RESEARCH REVIEW


ENGINEERS from the Chinese Academy of Sciences have increased the efficiency of green LEDs by almost one-third by adding a shallow quantum well to the active region.


This effort will help the quest to close the difference in efficiency between blue and red LEDs and their green cousins, which are plagued by strong polarization fields and a large lattice mismatch. Ultimately, this will make the use of lighting systems based on all three types of LED more attractive. Several groups have already modified the architecture of the green LED to improve its efficiency.


Shallow wells bolster green LED emission


Modified active region trims electric fields, increases electron-hole overlap and boosts brightness


“For staggered, graded and chirped multi-quantum wells, the emitting-well- layer is divided into two layers or three layers,” explains lead-author Hongjian Li. “However, the strong indium diffusion during the epi-growth of the InGaN active region makes the precise control of indium composition difficult.”


He and his co-workers take a slightly different approach, which involves maintaining the composition in the emitting layer, and inserting before it a shallow quantum well layer with a far lower indium composition. According to Li, it is far easier to carry out the growth of this structure, and that should make it easier to transfer the growth process to mass production.


Inserting a shallow quantum well has additional benefits: It reduces the strength of the polarization fields within the structure, and it increases the crystal quality of the InGaN emitting layer.


Although this approach might appear to deliver similar results to that of a graded multiple quantum well, Li asserts that there is a fundamental difference between the two structures: “Carriers won’t recombine within the shallow well layer due to the low indium composition, but for graded multi-quantum wells,


carriers will recombine within the whole graded well.”


The researchers have investigated the characteristics of their LED architecture with APSYS software produced by Crosslight of Vancouver, Canada. In addition, the team have fabricated and measured the performance of chips based on this design.


N quantum well just 2 nm-thick before the 3 nm-thick InGaN emitting layer, which has an indium composition of up to 30 percent. Results were compared with a more conventional design, with 3 nm-thick InGaN quantum wells.


Ga0.9


Modelling efforts were based on assessing the band structure and carrier distributions of an LED with a shallow In0.10


2-inch, sapphire-based epiwafers grown by MOCVD. Heterostructures featured a 30 nm-thick GaN nucleation layer; a 2 µm-thick GaN layer; a 2 µm-thick, silicon- doped GaN layer; a multi-quantum well region; a 20 nm-thick p-type AlGaN electron-blocking layer; and a 200 nm- thick p-GaN layer. The active region for the novel LED contained 12 periods of 2 nm-thick, shallow In0.10 wells, and 3 nm-thick In0.30


Ga0.90 Ga0.70


N quantum N


emitting layers, sandwiched between 12 nm-thick GaN barriers. A control structure was also formed that had a more conventional active region: 12 periods of 3 nm-thick In0.30


Ga0.70 N emitting layers interlaced with 12 nm-thick GaN barriers.


The team performed photolu minescence measurements at 85 K and 298 K on both structures. The design with a shallow quantum well had a narrower, stronger photoluminescence peak, which is believed to result from superior crystal quality. No emission can be detected from the shallow quantum well. Driven at 150 mA, the device with the shallow quantum well produced 49.3 mW at an emission wavelength of about 525 nm. In comparison, the output from the control sample was 38.4 mW.


Insertion of the shallow quantum wells led to less band-bending in the light- emitting wells, which is claimed to result from alleviation of the electrostatic field within the active region. In addition, the novel design pushed carriers towards the centre of the well and increased electron- hole wavefunction overlap from 18.3 percent to 25.8 percent.


LEDs with dimensions of 256 µm by 300 µm were fabricated by processing


60 www.compoundsemiconductor.net June 2013


The 29 percent increase in output power is attributed to enhanced radiative efficiency that stems from greater electron-hole overlap.


Li says that the team now plans to transfer the technology that they have developed to a high-volume LED manufacturing process. They will also optimise the design of this green-emitting chip.


H. Li et. al. Appl. Phys. Express 6 052102 (2013)


Output power increases by almost 30 percent with the addition of a shallow quantum well


Page 1  |  Page 2  |  Page 3  |  Page 4  |  Page 5  |  Page 6  |  Page 7  |  Page 8  |  Page 9  |  Page 10  |  Page 11  |  Page 12  |  Page 13  |  Page 14  |  Page 15  |  Page 16  |  Page 17  |  Page 18  |  Page 19  |  Page 20  |  Page 21  |  Page 22  |  Page 23  |  Page 24  |  Page 25  |  Page 26  |  Page 27  |  Page 28  |  Page 29  |  Page 30  |  Page 31  |  Page 32  |  Page 33  |  Page 34  |  Page 35  |  Page 36  |  Page 37  |  Page 38  |  Page 39  |  Page 40  |  Page 41  |  Page 42  |  Page 43  |  Page 44  |  Page 45  |  Page 46  |  Page 47  |  Page 48  |  Page 49  |  Page 50  |  Page 51  |  Page 52  |  Page 53  |  Page 54  |  Page 55  |  Page 56  |  Page 57  |  Page 58  |  Page 59  |  Page 60  |  Page 61  |  Page 62  |  Page 63  |  Page 64  |  Page 65  |  Page 66  |  Page 67  |  Page 68  |  Page 69  |  Page 70  |  Page 71  |  Page 72  |  Page 73  |  Page 74  |  Page 75  |  Page 76  |  Page 77  |  Page 78  |  Page 79  |  Page 80  |  Page 81  |  Page 82  |  Page 83  |  Page 84  |  Page 85  |  Page 86  |  Page 87  |  Page 88  |  Page 89  |  Page 90  |  Page 91  |  Page 92  |  Page 93  |  Page 94  |  Page 95  |  Page 96  |  Page 97  |  Page 98  |  Page 99  |  Page 100  |  Page 101  |  Page 102  |  Page 103  |  Page 104  |  Page 105  |  Page 106  |  Page 107  |  Page 108  |  Page 109  |  Page 110  |  Page 111  |  Page 112  |  Page 113  |  Page 114  |  Page 115  |  Page 116  |  Page 117  |  Page 118  |  Page 119  |  Page 120  |  Page 121  |  Page 122  |  Page 123  |  Page 124  |  Page 125  |  Page 126  |  Page 127  |  Page 128  |  Page 129  |  Page 130  |  Page 131  |  Page 132  |  Page 133  |  Page 134  |  Page 135  |  Page 136  |  Page 137  |  Page 138  |  Page 139  |  Page 140  |  Page 141  |  Page 142  |  Page 143  |  Page 144  |  Page 145  |  Page 146  |  Page 147  |  Page 148  |  Page 149  |  Page 150  |  Page 151  |  Page 152  |  Page 153  |  Page 154  |  Page 155  |  Page 156  |  Page 157  |  Page 158  |  Page 159  |  Page 160  |  Page 161  |  Page 162  |  Page 163  |  Page 164  |  Page 165  |  Page 166  |  Page 167  |  Page 168  |  Page 169  |  Page 170  |  Page 171  |  Page 172  |  Page 173  |  Page 174  |  Page 175  |  Page 176  |  Page 177  |  Page 178  |  Page 179  |  Page 180  |  Page 181  |  Page 182  |  Page 183  |  Page 184  |  Page 185  |  Page 186  |  Page 187  |  Page 188  |  Page 189  |  Page 190  |  Page 191