This invention relates to materials having thermoelectric properties and to thermoelectric devices.
A thermoelectric device can be used to obtain electrical energy from a thermal gradient (for example, a thermoelectric generator using the Seebeck effect), or to generate a thermal gradient from electrical energy (for example, a thermoelectric refrigerator using the Peltier effect). The discussion below is directed to the Seebeck effect, but the general concepts also apply to applications of the Peltier effect.
A typical thermoelectric device is built up from several unicouples, which are typically pairs of thermally conductive p-type (P) and n-type (N) semiconductors. These unicouples are connected electrically in series and thermally in parallel. Theoretically, the maximum efficiency of the conversion of heat energy to electrical energy is given by:
where Tave=(TH+TC)/2 is the average temperature of thermal gradient having a hot temperature (TH) end and a cold temperature (TC) end, and Z is a figure of merit, defined as Z=S2σ/κ. The figure of merit Z depends on the macroscopic transport parameters of the materials, namely the Seebeck coefficient (S), electrical conductivity (σ), and thermal conductivity (κ). A large figure of merit is provided by a thermoelectric material having a large Seebeck coefficient, high electrical conductivity, and low thermal conductivity.
The Seebeck coefficient is further defined as the ratio of the open-circuit voltage to the temperature difference between the hot and cold junctions of a circuit exhibiting the Seebeck effect, or S=V/(TH−TC). Since Z varies with temperature, a useful dimensionless figure of merit can be defined as ZT.
By the end of the 1950s, the best bulk thermoelectric materials were found to be alloys of bismuth telluride and antimony, which gave a room temperature ZT˜1. Workers in the thermoelectric field have been attempting to improve the figure of merit over the past 40 years without much success. Increasing ZT is difficult because the three parameters S, σ, and k are all related to the free carrier concentration and are usually not independent. For example, doping typically increases the semiconductor's electrical conductivity, but decreases its Seebeck coefficient and increases the thermal conductivity. Efforts to reduce the lattice thermal conductivity by alloying also reduce the electrical conductivity by providing an extra scattering mechanism.
Dresselhaus and coworkers at MIT theoretically demonstrated that quantum confinement of electrons and phonons within nanowires of a thermoelectric material can increase the value of ZT. 1-D nanowires in particular could reach ZT≈2-5 if the nanowire diameter lies in the range of 5-10 nanometers. Certain structures have been investigated, for example such as described in Heremans, J. P. et al., “Thermoelectric Power of Bismuth Nanocomposites”; Phys. Rev. Lett.; 2002, 88, 216801; Venkatasubramanian, R. et al., “Thin-film thermoelectric devices with high room temperature figures of merit”; Nature; 2001, 413, 597-602; Harman, T. C. et al., “Thermoelectric quantum dot superlattices with high ZT”; Electron. Mater.; 2000, 29, L1-L4; Rabin, O. et al., “Anomalously high thermoelectric figure of merit in Bi1-xSbx nanowires by carrier pocket alignment”; APL; 2001, 79, 81-83; and Dresselhaus, M. S. et al., “Low-dimensional thermoelectric materials”; PSS; 1999, 41, 679-682. However, these approaches do not provide a simple approach to making large-scale, low-cost thermoelectric devices. Conventional semiconductor device fabrication methods are unsuitable for manufacturing bulk samples, and are often expensive.
In automobiles, about 70 percent of energy derived from fuel is lost to waste heat and engine cooling. Only a small proportion of energy provided by fuel combustion is used, and a large amount of thermal energy is thrown away. Recovery of waste thermal energy is a big challenge in automotive industries due to the increasing energy crisis. Thermoelectric conversion of thermal energy to electrical energy could be an effective way to obtain electrical energy from otherwise wasted heat production. However, direct thermal to electric conversion (DTEC) technology currently faces two major challenges: low conversion efficiency and insufficient power density. Hence, improved materials and devices having high thermoelectric conversion efficiency are urgently required.
In response to the need for high thermoelectric conversion efficiency materials, Zhang et al. have investigated thermoelectric materials comprising two or more components, at least one of which is a thermoelectric material (U.S. Pat. No. 7,309,830). However, a given thermoelectric material system can have a wide range of compositions that may, or may not, exhibit high ZT values, and as such, Banerjee et al. have developed a process for determining an optimum range of compositions for a nanocomposite thermoelectric material system (U.S. Pat. No. 7,734,428).
In addition to the above, other factors such as grain size and grain boundary properties have been postulated to affect the properties of thermoelectric materials. However, as of yet no process has been developed to determine if there is and/or which optimum range of such factors can provide a thermoelectric material with an improved ZT. Therefore, a process to model, calculate and/or determine an optimum range of grain related properties in which a thermoelectric material exhibits high ZT values would be desirable.
A process for manufacturing a thermoelectric material having a plurality of grains and grain boundaries is provided. The process includes determining a material composition to be investigated for the thermoelectric material and then determining a range of values of grain size and/or grain boundary barrier height obtainable for the material composition using current state of the art manufacturing techniques. Thereafter, a plurality of Seebeck coefficients for the material composition as a function of the range of values for the grain size and/or grain boundary barrier height are calculated. In addition, a plurality of electrical resistivity values and a plurality of thermal conductivity values for the material composition and as a function of the range of values for the grain size and/or grain boundary barrier height are calculated.
Once such plurality of values have been determined, a range of figure of merit values for the material composition as a function of the calculated Seebeck coefficients, calculated electrical resistivity values, and calculated thermal conductivity values are determined/calculated. Based on the range of figure of merit values, a generally maximum range thereof for the material composition is determined, a thermoelectric material having the determined material composition and an average grain size and grain boundary barrier height corresponding to the maximum range of figure of merit values is manufactured.
The material composition of the thermoelectric material can be a bulk thermoelectric material composition, or in the alternative, a nanocomposite thermoelectric material composition. The range of values of grain size can be between 5 and 100 nanometers while the range of values of grain boundary barrier height can be between 10 and 300 milli-electron volts.
In some instances, the nanocomposite thermoelectric material can have a first matrix phase, an inter-grain phonon scattering second phase and a plurality of third phase grain boundaries. The first matrix phase has an average grain size within a range of 5-100 nm, preferably within 5-50 nm and more preferably within 5-25 nm. The inter-grain scattering second phase can be a plurality of oxide nanoparticles that have an average diameter within a range of 2-100 nm, preferably 4-50 nm and more preferably 6-14 nm. Also, the plurality of third phase grain boundaries have an average width within a range of 2-75 nm, preferably 5-70 nm, more preferably 10-70 nm, even more preferably 15-65 nm and still yet more preferably 27-61
The grain size of the manufactured thermoelectric material can be obtained by consolidating a plurality of nanoparticles having a mean diameter generally equal to less than the grain size and the grain boundary barrier height can be obtained by doping of the thermoelectric material, altering a surface of a plurality of nanoparticles used to manufacture the thermooelectric material, and the like.
a-1d are schematic illustrations of: (a) the grain structure of a prior art thermoelectric material; (b) a schematic illustration of a thermoelectric material having altered grain boundaries according to an embodiment of the present invention; (d) a schematic illustration of a prior art nanocomposite thermoelectric material; and (d) a schematic illustration of a nanocomposite thermoelectric material having modified grain boundaries according to an embodiment of the present invention;
The present invention discloses a process for determining an optimum range of compositions for a thermoelectric material system, within which the material system may exhibit generally high figure of merit values. As such, the process has utility for improving the efficiency of experimental design and production of thermoelectric materials.
The process for determining an optimum range of compositions for a thermoelectric material system considers a variety of relevant factors, parameters and the like in order to determine which material systems should be considered and/or which range of compositions should be studied in more detail. A thermoelectric material exhibiting a dimensionless high figure of merit (ZT) needs to possess a high Seebeck coefficient (S) for high voltage generation, a low electrical resistivity (ρ) to minimize Ohmic losses and a low thermal conductivity (κ) to minimize heat conduction.
The relationship between ZT, S, ρ, and κ can be expressed as:
ZT=S
2
T/κρ Eqn 1
and/or as:
where κel and κph are the electronic and phonon contribution to the overall thermal conductivity k.
Typically, S, ρ, and κ are interdependent with an increase of the Seebeck coefficient resulting in an increase in electrical resistivity, whereas a decrease in the electrical resistivity results in an increase of the thermal conductivity. At least one approach for obtaining high figure of merit values has investigated the insertion of nanoparticles within a thermoelectric material (U.S. Pat. No. 7,309,830). Materials using this approach can result in phonons being scattered by the nanoparticles, thereby reducing the lattice thermal conductivity while leaving the electrical resistivity and Seebeck coefficient for the thermoelectric host matrix unchanged.
Elemental substitutions, also known as atomic substitutions, in potential thermoelectric materials have imperfections on the order of 1 angstrom (Å). Thus alloying additions can result in the scattering of short-wavelength phonons much more effectively than mid- and long-wavelength phonons. Therefore, mid- and long-wavelength phonons dominate the heat conduction in alloys and thermoelectric materials that have been doped with other elements not originally within the starting material. In the alternative, the inclusion of additions such as nanoparticles in the size range of phonon wavelengths introduces another scattering mechanism that affects mid- and/or long-wavelength phonons, thereby providing an opportunity to reduce the thermal conductivity of such materials below the alloy limit. However, which nanoparticles with respect to their composition, size and size distribution, and which host matrix the nanoparticles should be added to has heretofore been a difficult task to predict. In response to the difficulty in predicting successful thermoelectric material systems, a process to perform just this task has been developed by Banerjee et al. (U.S. Pat. No. 7,734,428).
An embodiment of the current process includes determining a material composition to be investigated for the thermoelectric material and determining a range of values for a grain related property that is obtainable for the material composition using state of the art manufacturing techniques. Once the material composition and the range of values for the grain related property have been determined, a plurality of Seebeck coefficients for the material composition as a function of the range of values can be calculated. In addition, a plurality of electrical resistivity values and a plurality of thermal conductivity values for the material composition as a function of the range of values for the grain related property can also be calculated.
It is appreciated that once the plurality of Seebeck coefficients, electrical resistivity values, and thermal conductivity values have been determined, a range of figure of merit values as a function thereof can be calculated and a generally maximum range of figure of merit values can be determined, such values being a function of the range of values of the grain related property. Naturally, once the maximum range of figure of merit values has been determined, a thermoelectric material having the determined material composition and the grain related property(ies) corresponding to the maximum range of figure of merit values is manufactured.
In the alternative to the above outlined embodiment, a plurality of material compositions can be investigated in this manner and a single material composition or a limited range of compositions having a potential and desired ZT are manufactured.
The grain related property can include any grain related property known to those skilled in the art, illustratively including grain size, grain boundary barrier height, and the like. For the purposes of the present invention, the term “grain size” is defined as the average mean diameter of grains within a thermoelectric material obtained through any method and/or technique known to those skilled in the art. For example and for illustrative purposes only, a grain size can be determined by taking a statistical average of a plurality of grain diameters from a metallographic cross-section of the material with a single grain diameter obtained by averaging at least two linear and orthogonal measurements across a given grain.
Also for the purposes of the present invention, the term “grain boundary barrier height” is defined as the energy potential of a grain boundary that will scatter an electron having less energy than the potential and allow an electron having more energy than the potential to pass therethrough.
The material composition to be investigated can be a bulk thermoelectric material composition, or in the alternative, a nanocomposite thermoelectric material composition. It is appreciated that the term “bulk thermoelectric material” refers to a polycrystalline material without the presence of second phase particles such as nanoparticles of an insulating type material. In the alternative, the term “nanocomposite thermoelectric material” refers to a bulk thermoelectric material having second phase particles such as nanoparticle insulating material inclusions, e.g. nanoparticle inclusions such as silicon oxide, zinc oxide, and the like.
The range of values for grain size of the material composition to be investigated can be between 5 and 100 nanometers (nm) while the range of values of grain boundary barrier height can be between 10 and 300 milli-electron volts (meV). In addition, the grain size of the manufactured thermoelectric material can be obtained by consolidating a plurality of nanoparticles having a mean diameter that is less than or generally equal to the final grain size of the material. The grain boundary barrier height of the manufactured thermoelectric material can be altered and/or obtained by doping of the material and/or altering a surface of the plurality of nanoparticles used to manufacture the thermoelectric material. In some instances, the surface of the plurality of nanoparticles is altered by applying a coating thereon before the nanoparticles are consolidated to produce the thermoelectric material.
Not being bound by theory, it is appreciated that a grain boundary is a result of and/or forms from a crystallographic misalignment between adjacent grains. In addition, the misalignment results in a residual electric charge across the grain boundary which can produce an electrostatic potential commonly referred to as an interfacial barrier and/or grain boundary barrier height which can be measured using AC impedance. As a first approximation, the magnitude of this interfacial barrier, also known as the grain boundary barrier height, can be calculated from the expression:
where Nt is the number density of traps, ε is the permittivity and ND is the doping concentration. The trap density is generally unknown and can vary widely, however assuming a generally high doping level and reported values for Nt in the range of 10−11-10−13 cm−3, an Eb of around 25 meV can be calculated.
The process can provide a thermoelectric material as schematically illustrated in
The grain size of the thermoelectric material 100 and/or 200 can be altered and/or engineered, e.g. by using nanoparticles with a desired average size to consolidate and manufacture the material. In addition, local electronic and thermal properties of the grain boundaries can be altered and/or engineered by controlling the interfacial composition between the grains, that is the interfacial composition of the grain boundaries. For example and for illustrative purposes only, a second phase can be engineered to be present at the interface between the grains such as Pb0.75Sn0.25Se coatings on Pb0.75Sn0.25Te; CoSb3 coatings on La0.9CoFe3Sb12; and alkali-metal salt coatings on (Bi0.2Sb0.8)2Te3. In fact, results from CoSb3/La0.9CoFe3Sb12 and coated (Bi0.2Sb0.8)2Te3 materials have shown moderate improvements in the figure of merit ranging from 15-30%.
In order to incorporate a grain related property into a modeling and/or manufacturing process, the scattering behavior of electrons, holes and/or phonons within a material can be useful. Not being bound by theory, a theoretical simulation can be based on the Boltzmann equation with relaxation time approximation. For example, a modified Callaway model with respect to the lattice of a thermoelectric material can be incorporated with scattering of phonons through grain boundaries, defects, nanoparticles, and the like provided by Equation 4 below:
τc−1=τB−1+τU−1+τN−1+τA−1+τD− Eqn 4
where τ corresponds to scattering time and the subscripts B, U, N, A and D correspond to boundary, Umpklamp, normal, alloy, and nanoparticle, respectively, related scattering.
With respect to carriers, that is electrons and holes, Equation 5 can be used where Op, DOp, and DAp represent optical phonon, deformation potential of optical phonon, and deformation potential of acoustic phonon related scattering.
τξ−1=τOp−1+τDOp−1+τDAp−1 Eqn 5
In addition to scattering time, the total electrical conductivity can be expressed as a summation of the contributions from both electron and hole bands, while the overall Seebeck coefficient can be obtained through weighting each band's contribution using a normalized electrical conductivity. In order to obtain the electronic thermal conductivity, the electronic thermal conductivity from the Lorentz number (L) can be obtained using Equations 6-8 below. In particular, Equation 6 is an expression of the total electrical conductivity (σ), Equation 7 is an expression of the overall Seebeck coefficient, and Equation 8 is an expression for the electronic thermal conductivity. It is appreciated that the bipolar thermal conductivity contribution to the electronic thermal conductivity must also be considered and that this type of conduction occurs when carriers moving between different bands carry heat via the Peltier effect and as such can still transport heat even if the net electric current is zero.
In addition to the above, the nature of grain boundary scattering exhibited by carriers can be estimated from the electron wavelength and electron mean free path (MFP) and the cumulative distribution function of the electron occupation number versus electron energy can provide the percentage of electrons that have energy less than a certain value. In particular, Equations 9-13 afford for the electron MFP, electron wavelength, and carrier percentage occupation as a function of dimensionless electron energy shown in
As shown in
Turning now to the actual effect of grain boundary properties on thermoelectric characteristics,
Not being bound by theory, assuming T(E) is a transmission probability of an electron passing through a grain boundary barrier height and there are N grain boundaries, the MFP of the electron due to scattering by the grain boundary can be expressed as Equation 14 when N is assumed to be infinity.
which further provides a relaxation time of:
τB=λgrainboundary/ν Eqn 15
where ν is given by:
In order to better understand the effect of grain related properties on the thermoelectric material behavior, and based on the model shown in
Turning now to
Regarding the Seebeck coefficient for a thermoelectric material,
Based on these figures and their teachings, it is clear that small grains with high grain boundary barrier potentials, for example Eb=300 meV, have the least effect on the Seebeck coefficient since such high potential barriers can filter even high energy electrons. On the other hand,
Regarding the dimensionless figure of merit ZT,
The effect of ceramic nanoparticle inclusions within a bulk thermoelectric material on grain boundary barrier height can also be of interest with
It is appreciated that
Turning now to
At step 230, ZT values are calculated for Ci as a function of the obtainable range of matrix grain sizes and obtainable range of grain boundary heights that were determined in steps 210 and 220. Thereafter, a matrix grain size and grain boundary height is selected as a function of the calculated ZT values for Ci at step 240. In some instances, step 240 can include selecting a desired average grain size for the matrix phase and a desired particle size for inter-grain phonon scattering particles as a function of the calculated ZT values. Finally, a thermoelectric material is manufactured at step 250, the thermoelectric material having the composition Ci from step 200, the selected matrix grain size, grain boundary height and/or inter-grain phonon scattering particles with an average particle size that is equivalent to the desired particle size for the inter-grain phonon scattering second phase from step 240. For the purposes of the present invention, the term equivalent is defined to be within 10%, i.e. the average particle size of the inter-grain phonon scattering particles is within +/−10% of the desired particle size.
Another flowchart illustrating a process according to another embodiment of the present invention is shown generally at reference numeral 30 in
The process 30 also includes calculating Seebeck coefficients for the Ci composition as a function of the obtainable range of matrix grain sizes and obtainable grain boundary heights at step 306. At step 308, the process 30 includes calculating electrical resistivity values for Ci as a function of the obtainable range of matrix grain sizes and grain boundary heights. At step 310, the calculation of thermal conductivity values for Ci as a function of the obtainable range of matrix grain sizes and grain boundary heights is performed. Next, the calculation of ZT values for Ci as a function of the calculated Seebeck coefficients, electrical resistivity values, and thermal conductivity values is performed at step 312.
Once the ZT values have been calculated, a maximum range of the calculated ZT values for Ci is determined at step 314 and step 316 includes determining a matrix grain size and a grain boundary height that is within the maximum determined range from step 314. At step 318, a thermoelectric material having the composition Ci is manufactured, the material having the determined matrix grain size and grain boundary height from step 316. It is appreciated that in order to manufacture the thermoelectric material at step 318, material corresponding to the composition Ci is provided and processed to produce the material.
Referring to
A desired range of the calculated ZT values for Ci is determined at step 440, e.g. a desired maximum range of the calculated ZT values can be determined. Based on the determined desired range of the calculated ZT values, the range of matrix grain sizes and grain boundary heights that fall within this range are determined at step 450. Then, matrix grain sizes and grain boundary heights that are obtainable using current state of the art production techniques and that fall within the determined desired range of calculated ZT values for Ci are determined at step 460.
A powder that has the Ci composition and an average particle diameter that is equivalent to an obtainable matrix grain size that falls within the grain sizes of step 460 is provided. It is appreciated that the powder can be a homogeneous powder, i.e. a powder made of individual powder particles that have a generally uniform composition with each other or, in the alternative, a non-homogeneous composition, i.e. the powders being made from first component powder particles and second component powder particles. As stated above, the first component powder particles can be in the form of be a metal, alloy, semiconductor, ceramic, e.g. an oxide, nitride, etc., and the like. Also, the second component particles can be in the form be a metal, alloy, semiconductor, ceramic, e.g. an oxide, nitride, etc., and the like. In addition, third component particles, fourth component particles, etc. can be included in the powder having the Ci composition at step 470, the third, fourth, etc. particles being of the form of be a metal, alloy, semiconductor, ceramic, e.g. an oxide, nitride, etc., and the like. Also, the powders, particles, etc., may or may not be in the form of nanoparticles such a nano-spheres, nano-rods, nano-discs nano-ellipsoids, and the like.
The powder having the Ci composition is processed to produce a component. For example, a process for processing the powders is shown in
It is also appreciated that the particle diameter of the first component particles P1 can be the same or different than the particle diameter of the second component particles P2. Finally, it is appreciated that the terms “particle diameter” and “matrix grain size” refer to an average particle diameter and average matrix grain size, respectively, as is known to those skilled in the art. The variation in particle diameters and matrix grain sizes can have a half width at half maximum height (HWHM) to modal diameter ratio between 0.4-0.6 for a differential distribution as is known to those skilled in the art. In other instances, the HWHM/modal diameter ratio is between 0.3-0.4 or, in the alternative, between 0.2-0.3. In the alternative, the HWHM/modal diameter ratio is between 0.6-0.7 or, in the alternative, between 0.7-0.8.
The process 60 further includes compaction of powders to produce a thermoelectric component at step 610. The step 610 can be a compaction by any means or method known to those skilled in the art, illustratively including sintering, hot isostatic pressing (HIP), cold isostatic pressing (CIP), die pressing, continuous particle or powder processing (CPP), etc. as shown at 612. In some instances, the component is further treated at step 620 in order to obtain a desired matrix grain size and/or desired grain boundary barrier height. For example and for illustrative purposes only, the treatment at step 620 can include a thermal treatment, a mechanical treatment, and/or a thermal-mechanical treatment. Other treatments such as exposure to electromagnetic radiation, nuclear radiation, and the like can be included.
Regarding the calculation of the various Seebeck coefficients, electrical resistivity values, thermal conductivity values, ZT values, and the like,
The various calculations can include algorithms with respect to Equations 1-16, assumptions, electric constants and/or physical constants known to those skilled in the art. For example, the temperature T referenced in Equation 1 can be assumed to be room temperature. In the alternative, the calculations can assume a plurality of temperatures, e.g. temperatures ranging from 0° C. to 200° C. at increments of 1° C., increments of 5° C., increments of 10° C., and the like.
In order to illustrate a sample calculation, but not limit the scope of the instant disclosure in any way, an example of a ZT calculation is provided below.
The figure of merit (ZT) for a given grain size and grain barrier height combination “j”, is given by:
ZT=S
2
·T·C/(Ke+Kl) Eqn 17
where S is the Seebeck coefficient for the given grain size and grain boundary barrier height, C is the electrical conductivity, Ke is the electron contribution to the overall thermal conductivity and Kl is the phonon contribution to the overall thermal conductivity—all for the given grain size and grain boundary barrier height. It is appreciated that the index “j” for the given grain size and grain boundary energy barrier height is not shown for convenience, unless needed for clarity. Stated differently, each of the expressions discussed are for the given grain size and grain boundary energy barrier height “j”.
In order to properly define S, C, Kph and Ke, a series of constants known to those skilled in the art are required and provided below. It should be appreciated that the values for the constants listed below are presented without units, as used in computer code for the calculation of ZT as a function of grain size and grain boundary energy height. However, it should also be appreciated that the units for the constants provided below would be known to one skilled in the art and be in accordance with units that afford calculation of the Seebeck coefficient in microvolts per meter (μV/m), electrical conductivity in siemens per meter (S/m) and thermal conductivity in watts per meter kelvin (W/mK).
General constants used in an example calculation include:
π=3.14
κB=1.38×10−23 =Boltzmann constant
h
c=1.054×10−34=Planck's constant
e
v=1.6×10−19=1 electron volt
e=1.6×10−19=electron charge
m
e=9.1×10−31=electron effective mass
ε0=8.85×10−12=permittivity of air
e
1=69.8·εo·4π=high frequency dielectric constant Eqn 18
e
0=400·εo·4π=static dielectric constant Eqn 19
Also, density of states constants and expressions related to effective mass include:
Nv=12 =number of valleys in the electron bandstructure
E
g=0.13·ev−1.08×10−4·T·ev=electron bandgap Eqn 20
βL=Eg/(kBT)=bandgap in kBT Eqn 21
β=kBT/Eg=inverse of bandgap in kBT Eqn 22
e
g
=E
g
/e
v=bandgap in electron volt Eqn 23
m
h1=0.0308·me=hole effective mass Eqn 24
m
h2=0.441·me=hole effective mass Eqn 25
m
h3=0.0862·me=hole effective mass Eqn 26
m
e1=0.0213·me=electron effective mass Eqn 27
m
e2=0.319·me=electron effective mass Eqn 28
m
e3=0.0813·me=electron effective mass Eqn 29
md
e
=N
v
2/3·(me1·me2·me3)1/3=density of state electron effective mass Eqn 30
md
e1=(me1·me2·me3)1/3=density of state electron effective mass Eqn 31
md
h
=N
v
2/3·(me1·mee2·me3)1/3=density of state hole effective mass Eqn 32
md
h1=(me1·me2·me3)1/3=density of state hole effective mass Eqn 33
Mc
e=3/(1/me1+1/me2+1/me3)=Total effective mass of electron Eqn 34
Mch=3/(1/mh1+1/mh2+1/mh3)=Total effective mass of hole Eqn 35
Fermi energy expressions include:
with Fermi functions:
and conductivity effective mass expressions:
Regarding scattering terms, the polar optical phonon scattering of electrons (τpoe) and holes (τpoh) can be determined from the following constants and expressions:
εo=8.85×10−12=permittivity of air
e
1=69.8=high frequency dielectric constant
e
0=400=static dielectric constant
K
0=0.1ev=optical phono energy
N
0=1/(exp(K0/(κB·T))−1)=phonon Plank function Eqn 51
cop
e=(4π·εo·hc2/(3e2·(1/e1−1/e0)·N0))·(2/(mdc·K0·(1+K0/Eg)))0.5 Eqn 52
cpo
h=(4π·εo·hc2/(3e2·(1/e1−1/e0)·N0))·(2/(mdh·K0·(1+K0/Eg)))0.5 Eqn 53
b
e=(1+2βz)/(z+βz2) Eqn 54
τz3=1/be Eqn 55
with:
τpoe=cpoe·τz3=lifetime for optical phonon-electron scattering Eqn 56
and:
τpoh=cpoh·τz3==lifetime for optical phonon-hole scattering Eqn 57
Deformation potential scattering of electrons (τdae) and holes (τdah) by acoustic phonons can be determined using the following constants and expressions:
Ka=1.1=fitting constant
C
1=7.1×1010=combination electric constant
Eac=3.5ev=deformation potential for acoustic phonon Eqn 58
B
a=8βz(1+βz)·Ka/(3(1+2βz)2) Eqn 59
A
a
=βz(1−Ka)/(1+2βz) Eqn 60
Cda
e=2πhc4·C1/(Eac2·(2·mdc·κB·T)1.5) Eqn 61
Cda
h=2πhc4·C1/(Eac2·(2·mdh·κB·T)1.5) Eqn 62
τz1=1/(((z+βz2)0.5)·(1+2βz)·((1−Aa)2−Ba)) Eqn 63
with:
τdae=Cdae·τz1=lifetime for acoustic phonon-electron scattering Eqn 64
and:
τdah=Cdah·τz1=lifetime for acoustic phonon-hole scattering Eqn 65
Deformation potential scattering of electrons (τdoe) and holes (τdoh) by optical phonons can be determined using the following constants and expressions:
r
ho=7.86×103=density
a=10.45×10−10=lattice constant
K
0=1.1=fitting constant
E
oc=60ev=deformation potential for optical phonon Eqn 66
B
o=8βz(1+βz)·Ko/(3(1+2βz)2) Eqn 67
A
o
=βz(1−Ko)/(1+2βz) Eqn 68
Cdo
e=2hc2·a2·K02·rho/(πEoc2·(2·mde·κβ·T)1.5) Eqn 69
Cdo
h=2hc2·a2·K02·rho/(πEoc2·(2·mdh·κB·T)1.5) Eqn 70
τz2=1/(((z+βz2)0.5)·(1+2βz)·((1−Ao)2−Bo)) Eqn 71
with:
τdoe=Cdoe·τz2=lifetime for deformation potential-electron scattering Eqn 72
and:
τdoh=Cdoh·τz2=lifetime for deformation potential-hole scattering Eqn 73
In the event that the thermoelectric material includes nanoparticles, the scattering of elections (τie) and holes (τih) by the nanoparticles can be determined using the following constants and expressions:
with:
τie=(κBT)1.5·(z1.5·(1+βz)1.5·4R·(2mde1)0.5)/((1+2βz)·U·3λe)=lifetime for nanoparticles-electron scattering Eqn 86
and:
τih=(κBT)1.5·(z1.5·(1+βz)1.5·4R·(2mdh1)0.5)/((1+2βz)·U·3λh)=lifetime for nanoparticles-electron scattering Eqn 87
Grain boundaries can naturally be a source of scattering, and the scattering of electrons (τbe2) and holes (τbh2) can be determined using the following constants and expressions:
e
b=0.3(values range from 0.003-0.3 with 0.3 corresponding to a very strong electrical conductivity)=Barrier height
d1=30=grain boundary constant
E
b
=−e
b
·e
v=grain boundary barrier energy height=‘Eb’ in FIG. 3 Eqn 88
DL=d
1·10−9=grain size=‘L’ in FIG. 3 Eqn 89
Gw=5×10−9=grain boundary width=‘W’=FIG. 3
E=κBTz Eqn 90
GN=4(E/Eb)·(1−E/Eb) Eqn 91
GD
e=((2mde·Eb·Gw2/hc2)·(1−E/Eb))0.5 Eqn 92
Z
e=(exp(GDe)−exp(−GDe))/2 Eqn 93
Ze1=GDe Eqn 94
with:
τbe2=DL·(mde/(2·E))0.5·(1+GN/(Ze1)2)=lifetime for grain boundary-electron scattering Eqn 95
and:
GN=4·(E/Eb)·(1−E/Eb) Eqn 96
GD
h=((2·mdh·Eb·Gw2/hc2)·(1−E/Eb))0.5 Eqn 97
Z
h=(exp(GDh)−exp(−GDh))/2 Eqn 98
Zh1=GDh Eqn 99
with:
τbh2=DL·(mdh/(2E))0.5·(1+GN/(Zh1)2)=lifetime for grain boundary-hole scattering Eqn 100
Though not required, interfacial surface roughness scattering of an inclusion particle can be considered with such scattering of electrons (τifre) and holes (τifrh) determined by the following constants and expressions:
d=1=roughness height in nm
c1=2.4=correlation length in nm
λ=c1×10−9 Eqn 101
δ=d×10−9 Eqn 102
ε0=8.85×10−12
For holes:
and for electrons:
Thus the total scattering for electrons (τze) and holes (τzh) can be obtained from:
τze=1/(1/τdoe+1/τdae+1/τpoe+1/τbe2+1 /Γie+1/τifre)=total lifetime for electron scattering Eqn 123
τzh=1/(1/τdoh+1/τdah+1/τpoh+1/τbh2+1/Γie+1/τifrh)=total lifetime for hole scattering Eqn 124
Once the scattering terms have been determined, electrical conductivity (Ce, Ch), Seebeck coefficient (Se, Sh) can be determined for the given grain size and grain boundary energy barrier height using the following expressions. In particular, Ce and Ch can be determined from:
and the total electrical conductivity (C) is simply:
C=(Ce+Ch) Eqn 129
Also, Se and Sh can be determined by:
and the total Seebeck coefficient (S) is simply:
S=(Se.Ce+Sh·Ch)/C Eqn 132
It is appreciated that the power factor (P) is given by:
P=S
2
·C Eqn 133
Also, it should be appreciated that the preceding constants and expressions afford for the calculation of electrical conductivity and Seebeck coefficient as a function of grain size, grain boundary width and/or grain boundary barrier height. Naturally, certain constants would be assumed and varied as needed. For example, the temperature (T) for the calculations used to produce
Regarding thermal conductivity of the material, it is appreciate that additional expressions and scattering terms are needed. For example, Lorentz numbers for electrons (Le) and holes (Lh) are useful and can be obtained from the following expressions:
which afford for the electronic thermal conductivity (Ke) to be calculated from:
K
e
=T·C·(kB2/e2)·(Le+Lh+Lb) Eqn 137
As such, the electronic thermal conductivity as a function of grain size can be calculated and plotted as shown in
Regarding lattice thermal conductivity, the following constants and expressions are useful:
which afford for grain boundary scattering (t—B), Umpklamp scattering (t—u), normal scattering (t_N), alloy scattering (t_A) and nanoparticle scattering (t—D) to be determined from the following expressions:
For grain boundary scattering:
D
L=30×10−9=grain size
FT1=0.8=fitting parameter
FT2=1015=fitting parameter
ε=0.1=fitting parameter
t
ref=(DL/v)·FT1=total lifetime for phonon-and reflection type scattering Eqn 155
t
diff=(DL/v)·(κB·θd/K0)·1/η=total lifetime for phonon-and diffraction type scattering Eqn 156
t
ray=(v/DL)3·(θd·hc/(T·K0))4·FT2=total lifetime for phonon-and Rayleigh type scattering Eqn 157
and
t
—
Bn=1/tref+1/tdiff+1/tray Eqn 158
If surface roughness scattering is to be considered, the following constants and expressions can be included in a calculation:
n=1
W
L=3·10−9=grain boundary width
k=2π/WL Eqn 159
dw
AB=9.69×1012=used/calculated for BiTe/SiO2
h
cw=0.0024·ev
u
1=1730=constant for BiTe
λ=c1·10−9 Eqn 160
δ=d·10−9 Eqn 161
ww1=2=1st grain boundary thickness value/parameter
L
1
=w
w1·10−9 Eqn 162
q
z1
=n·π/L
1 Eqn 163
w
w2=5=2nd grain boundary thickness value/parameter
L
2=
w
w2
·10
−9 Eqn 164
q
z2
=n·π/L
2 Eqn 165
w
w3=10=3rd grain boundary thickness value/parameter
L
3
=w
w3·10−9 Eqn 166
q
z3
=n·π/L
3 Eqn 167
Z
p=∫06.28((1−cos(θ))(cos(θ))2exp(−k2λ2(sin(θ/2))2)dθ Eqn 168
And interface roughness scattering:
α1=(1−(qz12−k2)/(qz12+k2)·sin(2qz1δ)/(2qz1δ))·(δ/L1) Eqn 169
τifr
t
—
c=t
—U
+t
—N
+t
—A
+t
—D
+t
—Bn
+τ
ifr
1=total lifetime of phonon scattering Eqn 171
t
c=1/t—c Eqn 172
t
N=1/t—N Eqn 173
and the Lorentz numbers can be calculated from:
which affords for the lattice contribution to the thermal conductivity to be determined from the following expression:
K
1=(κB4·T3/(2π·v·hc3))·(L1+L22/L3) Eqn 177
As such, the lattice thermal conductivity (K1) can be calculated as a function of grain size and plotted as shown in
Finally, the figure of merit as a function of grain size can be determined as a function of grain size and plotted as shown in
Naturally, the calculation of ZT would be repeated for various values of matrix grain size, grain boundary barrier height, grain boundary width, nanoparticle, nanoparticle amount and/or nanoparticle size that were desired to be examined. Also, such calculations would be performed by a computer such as the one illustratively shown in
In this manner, researchers can estimate which matrix grain size, grain boundary barrier height, grain boundary width, nanoparticle, nanoparticle amount and/or nanoparticle size systems are more likely to exhibit relatively high ZT values and/or which compositions or range of compositions within a particular system may provide the highest ZT values. This range of compositions with the associated high ZT values can also be compared with other material properties such as mechanical property data, chemical property data and the like, in order to choose an optimum thermoelectric material composition for a given application. As such, the process provides a valuable tool to guide experimental design of thermoelectric materials.
For example, the process disclosed herein was used to design and produce a novel thermoelectric material with an improved ZT as discussed below. In particular, the process guided utilization of phonon scattering via inclusion of nanoparticles into a thermoelectric matrix to reduce phonon thermal conductivity, and also hybridization of the matrix with grain boundary modification to improve the carrier mobility, and therein the power factor.
A unique nanocomposite (referred to as BATZ) was created of a bismuth antimony telluride matrix with both zinc antimony grain boundary modifications and inter-grain phonon scattering zinc oxide nanoparticles. The power factor augmentation, in conjunction with reduction of thermal conductivity, resulted in an 83% improvement to the figure of merit ZT compared to an analogous or equivalent sample without zinc-nanostructures (referred to as BAT). In addition, it is appreciated that for the purposes of the present invention, the term “analogous” and “analogous material” refers to a material having generally the same non-oxide matrix composition and crystallite or grain size as the modified nanocomposite disclosed and discussed below and in
The BATZ material was made by means of a wet-chemistry synthesis that first yielded an admixture of bismuth antimony telluride nanoparticles and zinc oxide nanoparticles. This nanoparticle mixture was then consolidated, by hot pressing, to form a BATZ nanocomposite. As indicated below, the BAT nanocomposite was formed in an analogous manner, excluding the presence of zinc oxide nanoparticles and thereby precluding the formation of complex zinc-nanostructures responsible for improving the ZT from 0.6 to 1.1 (at 100° C.) as shown in
The synthesis of the BAT and BATZ nanoparticles was conducted as follows. A reagent solution of sodium telluride hydride was made in the following manner. Water (103 mL) and tellurium powder (5.91 g) were added to a flask degassed with inert gas, rapidly stirred and then cooled in an ice water bath. Sodium borohydride (6.32 g) was then added, in portions, and the reaction was allowed to stir for at least 12 hours until all of the tellurium powder has dissolved. The product solution was filtered through a fitted glass filter, still excluding oxygen, to collect a merlot-colored filter cake product solution. The filter cake was then washed with water (15 mL), through the fritted glass filter, and combined with an initially collected quantity of sodium tellurium hydride solution.
A solution of water and 28% ammonium hydroxide (6.5 mL and 5.5 mL, respectively) was prepared, and a combination of potassium antimony tartrate (9.02 g) and bismuth citrate (1.54 g) were dissolved completely in the diluted ammonium hydroxide solution. The antimony and bismuth salts were dissolved in portions; rigorously dissolving each portion before adding more of the salts. The freshly prepared aqueous solution of antimony and bismuth salts was then added to a reaction flask that had previously been degassed with inert gas and charged with water (480 mL). For the BATZ synthesis, a finely dispersed aqueous suspension of zinc oxide nanoparticles was added to the reaction solution (2.27 g of zinc oxide nanoparticles in 68 mL water).
The collected sodium tellurium hydride solution was then added dropwise to the rapidly stirring reaction solution containing the dissolved bismuth and antimony salts and zinc oxide nanoparticle suspension. After addition of the sodium tellurium hydride solution was complete, the reaction was allowed to stir for an additional 20 minutes. The product was then collected using centrifugation and washed under an inert atmosphere in a Soxhlet apparatus with a solution of water, methanol, and 28% ammonium hydroxide (35/165/0.8 respectively by volume). A final rinsing with methanol was administered and the methanol-slurry of nanoparticle product was dried under an inert gas flow and then ground to a fine powder, in a glovebox.
Sintering of the composite nanoparticle powders was performed using graphite punch and dies and a hot press. All samples were first baked at 400° C. for 20 minutes and then sintered at 400° C. and 100 MPa for 4 hours under an argon atmosphere.
Temperature dependent transport properties for the BAT and BATZ nanocomposites, between room temperature and 200° C., are shown in
The Seebeck coefficient was over 200 μV/K at temperatures below 150° C. for both BATZ and BAT as illustrated in
The BATZ material thermal conductivity ranged from 0.4 to 0.6 W/mK. A maximum reduction of 41% in thermal conductivity (at 150° C.) was realized from adding zinc oxide nanoparticles as illustrated in
Transmission electron microscopy (TEM) imaging was conducted to correlate the structural origin of the electrical conductivity increase in the presence of a reduced thermal conductivity in the BATZ material while maintaining a generally constant Seebeck coefficient when compared to the BAT material. Zinc antimony formed from a reaction of the nanocomposite constituents during the sintering process, and precipitated at the boundaries between bismuth antimony telluride grains in the BATZ material as illustrated in
Two other crystalline phases were identified in the XRD spectrum shown in
Zinc oxide nanoparticles were visible throughout the bismuth antimony telluride grains via TEM as shown in
The thermoelectric properties of the BATZ nanocomposite described were disentangled by the addition of phonon scattering zinc oxide nanoparticles and the formation of charge carrier mobility-enhancing zinc antimony grain boundaries. This effective decoupling of the electrical conductivity, Seebeck coefficient, and thermal conductivity, as shown here on multi-gram scale, is critical for the advancement of the field and its commercial viability. And in general, these two approaches to improving the ZT value, when combined in a single nanocomposite, offer a new hybrid methodology in thermoelectric material research.
As disclosed above, the plurality of material positions to be investigated can include a first component with a volume fraction of a second component ranging from 0.0 to 1.0. In some instances, the material compositions to be investigated can include the first component with a volume fraction of the second component ranging from 0.0 to 0.7. The plurality of thermal conductivity values are calculated as a function of the scattering cross section of the second component nanoparticles for the plurality of material compositions being investigated. In addition, the scattering cross section can be a function of the interfacial surface area of the second component nanoparticles for the plurality of material compositions being investigated. The function of the plurality of material compositions being investigated can include the size of the second component nanoparticles, the size distribution of the second component nanoparticles and an interfacial property of the second component nanoparticles. In some instances, an interfacial interaction property between the second component nanoparticles and the first component can be used.
It is appreciated that the thermoelectric device can be designed and developed using the process disclosed herein, the thermoelectric device having a first electrical contact, a second electrical contact, and a thermoelectric bulk material located within an electrical path between the first electrical contact and the second electrical contact. The thermoelectric bulk material can include a first powdered component having a particulate form, the first powdered component being electrically conducting, and a second powdered component having a particulate form, the second powdered component having an electrical conductivity substantially less than the first powdered component. The first and second powdered components can retain the particulate form in the bulk thermoelectric material and the thermoelectric bulk material can be a composite that has nanostructures of the first powdered component. The first component can be a metal or a semiconductor. The second component can be an electrical insulator in the form of a ceramic. It is appreciated that the process can also be used for semiconductor-metal and semiconductor-semiconductor thermoelectric material systems.
It is further appreciated that the bulk thermoelectric material can be an electrically conducting material such as a semiconductor or metal. In addition, the electrically conducting material can be an organic material, or an organic material such as an organic semiconductor.
In the temperature range between 300K to 500K, an n-type material such as Bi2Te3 or Bi2Se3 and/or the p-type material such as Bi2Te3 or Sb2Te3 can be used for the bulk thermoelectric material. For the temperature range between 500K to 700K, n-type materials such as PbTe or SnTe doped with Bi and/or p-type materials such as PbTe or SnTe can be used. In addition, materials such as ZnSb, SiGe, CoSb, CeFeCoSb, and alloys thereof can be used for the bulk thermoelectric material. Regarding nanocomposite thermoelectric materials, nanoparticles of insulating materials such as SiO2, ZnO, Al2O3, LaCoO4, NaCoO4, SnO2, (ZnO)x(In2O5)y, ZrO, Y-stabilized ZrO, ZrO2, yttria stabilized ZrO2 (YSZ), La2O3 stabilized YSZ, other oxide materials, carbon nanoparticles, electrically insulating polymer nanoparticles, fullerenes such as Co.
The invention is not restricted to the illustrative examples described above. The examples are not intended as limitations on the scope of the invention. Methods, apparatus, compositions and the like described herein are exemplary and not intended as limitations on the scope of the invention. Changes therein and other uses will occur to those skilled in the art. The scope of the invention is defined by the scope of the claims.
The present application is a continuation-in-part (CIP) of U.S. patent application Ser. No. 13/548,395 filed on Jul. 13, 2012, which in turn is a CIP of U.S. patent application Ser. No. 13/117,286 filed on May 27, 2011, both of which are incorporated herein in their entirety by reference.
Number | Date | Country | |
---|---|---|---|
Parent | 13548395 | Jul 2012 | US |
Child | 14303878 | US | |
Parent | 13117286 | May 2011 | US |
Child | 13548395 | US |