Abstract

Avalanche photodiodes (APDs) are key optical receivers due to their performance advantages of high speed, high sensitivity, and low noise. The most critical device parameters of APD include the avalanche breakdown voltage and dark current. In this work, we study the temperature dependence of the breakdown voltage and dark current of the mesa-type APD over a wide temperature range of 20–145°C. We institute an empirical model based on impact ionization processes to account for the experimental data. It is shown that highly stable breakdown characteristics of mesa-type APD can be attained with the optimization of the multiplication layer design. We have achieved excellent stability of avalanche breakdown voltage with a temperature coefficient of 0.017 V/°C. The temperature dependence of dark current is attributed to generation-recombination mechanism. The bandgap energy is estimated to be about 0.71 eV based on the temperature variation of dark current, in good agreement with the value for InGaAs.

1. Introduction

Semiconductor photodiodes are important components for the high-sensitivity, low-noise receivers and detectors deployed in the 2.5, 10, and 25G optical communication systems such as passive optical network (PON) and local area networks (LAN) [1]. Among the photodiode portfolio, APDs are attractive devices due to the significant improvement in photoreceiver sensitivity compared with traditional p-i-n (PIN) photodiodes [2]. By adding the multiplication layer, the avalanche photodiodes combine the detection and amplification properties simultaneously.

Recently, 10G/25G APD has drawn increasing interest in the commercial and military applications due to the high-bandwidth and low-noise performance advantages. In order to achieve the high bandwidth, a mesa structure with coplanar P and N electrodes is typically employed [36]. For APD, there are two critical device parameters for the reverse bias operation. The first parameter is the avalanche breakdown voltage associated with the multiplication layer. The breakdown voltage is typically measured at reverse current of 10 A. The avalanche breakdown has been theoretically formulated to study the impact ionization coefficients of electrons and holes [79]. The second parameter is the dark current that is typically measured at reverse bias below the breakdown voltage. Since these two parameters strongly influence the device performance of the APD, it is important to understand the temperature dependence of these two parameters. A good knowledge of the temperature dependence is critical for the design of robust APD that can maintain stable performance when subject to temperature fluctuations.

In this paper, we study the temperature dependence of breakdown voltage and dark current of the mesa-type APD. We experimentally measure the temperature variations of the breakdown voltage and dark current and compare the data with the modelling results based on depletion and impact ionization processes. We discuss the estimation of the energy bandgap using the dark current from the generation current model.

2. Experimental

Figure 1 shows the schematic of the mesa-type APD structure. The APD devices used in the modelling and experimental studies included the N-mesa at the bottom, the active region in the middle, and the P-mesa at the top [10]. The N-mesa consisting of the N-InP buffer and contact layers was grown on top of semi-insulating (SI) InP substrate. The active region consisted of the InAlAs multiplication, the InAlAs charge control, the graded InGaAs/InAlAs, and the InGaAs absorption layers. The InAlAs multiplication layer was undoped with a thickness of about 160 nm. The InAlAs charge control layer was p-type doped (~1.0–1.1 1018 cm−3). The InGaAs absorption layer was undoped with a thickness of about 1200 nm. The P-mesa consisted of the p-InP window and p-InGaAs contact layers. To achieve the 10G or 25G high speed, the mesa-type APD was formed where both P and N electrodes were on the top surface. The p-contact was made by forming the metal ring immediately outside the antireflective (AR) window. The p-ring was connected to the outside p-pad by the metal bridge. The n-metal contact was connected to the N-mesa. For the passivation, the low-k dielectric material such as polyimide was used to reduce the capacitance.

The DC characteristics including the reverse current versus voltage (IV) test was measured. The IV as a function of temperature was also tested to study the temperature dependence of breakdown voltage and dark current.

3. Results and Discussions

The typical reverse IV of the mesa-type APD is shown in Figure 2. On the IV curve, there are two transitions along the reverse voltage at about 10 V and 32 V, respectively. When the reverse voltage is applied to the device, the InAlAs multiplication layer begins to be depleted first. The first transition at 10 V corresponds to the punch-through voltage at which electric field depletes the InAlAs multiplication and -InGaAs absorption layers [11]. The punch-through voltage related to the absorption layer is denoted as . The second transition represents the avalanche breakdown voltage that is also a critical device parameter for APD. The breakdown is typically determined by the InAlAs multiplication layer. By properly controlling the charge density of the charge control layer, sufficient electric field can be reached to achieve a good avalanche gain while keeping the tunneling and impact ionization away from the InGaAs absorption layer. In this case, the breakdown voltage taken at 10 A is estimated to be 31.7 V. Between the two transitions, the reverse current is of technological importance for optical detection. The dark current is usually referred to the reverse current at 0.9. In this case, the dark current is estimated to be about 12.1 nA at 20°C.

In the following, we study the breakdown voltage and dark current as a function of temperature extensively. We discuss the temperature dependence and compare the experimental data with the modelling results.

3.1. Avalanche Breakdown Voltage

There are two major types of junction breakdown in semiconductor diodes. The first type is associated with the tunneling breakdown where the tunneling mechanism is dominant for the devices with lower breakdown voltage. The tunneling breakdown process exhibits a negative temperature coefficient [12, 13]. The second is the avalanche breakdown that is the dominant mechanism for large breakdown voltage, as illustrated in Figure 3. At very high electric field (~105 to 106 V/cm), some electrons within the diffusion distance near the depletion layer gain enough energy to create the secondary electron-hole pair by raising the electron from the valence band into the conduction band. This excitation process creates an electron-hole pair due to impact ionization. The electrons and holes created by the impact ionization are accelerated by the high electric field. Consequently, the secondary electron-hole pair can create even more carriers, leading to a snowball avalanche effect. The avalanche breakdown process typically shows a positive temperature coefficient.

Figure 4 shows the reverse IV as a function of temperature for the mesa-type APD. For APD, the breakdown is due to the avalanche mechanism since the device is operating at high electric field. The increase in ambient temperature is expected to cause the increase in breakdown voltage due to the effect of phonon [14]. As the temperature increases, the population of phonons increases. Thus, a higher electric field and applied voltage are required to reach breakdown in order to overcome the increased carrier cooling caused by phonon scattering [15].

The positive temperature coefficient of the APD has been experimentally found and theoretically described by Tyagi where the breakdown voltage of the Si APD followed a linear expression with temperature [16]. In the modelling of this study, it was assumed that the avalanche breakdown voltage increased linearly with increasing temperature as follows: where is the avalanche breakdown voltage at temperature , is the avalanche breakdown voltage at reference temperature , and is the normalized temperature coefficient. For the sake of comparison, (1) can be rewritten as follows where the second term shows the temperature coefficient of the breakdown voltage:

Figure 5 shows the avalanche breakdown voltage as a function of temperature based on two APD wafers with similar structures but from different processing runs. There were several interesting features worth mentioning. First, the two wafers showed similar breakdown voltage. The intercepts at the reference temperature ( = 20°C) for wafers A and B were 32.8 and 31.7 V, respectively. The similarity between the wafers from two different processing runs suggested that the breakdown voltage was largely determined by the epitaxial structure. Secondly, both wafers showed the same temperature coefficient of breakdown voltage where taken from the slope in Figure 5 was equal to 0.017 V/°C. Third, the normalized temperature coefficient was determined to be 5.1 10−4 and 5.5 10−4°C−1, as shown in Table 1. The measured value of the normalized temperature coefficient in the mesa-type APD was excellent, lower compared to the reported value of 7.2 10−4°C−1 [17]. The weak temperature dependence of our mesa-type InGaAs/InAlAs APD brought performance advantage to maintain the gain when the device was subject to temperature fluctuations. We attributed the superior temperature dependence of the avalanche breakdown voltage to the optimized design of the InAlAs multiplication layer thickness and InAlAs charge control layer doping.

3.2. Dark Current

Another important device parameter of APD is the dark current [18, 19]. As shown in Figure 4, the dark current typically referred to the reverse current below the breakdown voltage. For different temperature ranging from 20°C to 145°C, the dark current is taken from the reverse voltage of where increases with the temperature. Figure 6 illustrates the transport of electrons and holes in the energy diagram at the reverse voltage below the avalanche breakdown and above the punch-through voltage (). In this regime, both -InGaAs absorption and InAlAs multiplication layers are depleted, but the avalanche breakdown in the multiplication layer is not activated.

It has been found that the dark current increases with increasing temperature due to the influence of bandgap energy [20]. We note that the generation-recombination component of the dark current has a temperature dependence. Therefore, the bandgap could be estimated based on the temperature dependence of the dark current. The generation current can be expressed in (3) where is the area of the p-n junction, is the width of the depletion region, is the carrier charge, is the carrier capture cross section, is the carrier thermal velocity, is the trap density, and is the intrinsic carrier concentration.

The intrinsic carrier concentration can be expanded in (4) where is the effective density of state in the conduction band, is the effective density of state in the valence band and is the energy bandgap, is Boltzmann’s constant, and is the temperature. The energy bandgap, , shows a temperature dependence where the bandgap value decreases with increasing temperature [21].

Based on (4), we attempted to extract the energy bandgap from the plot of dark current versus temperature. Taking the natural logarithm of (4), the temperature dependence of the dark current can be expressed in (5). The slope of the versus plot shown in Figure 7 was equal to –. The energy bandgap was estimated to be about 0.71 eV, close to that for the InGaAs. It was noted that the bandgap energy of In0.53Ga0.47As was reported to be 0.75 eV at 295 K [22, 23]. The slight difference between our value and others was likely attributable to the variance from junction temperature and test measurement.

4. Conclusion

We have extensively studied the temperature dependence of mesa-type APD. In the avalanche breakdown regime (), our APD device showed excellent temperature stability in breakdown. The breakdown voltage showed very small increase with increasing temperature. The temperature coefficient of the breakdown voltage was found to be 0.017 V/°C, corresponding to a normalized temperature coefficient of 5.1 10−4°C−1. We attributed the superior temperature dependence of the avalanche breakdown voltage to the optimized design of the InAlAs multiplication layer thickness and InAlAs charge control layer doping. For the voltage below the breakdown (), the dark current increased exponentially with increasing temperature. From the plot of versus , the energy bandgap extracted from the slope was estimated to be about 0.71 eV, in good agreement with the bandgap of InGaAs (~0.75 eV).

Competing Interests

The authors declare that there is no conflict of interests regarding the publication of this paper.

Acknowledgments

The authors would like to thank Professor J.-W. Shi from National Central University (Zhongli, Taiwan) for helpful discussions.