Highly Reliable, Cost-effective and Temperature-stable

Top-illuminated Avalanche Photodiode (APD) for

100G Inter-Datacenter ER4-Lite Applications

Jack Jia-Sheng Huang

1,2

, H. S. Chang

, Yu-Heng Jan

2,1

, H. S. Chen

, C. J. Ni

, E. Chou

S. K. Lee

and Jin-Wei Shi

Source Photonics, 8521 Fallbrook Avenue, Suite 200, West Hills, CA 91304, U.S.A.

Source Photonics, No.46, Park Avenue 2

Rd., Science-Based Industrial Park, Hsinchu, Taiwan

Department of Electrical Engineering, National Central University, Zhongli, Taiwan

Keywords: Avalanche Photodiode, APD Photodetector, InGaAs/InAlAs APD, Top-Illumination APD, 100Gb/s Ethernet,

100G Datacenter, ER4, IEEE802.3.

Abstract: One of the key enablers for 100G ER4-Lite optical modules is 25G APD photodetector that can be employed

in 30-40km optical links for inter-datacenter applications. In this paper, we demonstrate that a cost-effective

top-illuminated InGaAs/InAlAs APD photodetector can be manufactured to meet stringent IEEE standard of

100G ER4-Lite. The 25G APD shows high bandwidth, high sensitivity with superb temperature stability of

breakdown voltage. The APD photodetector also possesses excellent durability against harsh optical and

electrical overload in both burst and continuous modes. Robust reliability performance based on aging

conditions of 85-175C has also been achieved with an activation energy of 1.18eV.

1 INTRODUCTION

Optical transmission for data center applications is

increasingly popular for future interconnection within

and between the cities (Bilal et al., 2013; Manzano et

al., 2013; Basa, 2016). The Institute of Electrical and

Electronics Engineers (IEEE) has developed various

802.3 standards for the 125m-40km optical links

listed in Table I. Since 2007, the technological

development on 40Gbit/s and 100Gbit/s applications

have further accelerated (Caruso, 2007). Historically,

the data center communications over 10km distance

represented the mainframe. However, ER4

applications have recently gained significant traction

due to its technological advantage in the 30-40km

optical reach.

One of the main challenges for ER4 ethernet is to

maintain undistorted optical signal over a long

transmission distance. One way to achieve the long-

distance transmission is to increase the output power

from the laser emitter. However, there are several

engineering tradeoffs associated with the higher

power design including reliability, design complexity

and processing cost (Connolly, 2002; Rinner et al.,

2003; Huang et al., 2012). In this paper, we

demonstrate an alternative low-cost ER4 solution by

employing high-sensitivity, high-speed top-

illuminated 25G APD photodetector on the receiver

side. Our data shows that it is feasible to attain low-

cost manufacturing of 25G APD with well-rounded

design-in aspects in bandwidth, sensitivity and

reliability. The top-illuminated APD (Huang et al.,

2016; Chen, et al., 2018) can bring advantages of low

cost and simple fabrication compared to the bottom-

illumiation design (Nada et al., 2014; Nada et al.,

2012). In addition, the 25G APD photodetector can

achieve superb durability against harsh electrical and

optical overload stress conditions as well as robust

reliability performance.

Table 1: IEEE 802.3 standards for 40G/100G optical

modules and fiber optics.

40G/100G Ethernet

Transmission

Distance

Optical fiber

SR4

125m

Multi-mode

fiber (MMF)

FR4 (CWDM4)

2km

Single-mode

fiber (SMF)

LR4

10km

SMF

ER4 Lite / ER4

30km / 40km

SMF

Huang, J., Chang, H., Jan, Y-H., Chen, H., Ni, C., Chou, E., Lee, S. and Shi, J-W.

Highly Reliable, Cost-effective and Temperature-stable Top-illuminated Avalanche Photodiode (APD) for 100G Inter-Datacenter ER4-Lite Applications.

DOI: 10.5220/0006510601190124

In Proceedings of the 6th International Conference on Photonics, Optics and Laser Technology (PHOTOPTICS 2018), pages 119-124

ISBN: 978-989-758-286-8

119

2 EXPERIMENTAL

Figures 1 shows the conceptual schematics of the

top-illuminated APD device structure. The epitaxial

layers were grown by molecular beam epitaxy

(MBE). From top to bottom, it is composed of the p

InGaAs contact layer, p

-InP window layer, graded

InGaAs/InAlAs, InGaAs absorption layer, p-doped

InAlAs field control layer (~1x10

-3

), intrinsic

InAlAs multiplication (M-) layer, and N

InAlAs/InP

contact layers. In order to shorten the avalanche delay

time, a thin M-layer (~90 nm) is chosen in our device

structure (Nada et al., 2015; Campbell et al., 2004).

The detail of our epi-layer structure can be referred to

our previous work (Huang et al., 2017; Chen et al.,

2018).

Figure 1: Schematics of top-illuminated mesa-type SACM

APD photodetector structure with coplanar N and P

electrodes.

We adopted the CH

/Ar dry etching technique that

exhibited a slow etching rate for the In

0.52

0.48

material in order to precisely control the depth of

mesa etch. The active diamter of the APD device was

about 20m. After the mesa etch and p- and n-metal

contacts, a thick (~5 m) benzocyclobutene (BCB)

film was used in the passivation process to reduce the

dark current and to minimize the parasitic

capacitance. An anti-reflection (AR) coating at 1.31

m wavelength was deposited on the surface of our

device to enhance its responsivity performance. A

co-planar stripe (CPS) was integrated with our device

for on-wafer high-speed measurement. The layout of

our CPS was suitable for traditional wire bonding

assembly of the top-illuminated APDs, bringing cost

advantage compared to the flip-chip package that was

used in some 25G bottom-illuminated APDs (Nada et

al., 2015; Nada et al., 2014).

3 RESULTS AND DISCUSSION

3.1 Avalanche Breakdown Voltage

Figure 2 shows the typical reverse current-voltage

(IV) curve of the 25G mesa-type SACM APD

photodetector. On the IV curve, there are two

transitions along the reverse voltage that occur at 3V

and 26V, respectively. The first transition at 3V

corresponds to the punch-through voltage (V

) at

which electric field depletes both the InAlAs

multiplication and i-InGaAs absorption layers

(Huang et al., 2017). The second transition represents

the avalanche breakdown voltage (V

) that is

determined by the InAlAs multiplication layer. The

avalanche breakdown voltage taken at 10A is

estimated to be about 26V for this device. The typical

range of avalanche breakdown voltage is 24-26V.

Our design allows excellent avalanche gain while

keeping the tunneling and impact ionization away

from the InGaAs absorption layer. The dark current

refers to the reverse current at 0.9V

is estimated to

be about 13.4nA at 25C.

Figure 2: The reverse IV curve of the 25G APD

photodetector where the first transition is related to the

punch-through (V

) and the second related to the avalanche

breakdown (V

3.2 Bandwidth

Figure 3 shows the bandwidth plot of the APD based

on small-signal modulation response at 25C. We

characterized the bandwidth curve at reverse voltage

of 17V and 21V. At the reverse bias of 17V, the

bandwidth taken by the 3dB roll-off reached 20GHz.

Such bandwidth was adequate for meeting the

requirement for 4x25G ER4 ethernet (Chen, et al.,

2018). The corresponding multiplication factor or

gain at -17V was about 2.2 (M=2.2). As the reverse

bias increased to 21V for high gain operation (M=5),

the 3dB bandwidth was maintained at around 15GHz.

PHOTOPTICS 2018 - 6th International Conference on Photonics, Optics and Laser Technology

120

Figure 3: Bandwidth plot of 25G APD photodetector

measured at 25C with the reverse bias at 17V to BW of

20GHz.

3.3 Sensitivity

Figure 4 shows the bit error rate (BER) of the 25G

APD photodetector as a function of input optical

power. At near-V

operation with gain of 6, the APD

achieved error-free for bit error rate (BER)<10

-12

with the sensitivity of -17dBm. Such sensitivity level

provided good margin for the photoreceiver detection

over the 40km transmission over fiber (Laird et al.,

2003; Alpert, 2015).

Figure 4: BER of 25G APD device showing that the

sensitivity of -17dBm can be achieved for BER of 10

-12

3.4 Temperature Stability

Temperature stability of the APD breakdown voltage

is also an important parameter for ER4 datacenter

applications. When the datacenter is running hot, the

stable temperature stability of the APD would allow

the gain to maintain constant when subject to

temperature fluctuations.

Figure 5: The normalized avalanche breakdown voltage of

25G APD as a function of temperature ranging from 25C

to 145C.

The avalanche breakdown voltage followed a

linear relationship with temperature (Tyagi, 1968), as

shown in Equation (1).

)(1)(/)(

TTTVTV

brbr





(1)

where V

(T)/V

) is the normalized avalanche

breakdown voltage to the reference temperature T

and  is the normalized temperature coefficient.

Figure 5 shows the normalized avalanche breakdown

voltage as a function of temperature based on two

different APD wafers. The normalized temperature

coefficient () showed ultra-low value of about

5.1x10

-4

C

-1

, lower compared to the reported value of

7.2x10

-4

C

-1

(Tan et al., 2010).

3.5 Optical & Electrical Overload

Stress

In order to verify the photodetector’s robustness

against the simultaneous electrical and optical

stresses, the mesa-type APD devices were tested with

overload stress in burst and continuous modes, as

illustrated in Fig. 6. To determine the damage

threshold of overload, the optical stress was ramped

up from -4dBm to +4dBm.

Figure 6: Schematic of electrical and optical overload stress

applied to the APD for both burst and CW modes.

Highly Reliable, Cost-effective and Temperature-stable Top-illuminated Avalanche Photodiode (APD) for 100G Inter-Datacenter ER4-Lite

Applications

121

Table 2: Damage threshold of optical and electrical

overload stresses of APD for burst and CW modes.

Burst mode

CW mode

Damage

threshold

No failure up to

+4dBm.

No failure up to

+1dBm.

In the burst mode, the optical stress of 1% pulsed

duty cycle was applied to the APD for 60 seconds

while the device was electrically stressed at 2V below

. All APD devices survived with no failure after

being subjected to overload stress up to +4dBm, as

shown in Table 2. In the continuous mode, the

damage threshold was around +1dBm, well

exceeding the -6dBm requirement.

3.6 Reliability

To establish long-term reliability performance, the

APD devices were stressed at 85C under a reverse

current of 100A (Telcordia, 2004). Figure 7 shows

the relative change in avalanche breakdown voltage

as a function of aging time. The failure criterion was

defined as 1V change in V

. All APD receivers have

passed reliability test with excellent margin after

5100hr aging.

Figure 7: The relative breakdown voltage change as a

function of aging time based on the stress condition of

85C, 100A.

Due to the small degradation at regular aging

condition of 85C, the APD devices were also

stressed at highly elevated temperature. Figure 8

shows the failure time distributions of the APD from

the aging groups of 165C and 175C. The failure

time at 50% cumulative probability shows the

statistical mean-time-to-failure (MTTF). The MTTF

values for 165C and 175C are 896hrs and 446 hrs,

respectively.

Figure 8: The failure time distributions of APD

photodetectors based on the stress condition of 165C and

175C.

The device failure time (t

) follows the modified

Black’s equation (Black , 1969; Huang, 2005; Huang

et al., 2005) which provides a good empirical

description of device degradation over time as a

function of stress current and temperature as shown

in Equation (2).

)exp(



(2)

In Equation (2), the first term represents the

current acceleration factor where A is a constant, I is

the stress current, and N is the current exponent; the

second term represents the temperature acceleration

where E

is the activation energy, k is the

Boltzmann’s constant, and T is the temperature.

For the sake of activation energy study, Equation

(2) can be rewritten in the form of natural logarithm

as shown in Equation (3) where the third term can

readily determine the activation energy.

ILnNALnMTTFLn

• )()()(

(3)

Figure 9 shows the plot of Ln(MTTF) vs. 1/(kT)

where the slope is equal to Ea. The error bars

indicates the variation between devices. Based on the

experimental aging data of 165C and 175C, the Ea

of APD is estimated to be 1.18eV, in close agreement

with other reported values (Ishimura et al., 2007;

Watanabe et al., 1996).

PHOTOPTICS 2018 - 6th International Conference on Photonics, Optics and Laser Technology

122

Figure 9: The plot of Ln(MTTF) vs. 1/(kT) for the

determination of E

. The E

value was 1.18eV.

Table 3: Projected device lifetimes of mesa-type APD at

50C operating condition based on extrapolation from the

stress condition.

Aging stress

temperature

Failure time at

stress

temperature

Device

operating

lifetime at

50C

165C

896 hours

6912 years

175C

446 hours

6909 years

With the E

establishment, the failure times from

the aging test can be extrapolated to project the device

lifetimes at the operating condition by using Equation

(2). For the 50C operating condition, the device

lifetimes of the 25G APD are estimated to be close to

6900 years shown in Table 3, representing great

reliability margin for the 20-year stringent

requirement per Telcordia.

4 CONCLUSIONS

We have demonstrated low-cost manufacturing of

25G top-illuminated, high-sensitivity SACM APD

photodetector for the 100G ER4 Lite datacenter

applications. The high-speed, high-sensitivity APD

showed favorable V

(24-26V). The 3dB bandwidth

reached 20GHz at reverse bias of 17V, meeting the

requirement of 4x25G ER4 ethernet. The sensitivity

of -17dBm was achieved to enable the detection over

the error-free 40km transmission over fiber at

BER<10

-12

. The APD also showed excellent

temperature stability where the normalized

temperature coefficient () was about 5.1x10

-4

C

-1

superior to the industry benchmark.

The APD photodetector showed superb

durability against simultaneous electrical and optical

overload stress. In the burst mode, the APD showed

no failure up to +4dBm. In the CW mode, the damage

threshold was +1dBm, well exceeding the -6dBm

requirement. We have also achieved robust reliability

for the APD with little degradation after 5100hr aging

at 85C. Based on the aging data of 165C and 175C,

the actiation energy of the APD was determined to be

1.18eV. The projected device lifetime of the APD

was extrapolated to be about 6900 years at the

operating condition of 50C.

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