1. Introduction

Shockley–Read–Hall (SRH) recombination is a nonradiative process that involves a defect and an electron-hole pair. SRH is one of the most important detrimental processes for optoelectronic devices, having a negative impact on the performance of all semiconductor light emitters, including laser diodes (LDs), light-emitting diodes (LEDs), superluminescent light-emitting diodes (SLEDs), and electroluminescent lamps [1,2]. Therefore, investigations of the basic properties of SRH recombination are of great interest from the fundamental point of view and also for applications. The basic features of the process were described relatively early, independently by Shockley and Read [1] and by Hall [3]. Since then, the primary role of the SRH process in the description of the energy dissipation and emission processes has remained unchanged [4,5,6].

The recent advent of nitride optoelectronic confirmed the important role of SRH recombination. However, the optical properties of these materials present a higher degree of complexity due to the initial high density of defects, alloy inhomogeneity, polarization, complex Auger processes, and strong electron–phonon interactions. Hence, the peculiarities of the SRH process were difficult to assess, and the role of SRH recombination in the overall performance is still under discussion [7,8,9,10]. It is widely recognized that, in InGaN LEDs, carrier localization in In-rich areas prevents migration to dislocation lines, which usually serve as effective nonradiative SRH recombination centers in semiconductors [7,8,9]. Such a positive insulation effect is not observed in AlGaN-based devices, which leads to a lower emission efficiency in comparison to their InGaN-based counterparts [11]. Recent application of Mg–Si codoping opens new avenues toward higher efficiency deep ultraviolet LEDs that may contribute significantly to overcoming important obstacles in the development of these devices [12].

The role of SRH recombination is universally recognized despite its relatively simple model. It is assumed that a deep defect level, i.e., the state located deep in the bandgap, is occupied by the majority carrier. As the energy of the state is much below the conduction band minimum of the crystal host and also much below the Fermi energy level, we can assume that the occupation of the deep localized state is close to complete. In the SRH process, the minority carrier is “captured” by the defect to be recombined. This is the slowest rate-controlling step; therefore, SRH is effectively a mono-molecular process with a recombination rate that is proportional to the density of minority carriers. The net result is the thermalization of the excess energy in the form of lattice vibrations, i.e., phonons that effectively heat the sample. Thus, the effect is doubly detrimental, first by the loss of energy and second by the increase in temperature, which decreases device efficiency and can ultimately lead to the degradation of the device.

The SRH recombination model, devised by Shockley, is based on a classical description of the minority carrier collision with the deep defect occupied by the majority carrier [1,3,4]. The recombination rate is calculated from the average capture rate of the minority carrier by the defect. This collision cross-section depends on the defect type (point or linear). Regardless of the type of defect, a shared feature of both types is that the size of the deep defect falls within the order of a lattice constant a. The cross-section is calibrated to experimental data, sometimes supplemented by the capture probability factor. This description has facilitated a basic modeling of optoelectronic devices, albeit with reduced prediction accuracy.

Due to the nature of SRH recombination, it is assumed that this recombination channel is suppressed in low temperatures. To study the properties of radiative recombination, the standard approach is to study samples in cryogenic temperatures, as it is generally believed that then only the radiative recombination channel would be significant. In this paper, we demonstrate that this is not the case, at least if the majority carrier concentrations are sufficiently low. If this is the case, the charge screening length is high, the Coulomb interaction between charged deep defects and minority charge carriers is high, and the nonradiative recombination rate is significantly increased. The effect is particularly important for the development of luminescent semiconductor devices.

SRH recombination rates can be extracted from time-resolved photoluminescence (TRPL) measurements. However, directly determining the SRH rate from TRPL data is challenging because the effect is entangled with the other processes, including radiative or Auger recombination [13]. Recently, we proposed a new method for the analysis of TRPL data, which allows disentangling mono-, bi-, and tri-molecular contributions to the overall photoluminescence decay [14,15]. However, the obtained results do not support the simple attribution of mono-molecular processes to SRH recombination, bi-molecular to radiative, and tri-molecular to Auger processes [14]. Further investigation of the nature of these processes and their contribution to overall decay is required.

In the present work, we study the carrier capture processes showing that Coulomb attraction can considerably increase the SRH rate. We propose a modification of the standard SRH capture rate to account for the described effect. The proposed modification is implemented in the open-source Python library unipress (Ref. [16]), developed by the authors of this manuscript.

2. Results

Deep defects have their eigenstates localized in a length scale of a few Angstroms. These eigenstates serve as conversion centers from electron-hole pairs to phonons. In the SRH recombination event, the deep center is assumed to be occupied by the majority carrier. Then, the SRH process is reduced to a minority carrier capture that leads to its annihilation with the localized majority carrier. Here, we delve into this capture process.

Following Shockley, we consider first the standard SRH formulation, where it is assumed that minority carriers travel over a length $l$ before being captured by the deep defect, with the following average constant thermal velocity:

(1)$v_{th}=\sqrt{{\displaystyle \frac{kT}{m_{eff}}}}=\sqrt{A}$

• i. For $N_{def}={10}^{17} c{m}^{-3}$,    $l=3.13\times {10}^{-5} m$;

• ii. For $N_{def}={10}^{19} c{m}^{-3}$,    $l=3.13\times {10}^{-7} m$.

The benchmark capture lengths $l$ associated with the dislocations are as follows:

• iii. For $N_{dis}={10}^7 c{m}^{-2}$,    $l=3.13\times {10}^{-2} m$;

• iv. For $N_{dis}={10}^{10} c{m}^{-2}$,    $l=3.13\times {10}^{-5} m$.

For other defect densities, these values scale linearly; thus, it may be easily assessed. It is worth noting that these values are relatively large; they are much bigger than the size of quantum structures such as quantum wells. They are of the order of the typical cavity length of laser diodes. Note also that the lengths are lower for point defects that indicate the dominant role of the latter in SRH recombination.

The combination of the capture length $l$ and the thermal velocity $v_{th}$ provides a standard estimate of the average SRH capture time:

(2)${\tau }_{SRH}\left(T\right)={\displaystyle \frac{l}{v_{th}}}=l\sqrt{{\displaystyle \frac{m_{eff}}{kT}}}$

Note that this velocity is calculated along the path, i.e., a single component in the equipartition principle. Thus, the variation in the SRH rate from low temperature (5 K) to room temperature is ${\tau }_{SRH}\left(5K\right)/{\tau }_{SRH}\left(300K\right) \approx 7.75$, i.e., less than one order of magnitude for the decrease from room temperature to the temperature of liquid helium. This is not a drastic decrease; nevertheless, it is frequently assumed that the SRH rate can be neglected for temperatures close to that of liquid helium [17,18,19,20].

The above comparison of the capture time at a low temperature and room temperature was based on the assumption that carriers travel with a constant thermal velocity in the crystal. However, a considerable fraction of the deep defects is charged by captured majority carriers; thus, the approaching minority carrier is attracted by a Coulomb force. As such, it is accelerated toward the defect. Additionally, the charged defect can be partially screened by the free-carrier gas, which reduces the effect. Free-carrier screening is characterized by the screening length $\lambda$.

As mentioned above, the carrier capture cross-section is relatively small, of the order of the lattice parameter a. Thus, only carriers that move directly toward the defect are captured, and such a process can be modeled using a one-dimensional approximation. In order to estimate the capture time, we use the energy conservation law, according to which the sum of the kinetic and potential energies is conserved:

(3)${\displaystyle \frac{m_{eff}{v}^2}{2}}+e V\left(r\right)=constant$

(4)$v\left(r\right)=\sqrt{{\displaystyle \frac{kT}{m_{eff}}}+{\displaystyle \frac{e^{2}exp\left(-r/\lambda \right)}{2\pi {\epsilon }_o\epsilon r{m}_{eff}}}}$

(5)$v\left(r\right)=\sqrt{ A+B\left[{\displaystyle \frac{exp\left(-r/\lambda \right)}{r}}\right]}$

The parameters in the above equation are as follows: $A={\displaystyle \frac{k_{B}T}{m_{eff}}}=v_{th}^2$ and $B={\displaystyle \frac{e^2}{2\pi \epsilon {\epsilon }_o{m}_{eff}}}$. The latter is material-dependent only and was calculated here for GaN (${\epsilon }_{GaN}=10.28)$ [21,22,23,24]. In the case of the electron capture $\left(m_{eff-GaN}=0.2 m_o=1.80\times {10}^{-31} kg\right)$, $B=2.49\times {10}^2 m^3 s^{-2}$. The relative change in the velocity along the path could be expressed in a function of the scaled distance, $x=r/l_{Coul}$, as follows:

(6a)${\displaystyle \frac{v\left(x\right)}{v_{th}}}=\sqrt{ 1+\left[{\displaystyle \frac{exp\left(-\gamma x\right)}{x}}\right]}$

(6b)$l_{Coul}={\displaystyle \frac{B}{A}}={\displaystyle \frac{e^2 }{k_{B}T 2\pi \epsilon {\epsilon }_o}}$

That is, the distance at which the thermal and Coulomb potential energies are equal. The Coulomb length $l_{Coul}$ is an important control parameter describing the influence of Coulomb attraction on the capture time. It is worth noting that $l_{Coul}$ is temperature dependent.

In order to grasp the value of this length, the GaN values are given as follows:

• (i). For $T=5K$,        $l_{Coul}=3.26\times {10}^{-7}m$;

• (ii). For $T=300K$,    $l_{Coul}=5.42\times {10}^{-9}m$.

The larger value of $l_{Coul}$ denotes the higher influence of the Coulomb force, which is due to the temperature decrease in the thermal energy. Thus, the acceleration is more important at low temperatures. Note also that the Coulomb length is much smaller than the capture length at room temperature. At helium temperatures $\left(T\approx 5 K\right)$ for a high point defect density, the capture and Coulomb lengths are comparable.

We introduce the parameter $\gamma$ as the screening factor that determines the degree of the screening at the Coulomb length. It is equal to the Coulomb length $l_{Coul}$ divided by the screening distance $\lambda$ ratio:

(6c)$\gamma ={\displaystyle \frac{l_{Coul} }{\lambda }}$

The parameter $\gamma$ controls the possible influence of the screening of the Coulomb potential on the capture time:

• i. $\gamma \ll 1$.

The screening factor $\gamma$ is close to zero, i.e., the screening length is much longer than the Coulomb length, i.e., $\lambda \gg l_{Coul}$; therefore, the screening does not affect the attraction potential, and the acceleration is the same as for a pure Coulomb potential.

• ii. $\gamma \gg 1$.

In case the screening factor $\gamma$ is higher than unity, screening is very effective; therefore, the capture time is determined by the thermal velocity alone, i.e., the standard SRH approach could be used. It is worth noting that if the influence of the screening is very strong, it could completely overcome the acceleration by the Coulomb force.

The magnitude of the screening distance can be determined from the Debye screening length estimate [25,26]:

(7)$\lambda =\sqrt{{\displaystyle \frac{{\epsilon }_o\epsilon kT }{2e^{2}n}}}$

• i. $n={10}^{17} c{m}^{-3}$ $\lambda =1.21\times {10}^{-8} m$;

• ii. $n={10}^{19} c{m}^{-3}$ $\lambda =1.21\times {10}^{-9} m$;

• iii. $n={10}^{21} c{m}^{-3}$ $\lambda =1.21\times {10}^{-10} m$.

The first case corresponds to a weakly doped semiconductor, and the second corresponds to a highly excited active zone in light-emitting diodes (LEDs) and laser diodes (LDs) [27,28,29,30,31,32]. Because screening lengths are generally shorter than the previously listed capture and Coulomb lengths; therefore, the case corresponding to $\gamma \gg 1$ is the most frequently encountered.

These two factors have a complex influence on the carrier velocity along the path; therefore, the relative increase in the velocity as a function of the scaled distance for the different types of screened potential is plotted in Figure 1.

The data shown in Figure 1 indicate that the velocity may be accelerated in a drastically different manner. Nevertheless, several general features can be distinguished. First, the noticeable acceleration emerges at distances not larger than several Coulomb lengths. Second, the screening is extremely important; for a screening length that is close to the Coulomb length, the acceleration could be neglected at distances greater than the Coulomb length. Finally, at very close distances, the acceleration may increase the carrier velocity by one order of magnitude.

These data indicate that the acceleration is important, especially relatively close to the charged center and in the absence of effective screening. It is expected, however, that the carrier may travel longer distances. This leads to a reduction in the capture time, which cannot be estimated from the magnitude of the velocity directly. It also has to be assumed that the carrier has a thermal velocity at the beginning of the path, i.e., for $r=l$. Thus, the velocity is changed to the following:

(8)$\tilde{v}\left(r\right)=\sqrt{A+B\left[{\displaystyle \frac{exp\left(-r/\lambda \right)}{ r}}-{\displaystyle \frac{exp\left(-l/\lambda \right)}{ l}}\right]}$

Therefore, the screened Coulomb attraction-dependent capture time ${\tau }_{S-Coul}$ has to be calculated as the time of the arrival of the carrier from the distance l to the recombination center:

(9)${\tau }_{S-Coul}={{\displaystyle \int }}_0^l{\displaystyle \frac{dr}{\tilde{v}\left(r\right)}}={{\displaystyle \int }}_0^l{\displaystyle \frac{dr}{\sqrt{A+B\left[\frac{exp\left(-r/\lambda \right)}{ r}-\frac{exp\left(-l/\lambda \right)}{ l}\right]}}}$

Since $l_{Coul}=B/A$ and $\gamma =l_{Coul}/\lambda$, Expression (9) may be simplified by substituting $y=r/l$, followed by $\vartheta =l/l_{Coul}$. Then, the capture time (9) may be expressed using the SRH capture time, ${\tau }_{SRH}=\vartheta {\displaystyle \frac{B}{A^{3/2}}}$, and the capture length/Coulomb length ratio $\vartheta$ as follows:

(10)${\tau }_{S-Coul}\left(\vartheta \right)={\tau }_{SRH}{{\displaystyle \int }}_0^1{\displaystyle \frac{dy}{\sqrt{1-\frac{exp\left(-\gamma \vartheta \right)}{\vartheta }+\frac{exp\left(-\gamma \vartheta y\right)}{y\vartheta }}}}$

First, we considered the acceleration caused by the influence of the Coulomb potential only ($\gamma =0$) on the capture time, (i.e., without screening—${\tau }_{Coul}$) (10):

(11)${\tau }_{Coul}={\tau }_{SRH}{{\displaystyle \int }}_0^1{\displaystyle \frac{dy}{\sqrt{1+\frac{1}{\vartheta }\left(\frac{1}{y}-1\right)}}}$

This integral could be evaluated analytically. For $y>0$ and constants $a,b>0$, we have $\int {\displaystyle \frac{dy}{\sqrt{a+\frac{b}{y}}}}={\displaystyle \frac{\sqrt{a{y}^2+b}}{a}}-{\displaystyle \frac{b asinh\left(\sqrt{\frac{ay}{b}}\right)}{a\sqrt{a}}}$, and if, additionally, $ay\le b$, then $\int {\displaystyle \frac{dy}{\sqrt{-a+\frac{b}{y}}}}={\displaystyle \frac{y\sqrt{y}}{\sqrt{b-ay}}}-{\displaystyle \frac{b\sqrt{y}}{a\sqrt{b-ay}}}+{\displaystyle \frac{b asin\left(\sqrt{\frac{ay}{b}}\right)}{a\sqrt{a}}}$. If we substitute $a=1-{\displaystyle \frac{1}{\vartheta }}, b={\displaystyle \frac{1}{\vartheta }}$ for $\vartheta >1$ in the first integral and $a={\displaystyle \frac{1}{\vartheta }}-1, b={\displaystyle \frac{1}{\vartheta }}$ for $0<\vartheta <1$ in the second integral, satisfying $ay\le b$ for $0\le y\le 1$, and for $\vartheta =1$ using $\int {\displaystyle \frac{dy}{\sqrt{\frac{1}{y}}}}={\displaystyle \frac{2y\sqrt{y}}{3}}$, and then integrate over $y\in \left[0,1\right]$, Expression (11) gives the following:

(12)$$\begin{gathered} {\tau }_{Coul}\left(\vartheta \right)={\tau }_{SRH}{\displaystyle \frac{\vartheta }{\vartheta -1}}\left[1-{\displaystyle \frac{1}{\sqrt{\vartheta }\sqrt{\vartheta -1}}} asinh\left(\sqrt{\vartheta -1}\right)\right]\hspace{1em}\hspace{1em}\hspace{1em}\vartheta >1 \\ \hspace{1em}\hspace{1em}\hspace{1em}\hspace{1em}\hspace{1em}\hspace{1em}\hspace{1em}\hspace{1em}\hspace{1em}\hspace{1em} {\displaystyle \frac{2}{3}}{\tau }_{SRH}\hspace{1em}\hspace{1em}\hspace{1em}\hspace{1em}\hspace{1em}\hspace{1em}\hspace{1em}\hspace{1em}\hspace{1em}\hspace{1em}\hspace{1em}\hspace{1em}\vartheta =1 \\ \hspace{1em}\hspace{1em}\hspace{1em}\hspace{1em}\hspace{1em}\hspace{1em}\hspace{1em}\hspace{1em}\hspace{1em}\hspace{1em}\hspace{1em}\hspace{1em}{\tau }_{SRH}{\displaystyle \frac{\sqrt{\vartheta }asin\left(\sqrt{1-\vartheta }\right)-\vartheta \sqrt{1-\vartheta } }{{\left(1-\vartheta \right)}^{3/2}}} 0<\vartheta <1 \end{gathered}$$

This dependence could be converted into the following:

(13)$$\begin{gathered} {\tau }_{Coul}\left(\vartheta \right)={\tau }_{SRH}{\displaystyle \frac{\vartheta }{\vartheta -1}}\left[1-{\displaystyle \frac{1}{\sqrt{\vartheta }\sqrt{\vartheta -1}}} ln\left(\sqrt{\vartheta -1}+\sqrt{\vartheta }\right)\right]\hspace{1em}\vartheta >1 \\ \hspace{1em}\hspace{1em}\hspace{1em}\hspace{1em}\hspace{1em}\hspace{1em}\hspace{1em}\hspace{1em}\hspace{1em}\hspace{1em}{\displaystyle \frac{2}{3}}{\tau }_{SRH}\hspace{1em}\hspace{1em}\hspace{1em}\hspace{1em}\hspace{1em}\hspace{1em}\hspace{1em}\hspace{1em}\hspace{1em}\hspace{1em}\hspace{1em}\vartheta =1 \\ {\tau }_{SRH}{\displaystyle \frac{\sqrt{\vartheta }asin\left(\sqrt{1-\vartheta }\right)-\vartheta \sqrt{1-\vartheta } }{{\left(1-\vartheta \right)}^{3/2}}} 0<\vartheta <1 \end{gathered}$$

This result can be approximated as a function of the capture and Coulomb lengths ratio $\vartheta$ for two opposite regimes:

• i. Weak attraction $l \gg l_{Coul}$ $\left(\vartheta \gg 1\right)$

(14a) ${\tau }_{Coul}\cong {\tau }_{SRH}\left\{1-{\displaystyle \frac{ln\left(4\vartheta \right)}{2\vartheta }}\right\}$

This relation recovers the SRH capture time for very weak Coulomb attraction $\left( l_{Coul}/l \to 0\right)$.

• ii. Strong attraction $l_{Coul} \gg l$ $\left(\vartheta \ll 1\right)$

(14b) ${\tau }_{Coul}\cong {\displaystyle \frac{\pi {\tau }_{SRH}}{2}}\sqrt{\vartheta }$

This reflects the reduction in the capture time for strong Coulomb attraction by the charged recombination center.

A more complex picture emerges in the case of the screened Coulomb potential. The screened Coulomb capture time may be expressed as follows:

(15)${\tau }_{S-Coul}={\tau }_{SRH}{{\displaystyle \int }}_0^1{\displaystyle \frac{dy}{\sqrt{1-\frac{exp\left(-\gamma \vartheta \right)}{\vartheta }+\frac{exp\left(-\gamma \vartheta y\right)}{y\vartheta }}}}$

The integral in Equation (15) cannot be evaluated analytically; therefore, numerical integration was employed to obtain the capture time dependence on $\vartheta$ for various values of $\gamma$. The data obtained are plotted in Figure 2.

These results indicate that the Coulomb attraction affects the capture time over large distances. The acceleration leads to a shortening of the time, even for a capture length as high as 10² Coulomb lengths. This is in agreement with the long-range character of electrostatic interactions. Nevertheless, the effect is not large, and the capture time is shortened by 20% for 10 Coulomb lengths. On the other hand, for a close distance, this reduction is more substantial: for a capture length equal to the Coulomb length, the reduction is by one-third. A drastic reduction is observed for very close distances, below $0.5 l_{Coul}$. In contrast to the long-range behavior of the Coulomb force, screening is governed by the exponential law, i.e., it is short-ranged. This is reflected by the screened attraction data.

The wide and effective application of this formulation requires an effective way of calculating the capture time that is comparable to the standard SRH estimate. In order to avoid a somewhat cumbersome integration, an approximate expression was obtained:

(16)${\tau }_{S-Coul}\left(\vartheta \right)\cong {\tau }_{SRH}{\left({\displaystyle \frac{{\vartheta }^{P1}}{{\vartheta }^{P1}+P2}}\right)}^{P3}$

(17)$P1\left(\gamma \right)=0.949+0.049 log\left(\gamma \right)$

(18)$P2\left(\gamma \right)=0.861-0.169 log\left(\gamma \right)$

(19)$P3\left(\gamma \right)=0.475+0.005327 log\left(\gamma \right)+0.001699 {\left[log\left(\gamma \right)\right]}^2$

These expressions were verified to be used in the following range: $\gamma \in \left[0.01, 100.0\right]$. In total, Equations (16) and (17) recover the accelerated time in the range $\vartheta \in \left[0.01, 100\right]$, with a precision of 35 percent.

For the ease of use of the provided expressions, both Approximation (16) and Formula (10), calculated by a numerical quadrature, are integrated into open-source Python library unipress [16].

The dependencies presented in Figure 2 and the data quoted earlier could be used to assess the relative importance of the reduction in the capture time. As is shown, in the pure Coulomb case without screening effects (i.e., $\gamma =0$), the reduction is not limited to the Coulomb length, i.e., to $\vartheta =l/l_{Coul}\approx 1$. For this case, the reduction is of the order of 40% (see Figure 2b). Nevertheless, it extends longer, $\vartheta =l/l_{Coul}\approx 10$, which is still 20%, while in the case of $\vartheta =l/l_{Coul}\approx 100$, it is about 5% (see Figure 2a). On the other hand, for a relatively short capture length, such as $\vartheta =l/l_{Coul}\approx 0.1$, it is one order of magnitude smaller (see Figure 3). Note that, for $T=5 \mathrm{K}$, we obtained $l_{Coul}=3.26\times {10}^{-7} \mathrm{m}$; therefore, such an extreme case can be achieved for high point defect densities, of about $N_{def}\approx {10}^{19} {\mathrm{cm}}^{-3}$. For this defect density, the obtained SRH time is ${\tau }_{SRH} \approx 1.7\times {10}^{-11} \mathrm{s}$. The obtained pure Coulomb time is ${\tau }_{Coul} \approx 2.3\times {10}^{-12} \mathrm{s}$, which is considerably shorter. The screened length of the relatively low free electron density $n={10}^{15}{ \mathrm{cm}}^{-3}$ is $\lambda =10 \mathrm{nm}$, which results in the intermediate time ${\tau }_{S-Coul} \approx 1.4\times {10}^{-12} \mathrm{s}$. Thus, the acceleration effects could be important for low-temperature PL investigations, where SRH recombination should not be neglected. For higher temperatures, i.e., $T=300 \mathrm{K}$, this acceleration-related effect is considerably smaller: ${\tau }_{SRH} \approx 2.0\times {10}^{-12} \mathrm{s}$, ${\tau }_{Coul} \approx 1.5\times {10}^{-12} \mathrm{s}$, and ${\tau }_{S-Coul} \approx 1.8\times {10}^{-12} \mathrm{s}$ for SRH, pure Coulomb, and screened Coulomb, respectively.

These effects should be investigated in more detail, which we plan to do in further studies, including the determination of the SRH recombination rate in the function of the point defect and dislocation densities, using newly developed methods of the analysis of time-resolved photoluminescence (TRPL) signal decay, as described in Ref [14]. The planned research will include the role of the defects in the radiative recombination rates.

3. Summary

It is shown that the electrostatic attraction of the minority carriers by charged deep defects may reduce the carrier capture time, significantly increasing the SRH recombination rate. The effect is related to the rate-limiting step, i.e., the carrier capture in linear nonradiative (i.e., SRH) recombination. The reduction in the capture time is expressed as a function of the two control parameters: the capture length/Coulomb length ratio and the screening length/Coulomb length ratio. The Coulomb length is defined as the length at which the Coulomb energy is equal to the kinetic motion thermal energy, i.e., it is temperature dependent. It was demonstrated recently that, in the typical semiconductor device or semiconductor medium, SRH recombination cannot be neglected at low temperatures [33,34].

Effective screening by mobile carrier density could reduce the acceleration effect, leading to an SRH decrease. This effect may be responsible for the decrease in LED efficiency at high excitations, known as “droop effect”.

The described effect of excited carriers’ acceleration due to the electrostatic attraction of the minority carriers by charged deep defects could enhance SRH recombination rates above the thermally imposed limits, showing the possibility of the nonradiative recombination increase, which was not explained by the standard SRH formulation.

Footnotes

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Enlarge this image.

Figure 1. The relative increase in the velocity of the carriers as a function of the scaled distance x from the charged defect, calculated for several values of the screening fraction [Forumla omitted. See PDF.]. The line (red) for [Forumla omitted. See PDF.] corresponds to the Coulomb potential and is essentially identical to [Forumla omitted. See PDF.].

Enlarge this image.

Figure 2. The relative capture time (capture/SRH time ratio, i.e., [Forumla omitted. See PDF.] ) in a function of the scaled capture length (capture/Coulomb length ratio, i.e., [Forumla omitted. See PDF.]) for various values of the screening factor [Forumla omitted. See PDF.]. [Forumla omitted. See PDF.] corresponds to [Forumla omitted. See PDF.], i.e., pure Coulomb attraction: (a) a wide range of [Forumla omitted. See PDF.] values, (b) a magnified portion of small [Forumla omitted. See PDF.]. The line (red) for [Forumla omitted. See PDF.] corresponds to the Coulomb potential and is essentially identical to [Forumla omitted. See PDF.].

Enlarge this image.

Figure 2. The relative capture time (capture/SRH time ratio, i.e., [Forumla omitted. See PDF.] ) in a function of the scaled capture length (capture/Coulomb length ratio, i.e., [Forumla omitted. See PDF.]) for various values of the screening factor [Forumla omitted. See PDF.]. [Forumla omitted. See PDF.] corresponds to [Forumla omitted. See PDF.], i.e., pure Coulomb attraction: (a) a wide range of [Forumla omitted. See PDF.] values, (b) a magnified portion of small [Forumla omitted. See PDF.]. The line (red) for [Forumla omitted. See PDF.] corresponds to the Coulomb potential and is essentially identical to [Forumla omitted. See PDF.].

Enlarge this image.

Figure 3. The relative capture time ([Forumla omitted. See PDF.]) calculated by Formula (10) by a numerical quadrature and by Approximation (16).

References

1. Shockley, W.; Read, W.T. Statistics of the Recombinations of Holes and Electrons. Phys. Rev.; 1952; 87, pp. 835-842. [DOI: https://dx.doi.org/10.1103/PhysRev.87.835]

2. Cuesta, S.; Harikumar, A.; Monroy, E. Electron beam pumped light emitting devices. J. Phys. D Appl. Phys.; 2022; 55, 273003. [DOI: https://dx.doi.org/10.1088/1361-6463/ac6237]

3. Hall, R.N. Electron-Hole Recombination in Germanium. Phys. Rev.; 1952; 87, 387. [DOI: https://dx.doi.org/10.1103/PhysRev.87.387]

4. Stoneham, M. Non-radiative transitions in semiconductors. Rep. Prog. Phys.; 1981; 44, pp. 1251-1295. [DOI: https://dx.doi.org/10.1088/0034-4885/44/12/001]

5. Sze, S.M.; Ng, K.K. Physics of Semiconductor Devices; 1st ed. John Wiley & Sons: Hoboken, NJ, USA, 2006; pp. 79-124. [DOI: https://dx.doi.org/10.1002/0470068329]

6. Hamaguchi, C. Basic Semiconductor Physics; 2nd ed. Springer: Berlin, Germany, 2010.

7. Chichibu, S.; Azuhata, T.; Sota, T.; Nakamura, S. Spontaneous emission of localized excitons in InGaN single and multi-quantum well structures. Appl. Phys. Lett.; 1996; 69, pp. 4188-4190. [DOI: https://dx.doi.org/10.1063/1.116981]

8. Chichibu, S.F.; Abare, A.C.; Minsky, M.S.; Keller, S.; Fleischer, S.B.; Bowers, J.E.; Hu, E.; Mishra, U.K.; Coldren, L.A.; DenBaars, S.P. et al. Effective band gap inhomogeneity and piezoelectric field in InGaN/GaN multiquantum well struc-tures. Appl. Phys. Lett.; 1998; 73, pp. 2006-2008. [DOI: https://dx.doi.org/10.1063/1.122350]

9. O’Donnell, K.P.; Martin, R.W.; Middleton, P.G. Origin of Luminescence from InGaN Diodes. Phys. Rev. Lett.; 1999; 82, pp. 237-240. [DOI: https://dx.doi.org/10.1103/PhysRevLett.82.237]

10. Murotani, H.; Yamada, Y.; Tabata, T.; Honda, Y.; Yamaguchi, M.; Amano, H. Effects of exciton localization on internal quantum efficiency of InGaN nanowires. J. Appl. Phys.; 2013; 114, 153506. [DOI: https://dx.doi.org/10.1063/1.4825124]

11. Hirayama, H.; Maeda, N.; Fujikawa, S.; Toyoda, S.; Kamata, N. Recent progress and future prospects of AlGaN-based high-efficiency deep-ultraviolet light-emitting diodes. Jpn. J. Appl. Phys.; 2014; 53, 100209. [DOI: https://dx.doi.org/10.7567/JJAP.53.100209]

12. Zhou, S.; Liao, Z.; Su, K.; Zhang, Z.; Quian, Y.; Liu, P.; Du, P.; Jiang, J.; Li, Z.; Qi, S. High-Power AlGaN-Based Ultrathin Tunneling Junction Deep Ultraviolet Light-Emitting-Diodes. Laser Photonics Rev.; 2023; 18, 2300464. [DOI: https://dx.doi.org/10.1002/lpor.202300464]

13. Khanna, V.K. Physical understanding and technological control of carrier lifetimes in semiconductor materials and devices: A critique of conceptual development, state of the art and applications. Prog. Quantum Electron.; 2005; 29, pp. 59-163. [DOI: https://dx.doi.org/10.1016/j.pquantelec.2005.01.002]

14. Strak, P.; Koronski, K.; Sakowski, K.; Sobczak, K.; Borysiuk, J.; Korona, K.P.; Dróżdż, P.A.; Grzanka, E.; Sarzynski, M.; Suchocki, A. et al. Instantaneous decay rate analysis of time resolved photoluminescence (TRPL): Application to nitrides and nitride structures. J. Alloy Compd.; 2020; 823, 153791. [DOI: https://dx.doi.org/10.1016/j.jallcom.2020.153791]

15. Leszczynski, M.; Teisseyre, H.; Suski, T.; Grzegory, I.; Bockowski, M.; Jun, J.; Porowski, S.; Pakula, K.; Baranowski, J.M.; Foxon, C.T. et al. Lattice parameters of gallium nitride. Appl. Phys. Lett.; 1996; 69, pp. 73-75. [DOI: https://dx.doi.org/10.1063/1.118123]

16. Unipress Python Library. Available online: https://github.com/ghkonrad/unipress (accessed on 3 October 2023).

17. Nakamura, S.; Chichibu, S.F. Introduction to Nitride Semiconductor Blue Lasers and Light Emitting Diodes; CRC Press: Boca Raton, FL, USA, 2000.

18. Langer, T.; Jönen, H.; Kruse, A.; Bremers, H.; Rossow, U.; Hangleiter, A. Strain-induced defects as nonradiative recombina-tion centers in green-emitting GaInN/GaN quantum well structures. Appl. Phys. Lett.; 2013; 103, 022108. [DOI: https://dx.doi.org/10.1063/1.4813446]

19. Gačević, Ž.; Das, A.; Teubert, J.; Kotsar, Y.; Kandaswamy, P.K.; Kehagias, T.; Koukoula, T.; Komninou, P.; Monroy, E. Internal quantum efficiency of III-nitride quantum dot superlattices grown by plasma-assisted molecular-beam epitaxy. J. Appl. Phys.; 2011; 109, 103501. [DOI: https://dx.doi.org/10.1063/1.3590151]

20. Watanabe, S.; Yamada, N.; Nagashima, M.; Ueki, Y.; Sasaki, C.; Yamada, Y.; Taguchi, T.; Tadatomo, K.; Okagawa, H.; Kudo, H. Internal quantum efficiency of highly-efficient InxGa1−xN-based near-ultraviolet light-emitting diodes. Appl. Phys. Lett.; 2003; 83, pp. 4906-4908. [DOI: https://dx.doi.org/10.1063/1.1633672]

21. Orton, J.W.; Foxon, C.T. Group III nitride semiconductors for short wavelength light-emitting devices. Rep. Prog. Phys.; 1998; 61, pp. 1-75. [DOI: https://dx.doi.org/10.1088/0034-4885/61/1/001]

22. Martin, G.; Botchkarev, A.; Rockett, A.; Morkoç, H. Valence-band discontinuities of wurtzite GaN, AlN, and InN hetero-junctions measured by X-ray photoemission spectroscopy. Appl. Phys. Lett.; 1996; 68, pp. 2541-2543. [DOI: https://dx.doi.org/10.1063/1.116177]

23. Vurgaftman, I.; Meyer, J.R.; Ram-Mohan, L.R. Band parameters for III–V compound semiconductors and their alloys. J. Appl. Phys.; 2001; 89, pp. 5815-5875. [DOI: https://dx.doi.org/10.1063/1.1368156]

24. Vurgaftman, I.; Meyer, J.R. Band parameters for nitrogen-containing semiconductors. J. Appl. Phys.; 2003; 94, pp. 3675-3696. [DOI: https://dx.doi.org/10.1063/1.1600519]

25. Shockley, W. The Theory of—Junctions in Semiconductors and—Junction Transistors. Bell Syst. Technol. J.; 1949; 28, pp. 435-489. [DOI: https://dx.doi.org/10.1002/j.1538-7305.1949.tb03645.x]

26. Mönch, W. Semiconductor Surfaces and Interfaces; Springer: Berlin/Heidelberg, Germany, 2001; Volume 26.

27. Yoshida, H.; Kuwabara, M.; Yamashita, Y.; Uchiyama, K.; Kan, H. Radiative and nonradiative recombination in an ultra-violet GaN/AlGaN multiple-quantum-well laser diode. Appl. Phys. Lett.; 2010; 96, 211122. [DOI: https://dx.doi.org/10.1063/1.3442918]

28. Meng, X.; Wang, L.; Hao, Z.; Luo, Y.; Sun, C.; Han, Y.; Xiong, B.; Wang, J.; Li, H. Study on efficiency droop in InGaN/GaN light-emitting diodes based on differential carrier lifetime analysis. Appl. Phys. Lett.; 2016; 108, 013501. [DOI: https://dx.doi.org/10.1063/1.4939593]

29. Piprek, J. Efficiency droop in nitride-based light-emitting diodes. Phys. Status Solidi; 2010; 207, pp. 2217-2225. [DOI: https://dx.doi.org/10.1002/pssa.201026149]

30. David, A.; Grundmann, M.J. Droop in InGaN light-emitting diodes: A differential carrier lifetime analysis. Appl. Phys. Lett.; 2010; 96, 103504. [DOI: https://dx.doi.org/10.1063/1.3330870]

31. Dai, Q.; Schubert, M.F.; Kim, M.H.; Kim, J.K.; Schubert, E.F.; Koleske, D.D.; Crawford, M.H.; Lee, S.R.; Fischer, A.J.; Thaler, G. et al. Internal quantum efficiency and nonradiative recombination coefficient of GaInN/GaN multiple quantum wells with different dislocation densities. Appl. Phys. Lett.; 2009; 94, 111109. [DOI: https://dx.doi.org/10.1063/1.3100773]

32. Shen, Y.C.; Mueller, G.O.; Watanabe, S.; Gardner, N.F.; Munkholm, A.; Krames, M.R. Auger recombination in InGaN measured by photoluminescence. Appl. Phys. Lett.; 2007; 91, 141101. [DOI: https://dx.doi.org/10.1063/1.2785135]

33. Henning, P.; Sidikejiang, S.; Horenburg, P.; Bremers, H.; Rossow, U.; Hangleiter, A. Unity quantum efficiency in III-nitride quantum wells at low temperature: Experimental verification by time-resolved photoluminescence. Appl. Phys. Lett.; 2021; 119, 011106. [DOI: https://dx.doi.org/10.1063/5.0055368]

34. Sakowski, K.; Borowik, L.; Rochat, N.; Kempisty, P.; Strak, P.; Majewska, N.; Mahlik, S.; Koroński, K.; Sochacki, T.; Piechota, J. et al. On method of estimating recombination rates by analysis of time-resolved luminescence. J. Lumin.; 2024; 269, 120473. [DOI: https://dx.doi.org/10.1016/j.jlumin.2024.120473]