Introduction

Thermoelectric energy harvesting has the reverse effect as opposed to the thermoelectric refrigerator1,2, and has been studied extensively in recent decades3,4,5,6. Right from the invention of the Seebeck and Peltier effects up to now, people have been using doped semiconductor materials with the aim of increasing the electrical conductivity and reducing thermal conductivity for a higher figure of merit. Figure 1a,b show conventional two-terminal Seebeck thermoelectric energy harvester in its normal and unfolded geometries, respectively. The configuration in Fig. 1b is very similar to p-n junction for solar cells. However, the metallic contacts in the middle remove the junction barrier and enables elastic thermoelectric transport. Although Fig. 1b reveals the similarity and difference between a thermoelectric engine and a solar cell, the mechanism that accounts for the significant difference of the two devices in efficiency (i.e., solar cells have much higher efficiency compared with thermoelectric engines) has not been uncovered. It was found only recently that a p-n junction thermoelectric engine based on hot-phonon-assisted interband transition can have considerably augmented thermoelectric efficiency and output power compared to conventional two-terminal thermoelectric devices with the same material. The intrinsic mechanism that distinguishes thermoelectric engines and solar cells in their efficiency and output power is then revealed as akin to inelastic transport processes in a three-terminal geometry7,8 (Fig. 1c).

Figure 1
figure 1

(a) Schematic of the conventional thermoelectric energy harvester that converts heat to electricity. (b) Unfolded geometry of the thermoelectric energy harvester. (c) Working principle of a solar cell, a three-terminal device akin to inelastic (i.e., photon absorbing) processes. (d) Schematic of staircase quantum-dots thermoelectric harvester. Heat from hot phonon bath is exploited to generate electricity via phonon-assisted electron hopping in a chain of quantum-dots with staircase energy configuration. The energy diagram for this device is illustrated as well. Each energy step is dE. For a chain of N quantum-dots the total energy difference is ΔE = (N − 1)dE.

Other prototypes of three-terminal inelastic thermoelectric devices include Coulomb coupled quantum-dots (QDs)9,10, phonon-assisted hopping in QD chains (or localized states in 1D or 2D systems)11,12,13,14,15, and inelastic thermoelectric transport across an electronic cavity promoted by mismatched resonant tunneling at the two-sides of the cavity16,17,18,19. In those devices thermal energy from the third, insulating terminal of phonon or electronic bath is converted to electrical energy between the source and the drain (and vice versa). It was found that to optimize the performance (efficiency and output power) the energy of the two QDs has to be above and below the chemical potential around 3kBT, respectively. Experimental developments on three-terminal inelastic thermoelectric devices in mesoscopic systems at low-temperature were established recently20,21,22, attracting more and more researches in the field8.

In this work we focus on phonon-assisted hopping thermoelectric transport in a three-terminal thermoelectric energy harvester. Our main concern is to optimize the output power of such a device by tuning the energy configuration of a chain of QDs embedded in a nanowire. Such a scheme can be used to form a macroscopic thermoelectric device, since many parallel nanowires can be assembled together and the nanoscale thermoelectric engines can be connected in series. We compare the power factor (density) P = σS2 for these configurations consisting of many serially connected nano- thermoelectric engines along the x direction (while in y-z directions there are many parallel nanowires, see Fig. 2). Specifically, we focus on two configurations: (1) in each nano-engine there is only a single pair of QDs; (2) in each nano-engine there are a chain of N QDs with staircase configuration of energy (see Fig. 1d). We emphasize that the density of QDs along x direction is the same for all these situations and the only difference here is the energy configuration. We show that the power factor is largest for staircase energy configuration (the main focus of this paper). Particularly we study the dependence of power factor on the number N and the energy-step dE for each hopping. We find that for a given dE there is an optimal number N that maximizes the power factor. Our findings reveal important information for future design of inelastic thermoelectric devices.

Figure 2
figure 2

Schematic diagram of the thermoelectric energy harvester based on series of quantum dots embedded in parallel nanowires.

Three-Terminal Thermoelectric Transport for Nanowire Quantum-Dots

The three-terminal thermoelectric energy harvesting device reported here is composed of two electrodes on the left and right sides under room-temperature environment, and a central region comprising QDs heated by the external phonon bath (Fig. 1d). By absorbing the phonon energy electrons hop from one QD to another which leads to electrical current against the voltage gradient. These are the processes that convert thermal energy from phonon bath to electrical energy7. For realistic devices operating at room-temperature and above, electron hopping is efficiently assisted by scattering with optical phonons. Optical phonon scattering transfer a considerable amount of energy, ranging from 10 meV to 120 meV for various materials23. In addition, electron-optical-phonon scattering time can be as short as 0.1 ps, leading to collision broadening as large as 10 meV24. These features make optical-phonon-assisted hopping thermoelectric transport as promising mechanism for powerful and efficient thermoelectric energy conversion.

We shall consider many serially connected nano- thermoelectric engines along the x direction, while in y-z directions there are many parallel nanowires, as shown in Fig. 2. Specifically, each QD is of length lqd = 6 nm along x direction. The distance between adjacent QDs is d = 6 nm. The probability of finding an electron outside the QD decays exponentially with the distance away from it with a characteristic length ξ = 2 nm. A simplified treatment based on Fermi golden rule yields the following hopping transition rate from QD i to QD j,

where the factor of two comes from spin-degeneracy, αep = 10 meV characterizes the strength of electron-phonon scattering, fi and fj are the probability of finding electron on QDs i and j, respectively. The x coordinates of the two QDs are xi and xj, respectively, while their energies are Ei and Ej, respectively. Here the phonon distribution function is given by

In our thermoelectric energy harvester, the phonon bath has temperature higher than the electrodes, i.e., Tp > T. The heat from the phonon bath is then converted into electricity. The electron distribution in each QD can be described by a Fermi distribution

From the above, the electric current flowing from QD i to QD j is given by

with e being the charge of a single electron. The linear conductance of electric conduction between QDs i and j is given by

where is the transition rate at equilibrium and the superscripts 0 denote equilibrium distributions. Hence each pair of QDs form a resistor with conductance Gij. Hopping conduction is mapped to conduction in network of resistance (i.e., the Miller-Abrahams network25). Such method is generalized to three-terminal hopping conduction in refs 11,12. Thermoelectric transport through the system is calculated by solving the Kirchhoff current equation, i.e., the total current flowing into QD i is equal to the total current flowing out of QD j for the Miller-Abrahams network12. In this fashion the electrochemical potentials at each QD. i.e., μI’s, are determined numerically via the method presented in ref. 12.

We shall consider a chain of N QDs with staircase energy configuration. Each energy step is dE = Ei+1 − Ei (we focus on the situation with dE > 0). The total energy difference is ΔE = (N − 1)dE. The first QD has energy E1 = −ΔE/2, while the last QD has energy EN = ΔE/2. Here the energy we referred to is the energy of the lowest two degenerate electronic levels (i.e., spin-up and spin-down) of the QD. Higher levels in the QDs are ignored due to their much higher energies as we consider small QDs here. N = 2 is the case with a single pair of QDs in a nano-thermoelectric engine. The energy configuration is chosen to have particle-hole symmetry, which has been proven to be best for thermoelectric performance as shown in refs 16,18.

It is noted that differing from variable range hopping between randomly localized states in nanowires or higher dimensional systems, the staircase energy configuration always favours the nearest neighbour hopping. This is because hopping to farther neighbour QDs costs larger energy gap and longer distance simultaneously. In contrast, in variable range hopping, the nearby neighbours may have larger energy differences compared to farther localized states. Optimization of the hopping distance in 1D localized system leads to the Mott’s law26 in non-interacting electron systems (with slight modifications27).

It is necessary to mention that the Fermi golden rule requests that the energy difference dE between the two electronic states must be the same as the optical phonon energy (i.e., microscopic energy conservation). We are interested only in the range with dE (10, 120) meV, which can be realized in III-V, II-VI, VI semiconductors. Considering the electron-optical-phonon scattering rate for most of those semiconductors are around 0.1 ps. Our model calculation hence captures the main physics of the system. We mention that acoustic-phonon scattering near the Debye frequency is also very efficient. In our calculation, modifying dE may need to be fulfilled by changing the materials for nanowire-QDs. Nevertheless, our study reveals for a given dE (i.e., a given material) the number of QDs in a single nanowire that optimizes the power factor, as well as how such an optimal number varies with dE. These information are useful for future material design of nanowire-QD thermoelectric devices.

Beside the inelastic hopping conduction, there is also elastic transport through the system. The elastic transport defines pure electron quantum tunneling mechanism between QDs and electrodes. A resonant tunneling mechanism is exploited to describe such conduction process. Note that since we consider QDs with considerably large energy differences (much larger than coupling between quantum dots) sequential tunneling between QDs is suppressed. The dominant contribution comes from single QD resonant tunneling12, where each QD forms one of such resonant tunneling conduction channel independently. Hence the elastic conduction contributes to the electric current via

Here V is the voltage across the source and drain electrodes, h is the Planck constant, Gel denotes the elastic conductance, f0(ε) = 1/[exp(ε/(kBT)) + 1] (we set the electrochemical potential at equilibrium as energy zero). The tunnel coupling between the QD i and the left (right) electrode is γLi (γRi). We shall set the coordinate of the left electrode as x = 0, while the right electrode has x = Ltot with Ltot = Nlqd + (N − 1)d + 2lb where lb is the distance between the first (last) QD and the left (right) electrode. The tunnel coupling is hence γLi = t0 exp(−xi/ξ) and γRi = t0 exp(−(Ltot − xi − lqd)/ξ) with t0 = 100 meV that characterizes hybridization energy of closely coupled QDs. We emphasize that the elastic current Ielas does not vary with the temperature of the phonon bath Tp since it originates purely from the quantum tunneling instead of coupling with phonons. In fact, in our thermoelectric engine, elastic conduction dissipates the electric energy generated by inelastic hopping into Joule heating.

Thermoelectric transport in our system the linear-response regime can be described by the coupled electric and heat conduction equation

where G = Gin + Gel with Gin being the inelastic conductance. It was shown in ref. 12 that where is the average energy of electrons entering into the right (left) electrode. For instance, hopping thermoelectric transport in a single pair of QDs gives L = Gin (E2 − E1)/e. Hopping for a chain of N QDs with staircase energy configuration yields L = Gin (EN − E1)/e. We emphasize that elastic tunneling does not contribute to the Seebeck effect here, which is the essential difference between three-terminal and conventional thermoelectric effects. The Seebeck coefficient for the phonon-driven three-terminal thermoelectric effect is then

For our system to work as an thermoelectric energy harvester, the inelastic conduction should dominate over the elastic conduction. The inelastic, elastic and total conductivity are plotted in Fig. 3(a) for a nano thermoelectric harvester with a single pair of QDs as functions of energy step dE for dE (10, 120) meV. Both the inelastic and elastic conductivity decreases with increasing dE. The elastic conductivity is reduced as the first QD has lower energy below the electrochemical potential while the second QD is higher above the electrochemical potential, leading to less effective conduction. The inelastic conductivity is also reduced due to the larger thermal activation energy dE and exponentially decreased phonon number . Therefore at very large energy difference dE the elastic conductivity may be more important. In reality, the elastic conduction also dominates in the small dE regime, which we ignored in this study. For a chain of QDs with N = 10, the results in Fig. 3(b) shows that the elastic conduction is much reduced, since tunneling over a longer distance is exponentially suppressed. The conductivity is then dominated by inelastic hopping in long chains of QDs.

Figure 3
figure 3

(a,b) Inelastic, elastic, and total conductivity as functions of dE for (a) a single pair of QDs and (b) a chain of N = 10 QDs with staircase energy configuration. The range of dE is between 10 and 120 meV. kBT = 30 meV. (c,d) Inelastic, elastic, and total conductivity as functions of the number of QDs in a single nano-device with staircase energy configuration for (c) dE = 10 meV and (d) dE = 30 meV.

Next we examine the conductivity as a function of the length of the chain. We show the results in Fig. 3(c,d) for dE = 10 meV and 30 meV, respectively. As the number of QDs increases both the inelastic hopping conductivity and elastic tunneling conductivity decreases. However, the elastic conductivity decreases much rapidly. The initial decay of hopping conductivity is sub-exponential, since increase the number of hopping is similar to increase the number of resistors. However, for large N, as the energy of the first (last) few QDs is much lower (higher) than the electrochemical potential, the hopping rates are suppressed by the exponentially small availability (occupation) of the final (initial) state. The decrease of conductivity at large N is hence exponential. Such exponential decrease become stronger for larger dE = 30 meV as shown in Fig. 3(d).

Power Factor for Different Energy Configurations

We then study the power factor P = σS2 for various energy step dE and length of the QDs chain N. We remark again that for all situations the density of QDs is the same, according to our geometry of the nanowire QDs. The conductivity is calculated via σ = Gl/A where l and A are the length and area of a single nano thermoelectric engine. Here the area is determined by the density of nanowires as A−1 = 1015 m−228,29. By focusing on the scale independent conductivity σ and power factor σS2 we are able to discuss ways of optimizing the power factor by engineering each nano thermoelectric element. In this way, the variation of the power factor σS2 is a sole consequence of the energy configuration (rather than geometry) in each nano thermoelectric engine.

In Fig. 4(a) we show the dependences of power factor σS2 and the Seebeck coefficient S on the energy step dE for a nano device with a single pair of QDs. It is found that the Seebeck coefficient S increases monotonically with the energy step dE, which is consistent with Eq. (10). As a consequence of competition between the conductivity and the Seebeck coefficient, the power factor is optimized around dE = 3kBT. For a chain of N = 10 QDs, the power factor is maximized at a much lower dE, as shown in Fig. 4(b). This is due to the more rapid decay of the conductivity as shown in Fig. 3(b).

Figure 4
figure 4

(a,b) Power factor P = σS2 and Seebeck coefficient S as functions of energy step dE for (a) a single pair of QDs and (b) a chain of N = 10 QDs with staircase energy configuration. (c,d): Power factor P = σS2 and Seebeck coefficient S as functions of the number of QDs in a single nano-device with staircase energy configuration for (c) dE = 10 meV and (d) dE = 30 meV. kBT = 30 meV.

Similarly, the dependence of the number of QDs N for a given energy difference dE also has a peak, as shown in Fig. 4(c,d). In Fig. 4(c) we plot the power factor σS2 and the conductivity σ as functions of the number of QDs N in a single nano device for dE = 10 meV. The power factor is maximized at N = 21. This maximum also appears as a consequence of the competition of the conductivity and the Seebeck coefficient when the number N is increased. The Seebeck coefficient increases as the total energy difference ΔE = (N − 1)dE increases, while the conductivity decays exponentially with the number of QDs for large N. Since such exponential decay of conductivity is more severe for larger energy step dE, the maximum appears at a smaller number of QDs N for dE = 30 meV, as shown in Fig. 4(d).

To have a global view of the dependence of the power factor on the energy configuration of QDs, we plot the σS2 for various N and dE in Fig. 5. It is seen that for each dE there is an optimized N at which the power factor is maximized. For smaller dE the optimal N is larger. More importantly, the maximal power factor is greater. Our study thus reveal the optimal energy configurations for powerful three-terminal thermoelectric energy harvester. In reality, it is important to find the energy dE that optimize the phonon-assisted hopping rate and the conductivity. Fixing such a dE one can find an optimal number of QDs N that form the maximal output power for a given material.

Figure 5: Power factor P = σS2 as a function of the energy step dE and the number of QDs in a single nano-device with staircase energy configuration.
figure 5

kBT = 30 meV. Other parameters are specified in the main text.

Conclusion

We study the optimization of energy configurations of thermoelectric energy harvester assembled by many nano thermoelectric elements. Each nano device contains N QDs of staircase energy configuration with energy step dE. It is found that such energy configuration is better than the situation studied before: each nano thermoelectric element contains only N = 2 QDs. More importantly, we find that for each given energy step dE there is an optimal number of QDs N that maximizes the power factor. Such optimization yields higher output power when dE is smaller. Finally, we argue that our design is also better in thermoelectric power factor than hopping in a chain of QDs with random energy configuration. This is because the conductivity of such a random energy QDs chain is lower than that of the nano device with a single pair of QDs (when its parameters are optimized). On the other hand, the Seebeck coefficient is fluctuating around zero12, yielding relatively low Seebeck coefficient. Therefore, the power factor can be relatively lower as compared to the situation of assembled thermoelectric energy harvester with each nano-scale element contains a single pair of QDs. Our design of staircase energy configuration can have much better output power than the sigle-pair of QDs nano device. Therefore, our study is valuable for future design of nanostructured thermoelectric devices. Future study should also include the effect of parasitic heat conduction due to, e.g., phonon thermal conductivity, which may reduce the figure of merit, although it is usually much smaller in nanowires than in bulk materials.

Methods

The power factor is calculated by computing the conductivity σ and Seebeck coefficient S. From Eq. (10), the essential quantities of interest are the conductivity for both inelastic and elastic transport processes. The conductivity for elastic processes are calculated via Eqs (7) and (8). The hopping conductivity is calculated via solving the Kirchhoff current equation for Miller-Abrahams resistor network numerically. The key quantities to be calculated are the “local voltage” Vi = μi/e for all i labeling the QDs. According to ref. 12 the equations to be solved are

where

The left electrode has voltage VL = V/2, while the right electrode has voltage VR = −V/2. The conductance GiL (GiR) is finite only when i labels the first (last) QD, and . The hopping conductance between QDs are given by Eqs (5) and (6). By setting V = 0.01 and solving the above equation, we obtain Vi for all i. The electrical current flowing through the system due to hopping is then calculated via using the numerically obtained V1. The inelastic conductance of the nanowire-QDs system is then .

Additional Information

How to cite this article: Li, L. and Jiang, J.-H. Staircase Quantum Dots Configuration in Nanowires for Optimized Thermoelectric Power. Sci. Rep. 6, 31974; doi: 10.1038/srep31974 (2016).