Heusler Thermoelectrics RYAN NEED UNIVERSITY OF CALIFORNIA SANTA BARBARA MATRL 286G, SPRING 2014.

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Presentation transcript:

Heusler Thermoelectrics RYAN NEED UNIVERSITY OF CALIFORNIA SANTA BARBARA MATRL 286G, SPRING 2014

Heusler Compounds

Half Heusler, XYZ (e.g. TiCoSb) Sb Ti Co

Heusler Compounds Half Heusler, XYZ (e.g. TiCoSb) Sb Ti Co Full Heusler, XY 2 Z (e.g. TiCo 2 Sb) Sb Ti Co

Thermoelectric Devices Images from: J-F Li, W-S Liu, L-D Zhao, M Zhou, High-performance nanostructured thermoelectric materials, NPG Asia Mater. 2 4 (2010)

Thermoelectric Devices

Heusler Compounds Thermoelectric Devices The goal of this talk… is to understand where these two overlap.

Points of inquiry 1.What material properties make a good thermoelectric? Derivation of thermoelectric figure or merit, ZT Relationships between electronic and thermal properties

Points of inquiry 1.What material properties make a good thermoelectric? Derivation of thermoelectric figure or merit, ZT Relationships between electronic and thermal properties 2.How do Heusler alloys meet these criteria? Electron count rules for semiconducting behavior Unit cell complexity and alloying for phonon scattering

Points of inquiry 1.What material properties make a good thermoelectric? Derivation of thermoelectric figure or merit, ZT Relationships between electronic and thermal properties 2.How do Heusler alloys meet these criteria? Electron count rules for semiconducting behavior Unit cell complexity and alloying for phonon scattering 3.Can we design nanostructures to improve Heusler TEs? Nanoscale grain sizes through ball milling and SPS Half Heusler matrix with full Heusler nanoparticles

Points of inquiry 1.What material properties make a good thermoelectric? Derivation of thermoelectric figure or merit, ZT Relationships between electronic and thermal properties 2.How do Heusler alloys meet these criteria? Electron count rules for semiconducting behavior Unit cell complexity and alloying for phonon scattering 3.Can we design nanostructures to improve Heusler TEs? Nanoscale grain sizes through ball milling and SPS Half Heusler matrix with full Heusler nanoparticles

What material properties do we need to consider for a thermoelectric device?

What do we want this thermoelectric device to do?

What material properties do we need to consider for a thermoelectric device? What do we want this thermoelectric device to do? To maximize output power or temperature gradient

What material properties do we need to consider for a thermoelectric device? What do we want this thermoelectric device to do? To maximize output power or temperature gradient QCQC QHQH

What material properties do we need to consider for a thermoelectric device? What do we want this thermoelectric device to do? To maximize output power or temperature gradient QCQC QHQH Q C = Peltier Cooling

What material properties do we need to consider for a thermoelectric device? What do we want this thermoelectric device to do? To maximize output power or temperature gradient QCQC QHQH Q C = Joule Heating Peltier Cooling −

What material properties do we need to consider for a thermoelectric device? What do we want this thermoelectric device to do? To maximize output power or temperature gradient QCQC QHQH Q C = Joule Heating Thermal Diffusion Peltier Cooling − −

What material properties do we need to consider for a thermoelectric device? What do we want this thermoelectric device to do? To maximize output power or temperature gradient QCQC QHQH Q C = Joule Heating Thermal Diffusion Peltier Cooling − −

What material properties do we need to consider for a thermoelectric device? What do we want this thermoelectric device to do? To maximize output power or temperature gradient QCQC QHQH Q C = Joule Heating Thermal Diffusion Peltier Cooling − −

The key material properties are inversely related through carrier concentration.

Image from: G.J. Snyder, E.S. Toberer, Complex thermoelectric materials, Nat. Mater. 7 (2008) The key material properties are inversely related through carrier concentration.

We want a degenerate semiconductor or dirty metal with a complex lattice for optimal ZT and device performance. Image from: G.J. Snyder, E.S. Toberer, Complex thermoelectric materials, Nat. Mater. 7 (2008) The key material properties are inversely related through carrier concentration.

Points of inquiry 1.What material properties make a good thermoelectric? Derivation of thermoelectric figure or merit, ZT Relationships between electronic and thermal properties 2.How do Heusler alloys meet these criteria? Electron count rules for semiconducting behavior Unit cell complexity and alloying for phonon scattering 3.Can we design nanostructures to improve Heusler TEs? Nanoscale grain sizes through ball milling and SPS Half Heusler matrix with full Heusler nanoparticles

Valence precise half Heusler compounds can be semiconductors.

Sb Ti Co Image from: H.C. Kandpal, C. Fesler, R. Seshadri, Covalent bonding and the nature of band gaps in some half-Heusler compounds, J. Phys. D 39 (2006) Example: TiCoSb Valence precise half Heusler compounds can be semiconductors.

Sb Ti Co Image from: H.C. Kandpal, C. Fesler, R. Seshadri, Covalent bonding and the nature of band gaps in some half-Heusler compounds, J. Phys. D 39 (2006) Example: TiCoSb Valence precise half Heusler compounds can be semiconductors. X: Ti → Ti 4+ (Ar) Y: Co → Co 4- (Ga) Z: Sb → Sb

X gives up its electrons and forms a covalent zinc-blende YZ sublattice. Sb Ti Co Image from: H.C. Kandpal, C. Fesler, R. Seshadri, Covalent bonding and the nature of band gaps in some half-Heusler compounds, J. Phys. D 39 (2006) Example: TiCoSb X: Ti → Ti 4+ (Ar) Y: Co → Co 4- (Ga) Z: Sb → Sb Valence precise half Heusler compounds can be semiconductors. 18-electron half Heusler compounds are electronically identical to common III-V systems.

Image from: T.Graf, C. Fesler, S.S.P. Parkin, Simple rules for the understanding of Heusler compounds, Prog. Solid State Chem. 39 (2011) Values from: H. Hohl, A.P. Ramirez, C. Goldmann, G. Ernst, B. Wolfing, E. Bucher, Efficient dopant for ZrNiSn-based thermoelectric materials, J. Phys.: Condens. Matter 11 (1999) Atomic disorder can be used to scatter phonons by alloying on the X, Y, and Z sites.

Image from: T.Graf, C. Fesler, S.S.P. Parkin, Simple rules for the understanding of Heusler compounds, Prog. Solid State Chem. 39 (2011) Values from: H. Hohl, A.P. Ramirez, C. Goldmann, G. Ernst, B. Wolfing, E. Bucher, Efficient dopant for ZrNiSn-based thermoelectric materials, J. Phys.: Condens. Matter 11 (1999) Atomic disorder can be used to scatter phonons by alloying on the X, Y, and Z sites. Heavily alloy X site with large mass contrast (XX’NiSn) X: Ti → Zr x Hf y Ti 0.5 κ: 9.3 W/mK → 3-6 W/mK

Image from: T.Graf, C. Fesler, S.S.P. Parkin, Simple rules for the understanding of Heusler compounds, Prog. Solid State Chem. 39 (2011) Values from: H. Hohl, A.P. Ramirez, C. Goldmann, G. Ernst, B. Wolfing, E. Bucher, Efficient dopant for ZrNiSn-based thermoelectric materials, J. Phys.: Condens. Matter 11 (1999) Atomic disorder can be used to scatter phonons by alloying on the X, Y, and Z sites. Heavily alloy X site with large mass contrast (XX’NiSn) X: Ti → Zr x Hf y Ti 0.5 κ: 9.3 W/mK → 3-6 W/mK Lightly dope on the Z site to introduce carriers (XX’NiSn:Sb) Z: Sn → Sn 1-δ Sb δ σ: 100 S/cm → 1200 S/cm

However, phonons cover a wide range of wavelengths and require a multi-length scale scattering approach. Image from: K. Biswas, J. He, I.D. Blum, C-I Wu, T.P. Hogan, D.N. Seidman, V.P. Dravid, M.G. Kanatzidis, High- performance bulk thermoelectrics with all-scale hierarchical architectures, Nat. Lett. 489 (2012)

Heusler alloys have phonon dispersions with high DOS at nanometer wavelengths. Image from: A.T. Zayak, P. Entel, K.M. Rabe, W.A. Adeagbo, M. Acet, Anomalous vibrational effects in nonmagnetic and megnetic Heusler alloys, Phys. Rev. B 72 (2005)

Points of inquiry 1.What material properties make a good thermoelectric? Derivation of thermoelectric figure or merit, ZT Relationships between electronic and thermal properties 2.How do Heusler alloys meet these criteria? Electron count rules for semiconducting behavior Unit cell complexity and alloying for phonon scattering 3.Can we design nanostructures to improve Heusler TEs? Nanoscale grain sizes through ball milling and SPS Half Heusler matrix with full Heusler nanoparticles

Nanoscale grain sizes impede mid-wavelength phonons, reduce thermal conductivity, and improve ZT. Images from: X. Yan, G. Joshi, W. Liu, Y. Lan, H. Wang, S. Lee, J.W. Simonson, S.J. Poon, T.M. Tritt, G. Chen, Z.F. Ren, Enhanced thermo-electric figure of merit of p-type half-heuslers, Nano Lett. 11 (2011) Zr 0.5 Hf 0.5 CoSb 0.8 Sn 0.2

Half Heusler matrices with full Heusler nanoparticles also show reduced thermal conductivity and improved ZT. Image from: J.E. Douglas, C.S. Birkel, M-S Miao, C.J. Torbet, G.D. Stucky, T.M. Pollock, R. Seshadri, Enhanced thermoelectric properties of bulk TiNiSn via formation of a TiNi 2 Sn second phase, Appl. Phys. Lett. 101 (2012)

Half Heusler matrices with full Heusler nanoparticles also show reduced thermal conductivity and improved ZT. Image from: J.E. Douglas, C.S. Birkel, M-S Miao, C.J. Torbet, G.D. Stucky, T.M. Pollock, R. Seshadri, Enhanced thermoelectric properties of bulk TiNiSn via formation of a TiNi 2 Sn second phase, Appl. Phys. Lett. 101 (2012)

Superlattices can disrupt phonons at specifically designed wavelengths. d0d0 Z1Z1 Z2Z2 Z i Ξ acoustical impediance of layer i λ<<2d 0 λ=2d 0

Superlattices can also filter low energy electrons to improve the Seebeck coefficient. Cathode Anode

Superlattices can also filter low energy electrons to improve the Seebeck coefficient. Cathode Anode E DOS E avg EFEF

Superlattices can also filter low energy electrons to improve the Seebeck coefficient. Cathode Anode E DOS E avg EFEF E DOS E avg EFEF

High thermal conductivity still limits ZT in state-of-the-art Heulser thermoelectric compounds. MATERIAL κ [W/mK] ZT (Meas. Temp) [Ref.] TiNiSn (n-type) (740K) [1] Hf 0.5 Zr 0.5 NiSn30.9 (960 K) [2] Zr 0.25 Hf 0.25 Ti 0.5 NiSn Sb (700 K) [2] TiCoSb (p-type) (780 K) [1] ZrCoSb 0.9 Sn (958 K) [2] Zr 0.5 Hf 0.5 CoSb 0.8 Sn (1000 K) [2] SnSe (932 K) [3] Values from: [1] C.S. Birkel, W.G. Zeier, J.E. Douglas, B.R. Lettiere, C.E. Mills, G. Seward, A. Birkel, M.L. Snedaker, Y. Zhang, G.J. Snyder, T.M. Pollock, R. Seshadri, G.D. Stucky, Rapid microwave preparation of thermelectric TiNiSn and TiCoSb half-Heusler compounds, Chem. Mater. 24 (2013) [2] T.Graf, C. Fesler, S.S.P. Parkin, Simple rules for the understanding of Heusler compounds, Prog. Solid State Chem. 39 (2011) [3] L-D. Zhao, S-H Lo, Y. Zhang, H. Sun, G. Tan, C. Uher, C. Wolverton, V.P. Dravid, M.G. Kanatzidis, Ultralow thermal conductivity and high thermoelectric figure of merit in SnSe crystals, Nat. Lett. 508 (2014)