Title Details

Kornelius Nielsch is Professor for Experimental Physics at the Institute of Applied Physics of the University Hamburg, Germany, and coordinator of the German Priority Program of Thermoelectric Nanostructures, funded by the German Science Foundation (DFG). After his PhD obtained for a doctoral thesis carried out at Max Planck Institute of Microstructure Physics in Halle, Germany, he was postdoctoral associate at MIT, USA. From October 2003 to December 2008 he was leader of the a nanotechnology research group funded by the German Federal Ministry of Education and Research (BMBF) on Multifunctional Nanowires and Nanotubes at the Max Planck Institute in Halle. He received the State Research Prize for Basic Research from the State of Saxony-Anhalt in 2006. In the same year he was appointed Full Professor for Experimental Physics in Hamburg.

Friedemann Völklein is Director of the Institute for Microtechnologies (IMtech) and Professor for Physical Technologies and Microsystem Technology at the RheinMain University of Applied Sciences in Wiesbaden. He received both his PhD and DSc degrees in Physics from the University of Jena, Germany. He specializes in solid-state physics of thin films and their applications in thermoelectric microsensors and microactuators. Before his move to Wiesbaden, he was head of the sensor department of the Institute for Photonic Technology (IPHT) Jena and senior scientist in the Physical Electronics Laboratory of the ETH Zurich, Switzerland.

Oliver Eibl is Professor for Applied Physics at the University of Tuebingen. He spent fifteen years as researcher at Siemens Corporate Research in Munich and started his university career in Tübingen in 1999. His field of research is electron microscopy and applied materials science. He is author of more than 100 scientific papers and holds more than ten patents. He has reviewed numerous scientific papers and has acted as a referee for numerous scientific research proposals.

Nicola Peranio is Research Scientist in Professor Eibl's group at the University of Tübingen. He received his Master degree from Karlsruhe Institute of Technology and his PhD from the University of Tübingen in 2008. In 2009 he obtained the Young Investigator Award from the German Thermoelectric Society (DTG) for his PhD thesis on Bi2Te3 bulk and nanomaterials.

Preface XIII

List of Contributors XVII

Acknowledgments XXIII

1 Old and New Things in Thermoelectricity 1
Rudolf P. Huebener

1.1 ThreeThermoelectric Effects 2

1.1.1 Seebeck Effect 2

1.1.2 Peltier Effect 3

1.1.3 Thomson Effect 3

1.2 Semiconductors 4

1.3 My Entry into Thermoelectricity 6

1.4 Peltier Cascades 9

1.5 Challenge of Materials Science 9

References 10

Part I: Synthesis of Nanowires, Thin Films, and Nanostructured Bulk 11

2 Electrodeposition of Bi2Te3-Based Thin Films and Nanowires 13
William Töllner, Svenja Bäßler, Nicola Peranio, Eckhard Pippel, Oliver Eibl, and Kornelius Nielsch

2.1 Introduction 13

2.2 Fundamentals of Bi2Te3-Based Electrodeposition 14

2.3 Electrodeposition of Bi2Te3 Thin Films 16

2.4 Electrodeposition of Thermoelectric Nanowires 21

2.4.1 Electrodeposition of Bi2Te3 Nanowires 21

2.4.2 Ternary Bi2Te3-Based Nanowires 28

2.5 Conclusion 31

References 31

3 Bi2Te3 Nanowires by Electrodeposition in Polymeric Etched Ion Track Membranes: Synthesis and Characterization 33
Oliver Picht, Janina Krieg, and Maria Eugenia Toimil-Molares

3.1 Introduction 33

3.2 Synthesis of Bi2Te3 NWs with Controlled Size and Crystallography 36

3.2.1 Fabrication of Etched Ion-Track Membranes 36

3.2.1.1 Swift Heavy-Ion Irradiation 36

3.2.1.2 Chemical Etching 37

3.2.2 Electrodeposition of Bi2Te3 NWs 38

3.2.2.1 Experimental Setup 38

3.2.2.2 Electrodeposition of Bi2Te3 and Choice of the Electrolyte 40

3.2.2.3 Chronoamperometric Current–Time Curves 41

3.2.3 Morphological and Crystallographic Characterization of Bi2Te3 NWs 42

3.2.3.1 NWArrays 42

3.2.3.2 Morphology of Individual Nanowires as a Function of the Deposition Parameters 43

3.2.3.3 Adjusting the Nanowire Dimensions 44

3.2.3.4 Investigation of the Nanowire Crystallinity and Composition by TEM 45

3.2.3.5 Investigation of the Preferred Crystallographic Orientation of Wire Arrays by X-Ray Diffraction 49

3.3 Conclusions 50

References 51

4 Fabrication and Comprehensive Structural and Transport Property Characterization of Nanoalloyed Nanostructured V2VI3 Thin Film Materials 55
MarkusWinkler, Torben Dankwort, Ulrich Schürmann, Xi Liu, Jan D. König, Lorenz Kienle,Wolfgang Bensch, Harald Böttner, and Kilian Bartholomé

4.1 Situation/State of the Art before the Start of Our Combined Research Project 55

4.2 Motivation for Research on V2VI3 Multilayered Structures 56

4.2.1 BinaryThin Films 58

4.2.2 Results Obtained for SL Structures 62

4.2.3 Results Obtained from aTheoretical Analysis of V2VI3 Binaries and Nanoscale SL Structures 66

4.3 Conclusion and Outlook 67

Acknowledgments 69

References 69

5 Structure and Transport Properties of Bi2Te3 Films 73
GuoyuWang, Lynn Endicott, and Ctirad Uher

5.1 Introduction 73

5.2 Structural Aspects of the Tetradymite-type Lattice 75

5.3 MBE Film Deposition 76

5.4 Structural Characterization of Bi2Te3 Films 78

5.5 Transport Properties of Films on Sapphire Substrates 85

5.6 Conclusion 95

Acknowledgment 95

References 95

6 Bulk-Nanostructured Bi2Te3-Based Materials: Processing, Thermoelectric Properties, and Challenges 99
Vicente Pacheco, Henrik Görlitz, Nicola Peranio, Zainul Aabdin, and Oliver Eibl

6.1 Success of ZT Enhancement in Nanostructured Bulk Materials 99

6.2 Methodology at Fraunhofer IFAM-DD: Previous Research 100

6.3 High-Energy Ball Milling Technology, SPS Technology, and Thermoelectric Characterization 102

6.4 Control of Crystallite Size and Mass Density 103

6.4.1 Optimizing Ball Milling Parameters 103

6.4.2 Optimizing SPS Parameters 105

6.5 Nanostructure – Transport Properties – Correlations in Sintered Nanomaterials 106

6.5.1 Transport Properties 106

6.5.2 Nanostructure 108

6.5.3 Crystallite Size–Lattice Thermal Conductivity Correlation 110

6.5.4 Composition–Antisite Defect Density–Electric Transport Correlation 111

6.5.5 Oxidized Secondary Phases–Oxidized Matrix–Electric Transport Correlation 112

6.6 Summary and State of the Art 113

6.7 Outlook Second Generation SPS Prepared Nanomaterials 114

References 115

Part II: Structure, Excitation, and Dynamics 119

7 High Energy X-ray and Neutron Scattering on Bi2Te3 Nanowires, Nanocomposites, and BulkMaterials 121
Benedikt Klobes, Dimitrios Bessas, and Raphaël P. Hermann

7.1 Introduction 121

7.2 Review of Published High-Energy X-ray and Neutron Scattering Studies on Bi2Te3 and Related Compounds 122

7.3 Element Specific Lattice Dynamics in Bulk Bi2Te3 and Sb2Te3 125

7.4 Nanostructure and Phonons in a Bi2Te3 Nanowire Array 130

7.5 Nanocomposites and Speed of Sound 134

7.6 Perspectives of High-Energy X-ray and Neutron Scattering 136

Acknowledgments 136

References 137

8 Advanced Structural Characterization of Bi2Te3 Nanomaterials 141
Nicola Peranio, Zainul Aabdin,Michael Dürrschnabel, and Oliver Eibl

8.1 From Bulk to Nanomaterials 141

8.2 Synthesis of Nanomaterials and Transport Measurements 142

8.3 Relevance of Advanced Microscopy and Spectroscopy for Bi2Te3 Nanomaterials 143

8.4 Nanostructure–Property Relations in Bulk and Nanomaterials 147

8.4.1 Chemical Modulations and Structural Disorder in Commercial Bulk Materials 147

8.4.2 Near Stoichiometric, Single Crystalline Nanowires for Transport in the Basal Plane 150

8.4.3 Epitaxial and Nano-alloyedThin Films with Low Charge Carrier Densities and High Power Factors 152

8.4.4 Highly Dense, Ultra-fine Nanostructured Bulk with Low Thermal Conductivities 153

8.5 Simulation of Electron Transport and Electron Scattering in Bi2Te3-Based Materials 155

8.5.1 Calculation of Electronic Transport Coefficients 156

8.5.2 Calculation of High-Energy Electron Scattering in Bi2Te3-Based Materials 158

8.6 Experimental Techniques and Simulation 161

References 161

Part III: Theory and Modeling 165

9 Density-Functional Theory Study of Point Defects in Bi2Te3 167
Adham Hashibon and Christian Elsässer

9.1 Introduction 167

9.2 Thermoelectric Properties 168

9.3 The Lattice Structure of Bi2Te3 173

9.4 Point Defects in Bi2Te3-Related Materials 174

9.5 Concentration of Point Defects 177

9.6 Calculation of Formation Energies from First Principles 178

9.7 Recent DFT Results for the Point Defect Energies in Bi2Te3 180

9.8 Summary and Outlook 183

Acknowledgments 184

References 184

10 Ab Initio Description of Thermoelectric Properties Based on the Boltzmann Theory 187
Nicki F. Hinsche, Martin Hölzer, Arthur Ernst, Ingrid Mertig, and Peter Zahn

10.1 Introduction 187

10.1.1 Low-Dimensional Thermoelectrics 188

10.1.2 Phonon-Glass Electron-Crystal 189

10.1.3 Phonon-Blocking and Electron-Transmitting Superlattices 191

10.2 Transport Theory 193

10.2.1 Linearized Boltzmann Equation and Relaxation Time Approximation 193

10.2.2 Transport Coefficients 194

10.3 Results 197

10.3.1 Influence of Strain 197

10.3.2 Superlattices 203

10.3.3 Thermal Conductivity - Toward the Figure of Merit 206

10.3.4 Lorenz Function of Superlattices 208

10.3.5 Phonons 211

10.4 Summary 213

References 214

Part IV: Transport PropertiesMeasurement Techniques 223

11 Measuring Techniques for Thermal Conductivity and Thermoelectric Figure of Merit of V–VI Compound Thin Films and Nanowires 225
F. Völklein, H. Reith, A. Meier, and M. Schmitt

11.1 Introduction 225

11.2 Methods for the Investigation of the In-plane Thermal Conductivity of Thin Films 227

11.2.1 Steady-State Joule Heating Method for Determining the Thermal Conductivity and Emissivity of Electrically Conducting Films 227

11.2.2 Microfabricated λ-Chips for Measurements of In-Plane Thermal Conductivity 230

11.2.3 The λ-Chips for Transient Measurements of the In-Plane Thermal Conductivity and the Specific Heat Capacity of Thin Films 235

11.3 Steady-State Measurements of the Cross-PlaneThermal Conductivity of Thin Films 236

11.4 Investigation of Cross-PlaneThermal Conductivity of Nanowire Arrays 243

11.5 Characterization ofThermal Conductivity and Thermoelectric Figure of Merit of Single Nanowires 245

11.5.1 Design of the z-Chip 245

11.5.2 Electrical Conductivity Measurement 248

11.5.3 Thermopower Measurements 248

11.5.4 Thermal Conductivity Measurement 250

Acknowledgments 251

References 251

12 Development of a Thermoelectric Nanowire Characterization Platform (TNCP) for Structural and Thermoelectric Investigation of Single Nanowires 253
ZhiWang, S. Hoda Moosavi,Michael Kroener, and PeterWoias

12.1 Introduction 253

12.2 TNCP Initial Design 256

12.3 First and Second Generations of TNCP 257

12.3.1 Design, Modeling, and Simulation 257

12.3.2 Design Improvements and New Characteristics for the Second Generation Chip Design 259

12.3.3 Fabrication 262

12.4 Nanowire Assembly Utilizing Dielectrophoresis 264

12.4.1 Theory 264

12.4.2 Experimental Details 267

12.4.2.1 Liquid Medium Selection 267

12.4.2.2 Nanowire Assembly Process 267

12.4.2.3 Acceleration ofWater Droplet Evaporation 269

12.4.2.4 Recognition of Properly Assembled Nanowires 269

12.4.2.5 Results and Discussion 270

12.5 Ohmic Contact Generation 271

12.5.1 SEM Electron Beam Induced Deposition (EBID) 271

12.5.2 Shadow Mask Techniques 275

12.5.2.1 Design and Fabrication 275

12.5.2.2 Experimental Process 277

12.6 Summary and Outlook 277

References 279

Appendix 283

Index 287