TY - JOUR
T1 - The influence of a piezoelectric field on the dynamic performance of gan-based green light-emitting diodes with an InGaN insertion layer
AU - Shi, Jin Wei
AU - Kuo, F. M.
AU - Huang, H. W.
AU - Sheu, Jinn Kong
AU - Yang, Chih Ciao
AU - Lai, Wei Chih
AU - Lee, Ming Lung
N1 - Funding Information:
Manuscript received January 13, 2011; revised January 29, 2011; accepted January 29, 2011. Date of publication March 21, 2011; date of current version April 27, 2011. This work was supported by the National Science Council of Taiwan under Grants NSC-96-2221-E-008-106-MY3 and 97-2221-E-006-242-MY3. The review of this letter was arranged by Editor C. Jagadish.
PY - 2011/5
Y1 - 2011/5
N2 - In this letter, the mechanism for improvement of the dynamic performance of GaN-based light-emitting diodes with an InGaN insertion layer is investigated using the very fast electricaloptical pump-probe technique. Our measurements indicate that, when the bias current is relatively low (100 A/cm2), the device with the InGaN insertion layer (device A) exhibits a shorter response time than does the control (device B) without such a layer. However, when the bias current density reaches 0.5 kA/cm2, devices A and B exhibit exactly the same response time during operation from room temperature to 200 °C. These results indicate that, under low current density (100 A/cm 2), the piezoelectric (PZ) field inside device A will be stronger, which should result in a lower effective barrier height with a shorter carrier escape time than is the case for device B. On the other hand, under high bias current density, both devices have the same internal response time, which indicates the screening of the PZ field inside due to injected carriers. These dynamic measurement results suggest that the origin of the efficiency droop in our device under low and high bias current densities is carrier leakage and the Auger effect, respectively.
AB - In this letter, the mechanism for improvement of the dynamic performance of GaN-based light-emitting diodes with an InGaN insertion layer is investigated using the very fast electricaloptical pump-probe technique. Our measurements indicate that, when the bias current is relatively low (100 A/cm2), the device with the InGaN insertion layer (device A) exhibits a shorter response time than does the control (device B) without such a layer. However, when the bias current density reaches 0.5 kA/cm2, devices A and B exhibit exactly the same response time during operation from room temperature to 200 °C. These results indicate that, under low current density (100 A/cm 2), the piezoelectric (PZ) field inside device A will be stronger, which should result in a lower effective barrier height with a shorter carrier escape time than is the case for device B. On the other hand, under high bias current density, both devices have the same internal response time, which indicates the screening of the PZ field inside due to injected carriers. These dynamic measurement results suggest that the origin of the efficiency droop in our device under low and high bias current densities is carrier leakage and the Auger effect, respectively.
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U2 - 10.1109/LED.2011.2114321
DO - 10.1109/LED.2011.2114321
M3 - Article
AN - SCOPUS:79955529325
SN - 0741-3106
VL - 32
SP - 656
EP - 658
JO - IEEE Electron Device Letters
JF - IEEE Electron Device Letters
IS - 5
M1 - 5735185
ER -