Post on 24-Jul-2015
Efficiency of InGaAs/GaAs Quantum Well Laser Stripes with 30 µm-MesaI. R. Tagaca, J. Fernandez Jr., A. Somintac and A. Salvador
Condensed Matter Physics Laboratory, National Institute of PhysicsUniversity of the Philippines, Diliman, Quezon City 1101
Efficiency of MBE-grown InGaAs/GaAs quantum well (QW) laser stripes fabricated with 30 µm mesa (Figs. 1 to 3) is determined at its lasing wavelength ~ 0.98µm. The lowest threshold current density (Jth) measured is ~ 600A/cm2 (for cavity
length l = 0.4 mm), much better than the last reported (2004) Jth ~
4400 A/cm2 from a similar laser with 75µm mesa.[1] Room-temperature output power vs. injection current (L-I) curves at one laser facet estimate the internal quantum efficiency (ηi = fraction of
injected carriers that stimulate emission of photons) and the internal absorption loss (αi) to be ηi = 83 ± 23 % (with correction
factor (cf)) and αi = 75 ± 24 cm-1 (Fig. 4). The correction factor to
the output power takes into account the undetected light due to elliptically diverging beam of the laser as verified by its far-field distributions.
Figure 3 (a) Emission Spectra at LED (λ = 0.98 µm, I < Ith) and laser (λ = 0.96 µm) operation. LED intensity was magnified several times to
emphasize linewidth collapse (from ~400Å to ~4Å) when the device lases. Shift in λ is due to subsequent device heating.
(b) Pulsed L-I curves (0.01% DC, 1kHz) from laser with l= 0.4 mm. Lasing occurs at the region where the L-I slope steeply rises.
(a) (b)
1/ηe = 253.03(l) + 4.0603
1/ηe = 74.816(l) + 1.2006
0
5
10
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25
30
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-0.02 0.01 0.04 0.07 0.1 0.13 0.16
Cavity length (cm)
Inve
rse
exte
rnal
qua
ntum
eff
icie
ncy
w cf
no cf
Figure 4 From ηe-1 vs. l, home-grown lasers have αi = 75 ± 24 cm-
1, ηi ~ 83 ± 23 % (no cf) and ηi ~ 25 ± 7 % (with cf). ηe is the
fraction of carriers responsible for photons transmitted out of the laser
1.5mm
human hairstrand
1.5mm
human hairstrand
Figure 2 Top view of an array of fabricated 1.5 mm-long lasers. Without polyimide, electrical access is by metal
contacts about the width of white strip.
AcknowledgmentWe would like to thank the DOST-PCASTRD and UP-OVCRD
for their continued support.
Reference[1] G. Manasan, “Fabrication and Characterization of MBE-
grown GaAs-based Lasers”, BS Thesis, University of the Philippines-Diliman, 2003.
GaAs substrate
342 Å GaAs buffer
2 µm Al0.3Ga0.7As cladding layer
0.19 µm GRIN-SCH AlxGa1-xAs; x = [0.3 to 0.2]
369 Å GaAs
80Å In0.2Ga0.8As QW
3 periods of InAs-dots-in-an-InGaAs-well layers with 20Å GaAs spacer layer
369 Å GaAs
0.19 µm GRIN-SCH AlxGa1-xAs; x = [0.2 to 0.3]
100 nm AlAs
2 µm Al0.3Ga0.7As cladding layer
0.2 µm GaAs cap
GaAs substrate
342 Å GaAs buffer
2 µm Al0.3Ga0.7As cladding layer
0.19 µm GRIN-SCH AlxGa1-xAs; x = [0.3 to 0.2]
369 Å GaAs
80Å In0.2Ga0.8As QW
3 periods of InAs-dots-in-an-InGaAs-well layers with 20Å GaAs spacer layer
369 Å GaAs
0.19 µm GRIN-SCH AlxGa1-xAs; x = [0.2 to 0.3]
100 nm AlAs
2 µm Al0.3Ga0.7As cladding layer
0.2 µm GaAs cap
p-doped layers
n-doped layers
Active region
(b)Figure 1 (a) SEM photograph and (b) schematic cross-section of the 30-m mesa InGaAs laser stripe. The low
quantum dot (QD) density (hence, few recombination sites) was inadequate to make the device lase at intended λ ~ 1.1
µm and even contributed to high αi (QDs absorb the higher energy emitted by the QW).
ll
mesa widthtop metal
polyimidep-layer
thin i-layer(active)
n-layer
transverse(z)
lateral(x)
mesa widthtop metal
polyimidep-layer
thin i-layer(active)
n-layer
transverse(z)
lateral(x)
ll
(a)