-LED, and FC-HV-LED, respectively. Moreover, the white LEDs were formed by combining the blue LED chips and the phosphor-dispensing method. The thermal resistances (at 20 mA) of C-LED, L-HV-LED, and FC-HV-LED were 14.5, 59.2, and 12.2 K/W, respectively. In addition, the surface temperatures (at 20 mA) of these three devices were 30.74-31.82, 65.93-68.95, and 27.01-27.96 °C, respectively. Obviously, the heat dissipation of L-HV-LED was much worse than that of C-LED. However, via the fabrication of the flip-chip structure, the heat dissipation of HV-LED can be enhanced significantly. At an injection current of 100 mA, the luminous efficiencies of C-LED, L-HV-LED, and FC-HV-LED were 80.8, 81.0, and 91.8 lm/W, respectively. Furthermore, at the same forward voltage, a higher current can be driven in the FC-HV-LED, leading to an apparent improvement in the luminous efficiency. According to our calculation, the emission size of HV-LED was only 84% compared with that of C-LED. On the other hand, the fabrication of HV-LED can be performed without the wire-bonding process. This indicates that the FC-HV-LED possesses not only lower production costs but also higher optoelectronic performance than that of the C-LED.
KW - flip-chip LED
KW - heat dissipation
KW - High-voltage light-emitting diode ( HV-LED )
KW - luminous efficiency
KW - white LED
UR - http://www.scopus.com/inward/record.url?scp=85017663513&partnerID=8YFLogxK
U2 - 10.1109/TDMR.2016.2646362
DO - 10.1109/TDMR.2016.2646362
M3 - Article
AN - SCOPUS:85017663513
SN - 1530-4388
VL - 17
SP - 197
EP - 203
JO - IEEE Transactions on Device and Materials Reliability
JF - IEEE Transactions on Device and Materials Reliability
IS - 1
M1 - 7801912
ER -