Scalable synthesis of n-type Mg3Sb2-xBix for thermoelectric applications

[1]  Gang Chen,et al.  Thermoelectric cooling materials , 2020, Nature Materials.

[2]  Z. Ren,et al.  N-type Mg3Sb2-Bi with improved thermal stability for thermoelectric power generation , 2020 .

[3]  Z. Ren,et al.  N-Type Mg3Sb2-xBix Alloys as Promising Thermoelectric Materials , 2020, Research.

[4]  Xinbing Zhao,et al.  High-Performance Mg3Sb2-xBix Thermoelectrics: Progress and Perspective , 2020, Research.

[5]  Liming Wu,et al.  Point defect engineering and machinability in n-type Mg3Sb2-based materials , 2020 .

[6]  G. J. Snyder,et al.  Mg3(Bi,Sb)2 single crystals towards high thermoelectric performance , 2020, Energy & Environmental Science.

[7]  Z. Ren,et al.  A double four-point probe method for reliable measurement of energy conversion efficiency of thermoelectric materials , 2020 .

[8]  E. Müller,et al.  High efficiency Mg2(Si,Sn)-based thermoelectric materials: scale-up synthesis, functional homogeneity, and thermal stability , 2019, RSC advances.

[9]  Gang Chen,et al.  High thermoelectric cooling performance of n-type Mg3Bi2-based materials , 2019, Science.

[10]  B. Iversen,et al.  Insights into the design of thermoelectric Mg3Sb2 and its analogs by combining theory and experiment , 2019, npj Computational Materials.

[11]  Anubhav Jain,et al.  Revelation of Inherently High Mobility Enables Mg3Sb2 as a Sustainable Alternative to n‐Bi2Te3 Thermoelectrics , 2019, Advanced science.

[12]  G. J. Snyder,et al.  Improvement of Low‐Temperature zT in a Mg3Sb2–Mg3Bi2 Solid Solution via Mg‐Vapor Annealing , 2019, Advanced materials.

[13]  Xin Li,et al.  Achieving band convergence by tuning the bonding ionicity in n‐type Mg3Sb2 , 2019, J. Comput. Chem..

[14]  G. J. Snyder,et al.  Exceptional thermoelectric performance in Mg3Sb0.6Bi1.4 for low-grade waste heat recovery , 2019, Energy & Environmental Science.

[15]  Stephen D. Wilson,et al.  Joint effect of magnesium and yttrium on enhancing thermoelectric properties of n-type Zintl Mg3+Y0.02Sb1.5Bi0.5 , 2019, Materials Today Physics.

[16]  Z. Ren,et al.  Realizing high conversion efficiency of Mg3Sb2-based thermoelectric materials , 2019, Journal of Power Sources.

[17]  Y. Liu,et al.  Mg3+δSbxBi2−x Family: A Promising Substitute for the State‐of‐the‐Art n‐Type Thermoelectric Materials near Room Temperature , 2018, Advanced Functional Materials.

[18]  Yue Chen,et al.  Extraordinary thermoelectric performance in n-type manganese doped Mg3Sb2 Zintl: High band degeneracy, tuned carrier scattering mechanism and hierarchical microstructure , 2018, Nano Energy.

[19]  B. Iversen,et al.  Thermal stability of Mg3Sb1.475Bi0.475Te0.05 high performance n-type thermoelectric investigated through powder X-ray diffraction and pair distribution function analysis , 2018 .

[20]  Wen Li,et al.  Advances in Thermoelectric Mg3Sb2and Its Derivatives , 2018, Small Methods.

[21]  Jun Mao,et al.  Discovery of ZrCoBi based half Heuslers with high thermoelectric conversion efficiency , 2018, Nature Communications.

[22]  B. Iversen,et al.  New Insight on Tuning Electrical Transport Properties via Chalcogen Doping in n‐type Mg3Sb2‐Based Thermoelectric Materials , 2018 .

[23]  Gang Chen,et al.  Advances in thermoelectrics , 2018 .

[24]  G. J. Snyder,et al.  Grain boundary dominated charge transport in Mg3Sb2-based compounds , 2018 .

[25]  Z. Ren,et al.  Significant Role of Mg Stoichiometry in Designing High Thermoelectric Performance for Mg3(Sb,Bi)2-Based n-Type Zintls. , 2018, Journal of the American Chemical Society.

[26]  G. J. Snyder,et al.  Improving the thermoelectric performance in Mg3+xSb1.5Bi0.49Te0.01 by reducing excess Mg , 2018 .

[27]  G. J. Snyder,et al.  Enhancement of average thermoelectric figure of merit by increasing the grain-size of Mg3.2Sb1.5Bi0.49Te0.01 , 2018 .

[28]  Z. Ren,et al.  Anomalous electrical conductivity of n-type Te-doped Mg3.2Sb1.5Bi0.5 , 2017 .

[29]  Eric S. Toberer,et al.  Phase Boundary Mapping to Obtain n-type Mg3Sb2-Based Thermoelectrics , 2017 .

[30]  Terry M. Tritt,et al.  Advances in thermoelectric materials research: Looking back and moving forward , 2017, Science.

[31]  Jun Mao,et al.  Defect Engineering for Realizing High Thermoelectric Performance in n-Type Mg3Sb2-Based Materials , 2017 .

[32]  Jun Mao,et al.  Manipulation of ionized impurity scattering for achieving high thermoelectric performance in n-type Mg3Sb2-based materials , 2017, Proceedings of the National Academy of Sciences.

[33]  B. Iversen,et al.  High-Performance Low-Cost n-Type Se-Doped Mg3Sb2-Based Zintl Compounds for Thermoelectric Application , 2017 .

[34]  Liu Yong,et al.  New trends, strategies and opportunities in thermoelectric materials: A perspective , 2017 .

[35]  Gang Chen,et al.  Recent progress and future challenges on thermoelectric Zintl materials , 2017 .

[36]  Jun Mao,et al.  Tuning the carrier scattering mechanism to effectively improve the thermoelectric properties , 2017 .

[37]  Hee Seok Kim,et al.  The bridge between the materials and devices of thermoelectric power generators , 2017 .

[38]  B. Iversen,et al.  Discovery of high-performance low-cost n-type Mg3Sb2-based thermoelectric materials with multi-valley conduction bands , 2017, Nature Communications.

[39]  T. Kanno,et al.  Isotropic Conduction Network and Defect Chemistry in Mg3+δSb2‐Based Layered Zintl Compounds with High Thermoelectric Performance , 2016, Advanced materials.

[40]  M. Kanatzidis,et al.  Toward High‐Thermoelectric‐Performance Large‐Size Nanostructured BiSbTe Alloys via Optimization of Sintering‐Temperature Distribution , 2016 .

[41]  Zhifeng Ren,et al.  Relationship between thermoelectric figure of merit and energy conversion efficiency , 2015, Proceedings of the National Academy of Sciences.

[42]  Gang Chen,et al.  Understanding of the contact of nanostructured thermoelectric n-type Bi2Te2.7Se0.3 legs for power generation applications , 2013 .

[43]  Mildred S Dresselhaus,et al.  When thermoelectrics reached the nanoscale. , 2013, Nature nanotechnology.

[44]  G. J. Snyder,et al.  Thermoelectric property studies on thallium-doped lead telluride prepared by ball milling and hot pressing , 2010 .

[45]  Zhifeng Ren,et al.  Enhancement of Thermoelectric Figure‐of‐Merit by a Bulk Nanostructuring Approach , 2010 .

[46]  L. Bell Cooling, Heating, Generating Power, and Recovering Waste Heat with Thermoelectric Systems , 2008, Science.

[47]  Gang Chen,et al.  Enhanced thermoelectric figure-of-merit in p-type nanostructured bismuth antimony tellurium alloys made from elemental chunks. , 2008, Nano letters.

[48]  M. Dresselhaus,et al.  High-Thermoelectric Performance of Nanostructured Bismuth Antimony Telluride Bulk Alloys , 2008, Science.

[49]  G. J. Snyder,et al.  Complex thermoelectric materials. , 2008, Nature materials.

[50]  F. Disalvo,et al.  Thermoelectric cooling and power generation , 1999, Science.

[51]  A. Al-Azzawi,et al.  Mechanical Alloying and Milling , 2015 .

[52]  E. Lavernia,et al.  Synthesis and mechanical behavior of nanostructured materials via cryomilling , 2006 .