Multifunctional structural design of graphene thermoelectrics by Bayesian optimization

Efficient multifunctional materials informatics enables the design of optimal graphene thermoelectrics. Materials development often confronts a dilemma as it needs to satisfy multifunctional, often conflicting, demands. For example, thermoelectric conversion requires high electrical conductivity, a high Seebeck coefficient, and low thermal conductivity, despite the fact that these three properties are normally closely correlated. Nanostructuring techniques have been shown to break the correlations to some extent; however, optimal design has been a major challenge due to the extraordinarily large degrees of freedom in the structures. By taking graphene nanoribbons (GNRs) as a representative thermoelectric material, we carried out structural optimization by alternating multifunctional (phonon and electron) transport calculations and Bayesian optimization to resolve the trade-off. As a result, we have achieved multifunctional structural optimization with an efficiency more than five times that achieved by random search. The obtained GNRs with optimized antidots significantly enhance the thermoelectric figure of merit by up to 11 times that of the pristine GNR. Knowledge of the optimal structure further provides new physical insights that independent tuning of electron and phonon transport properties can be realized by making use of zigzag edge states and aperiodic nanostructuring. The demonstrated optimization framework is also useful for other multifunctional problems in various applications.

[1]  Takahiro Yamamoto,et al.  Edge‐disorder‐induced optimization of thermoelectric performance of finite‐length graphene nanoribbons , 2016 .

[2]  P. Dollfus,et al.  Thermoelectric effects in graphene nanostructures , 2015, Journal of physics. Condensed matter : an Institute of Physics journal.

[3]  Taylor D. Sparks,et al.  Perspective: Web-based machine learning models for real-time screening of thermoelectric materials properties , 2016 .

[4]  Yukinori Koyama,et al.  Accelerated discovery of cathode materials with prolonged cycle life for lithium-ion battery , 2014, Nature Communications.

[5]  P. Dollfus,et al.  Enhanced thermoelectric properties in graphene nanoribbons by resonant tunneling of electrons , 2011 .

[6]  Xingao Gong,et al.  Thermal conductivity of graphene nanoribbons , 2009 .

[7]  Atsuto Seko,et al.  Prediction of Low-Thermal-Conductivity Compounds with First-Principles Anharmonic Lattice-Dynamics Calculations and Bayesian Optimization. , 2015, Physical review letters.

[8]  Junichiro Shiomi,et al.  Crystalline-Amorphous Silicon Nanocomposites with Reduced Thermal Conductivity for Bulk Thermoelectrics. , 2015, ACS applied materials & interfaces.

[9]  Yoyo Hinuma,et al.  Discovery of earth-abundant nitride semiconductors by computational screening and high-pressure synthesis , 2016, Nature Communications.

[10]  Nonequilibrium Green's function approach to phonon transport in defective carbon nanotubes. , 2006, Physical review letters.

[11]  J. Meyer,et al.  Nanopore fabrication and characterization by helium ion microscopy , 2016, 1805.00292.

[12]  M. Dresselhaus,et al.  Diameter dependence of thermoelectric power of semiconducting carbon nanotubes , 2015, 1508.05727.

[13]  H. Kataura,et al.  Giant Seebeck coefficient in semiconducting single-wall carbon nanotube film , 2014, 1401.7469.

[14]  H. Miura,et al.  Effects of uniaxial compressive strain on the electronic-transport properties of zigzag carbon nanotubes , 2016, Nano Research.

[15]  Koji Tsuda,et al.  Acceleration of stable interface structure searching using a kriging approach , 2016 .

[16]  Dong Hyun Lee,et al.  Holey silicon as an efficient thermoelectric material. , 2010, Nano letters.

[17]  Y. Kivshar,et al.  Superscattering of light optimized by a genetic algorithm , 2014 .

[18]  Junichiro Shiomi,et al.  Designing Nanostructures for Phonon Transport via Bayesian Optimization , 2016, 1609.04972.

[19]  J. Nakamura,et al.  Anomalous enhancement of Seebeck coefficients of the graphene/hexagonal boron nitride composites , 2016 .

[20]  S. Cronin,et al.  Experimental proof-of-principle investigation of enhanced Z 3 DT in „ 001 ... oriented Si Õ Ge superlattices , 2000 .

[21]  X. Duan,et al.  Graphene nanomesh , 2010, Nature nanotechnology.

[22]  Zhifeng Ren,et al.  Coherent Phonon Heat Conduction in Superlattices , 2012, Science.

[23]  Avram Bar-Cohen,et al.  Nanothermal Interface Materials: Technology Review and Recent Results , 2015 .

[24]  S. Datta Nanoscale device modeling: the Green’s function method , 2000 .

[25]  Kai Nordlund,et al.  Analytical interatomic potential for modeling nonequilibrium processes in the W–C–H system , 2005 .

[26]  Alexander Tropsha,et al.  Materials Informatics , 2019, J. Chem. Inf. Model..

[27]  Taylor D. Sparks,et al.  High-Throughput Machine-Learning-Driven Synthesis of Full-Heusler Compounds , 2016 .

[28]  M. Buongiorno Nardelli,et al.  Thermoelectric properties of graphene nanoribbons, junctions and superlattices , 2010, Journal of physics. Condensed matter : an Institute of Physics journal.

[29]  Jing Guo,et al.  A theoretical study on thermoelectric properties of graphene nanoribbons , 2009 .

[30]  M. Dresselhaus,et al.  New Directions for Low‐Dimensional Thermoelectric Materials , 2007 .

[31]  Shin Kiyohara,et al.  Prediction of interface structures and energies via virtual screening , 2016, Science Advances.

[32]  D. A. Broido,et al.  Optimized Tersoff and Brenner empirical potential parameters for lattice dynamics and phonon thermal transport in carbon nanotubes and graphene , 2010 .

[33]  Shin Kiyohara,et al.  Prediction of grain boundary structure and energy by machine learning , 2015 .

[34]  Fujita,et al.  Edge state in graphene ribbons: Nanometer size effect and edge shape dependence. , 1996, Physical review. B, Condensed matter.

[35]  L. Esaki,et al.  Tunneling in a finite superlattice , 1973 .

[36]  H. Sevinçli,et al.  Enhanced thermoelectric figure of merit in edge-disordered zigzag graphene nanoribbons , 2009, 0908.3207.

[37]  K. Esfarjani,et al.  Green's function studies of phonon transport across Si/Ge superlattices , 2014 .

[38]  Efstratios Skafidas,et al.  High Performance Graphene Nano-ribbon Thermoelectric Devices by Incorporation and Dimensional Tuning of Nanopores , 2015, Scientific Reports.

[39]  H Zhao,et al.  Thermoelectric properties of one-dimensional graphene antidot arrays , 2012 .

[40]  P. Dollfus,et al.  Thermoelectric performance of disordered and nanostructured graphene ribbons using Green’s function method , 2012 .

[41]  C. T. White,et al.  Room-temperature ballistic transport in narrow graphene strips , 2006, cond-mat/0606693.

[42]  Richard G. Blair,et al.  Nanostructured Bulk Silicon as an Effective Thermoelectric Material , 2009 .

[43]  D. Brenner,et al.  Empirical potential for hydrocarbons for use in simulating the chemical vapor deposition of diamond films. , 1990, Physical review. B, Condensed matter.

[44]  Austin J. Minnich,et al.  The best nanoparticle size distribution for minimum thermal conductivity , 2014, Scientific Reports.

[45]  Corey Oses,et al.  High-Throughput Computation of Thermal Conductivity of High-Temperature Solid Phases: The Case of Oxide and Fluoride Perovskites , 2016, 1606.03279.

[46]  Jimmy Ba,et al.  Adam: A Method for Stochastic Optimization , 2014, ICLR.

[47]  J. Freund,et al.  Lattice-dynamical calculation of phonon scattering at ideal Si–Ge interfaces , 2005 .

[48]  Atsuto Seko,et al.  Representation of compounds for machine-learning prediction of physical properties , 2016, 1611.08645.

[49]  D. Muller,et al.  Crossover from incoherent to coherent phonon scattering in epitaxial oxide superlattices. , 2014, Nature materials.

[50]  Lihong Li,et al.  An Empirical Evaluation of Thompson Sampling , 2011, NIPS.

[51]  N. M. R. Peres,et al.  Tight-binding approach to uniaxial strain in graphene , 2008, 0811.4396.

[52]  Koji Miyazaki,et al.  Enhanced figure of merit of a porous thin film of bismuth antimony telluride , 2011 .

[53]  J. Shiomi Research Update: Phonon engineering of nanocrystalline silicon thermoelectrics , 2016 .

[54]  Takeshi Saito,et al.  From materials to device design of a thermoelectric fabric for wearable energy harvesters , 2017 .

[55]  Y. Imry,et al.  Multichannel Landauer formula for thermoelectric transport with application to thermopower near the mobility edge. , 1986, Physical review. B, Condensed matter.

[56]  Atta,et al.  Nanoscale device modeling: the Green’s function method , 2000 .

[57]  M. Dresselhaus,et al.  Experimental proof-of-principle investigation of enhanced Z[sub 3D]T in (001) oriented Si/Ge superlattices , 2000 .

[58]  Xiaoning Qian,et al.  Accelerated search for BaTiO3-based piezoelectrics with vertical morphotropic phase boundary using Bayesian learning , 2016, Proceedings of the National Academy of Sciences.

[59]  H. Miura,et al.  Electronic properties and strain sensitivity of CVD-grown graphene with acetylene , 2016 .

[60]  P. Anderson Absence of Diffusion in Certain Random Lattices , 1958 .

[61]  A. McGaughey,et al.  Orientational order controls crystalline and amorphous thermal transport in superatomic crystals. , 2017, Nature materials.

[62]  Koji Tsuda,et al.  COMBO: An efficient Bayesian optimization library for materials science , 2016 .

[63]  Bryce Meredig,et al.  A recommendation engine for suggesting unexpected thermoelectric chemistries , 2015, 1502.07635.

[64]  Phillip B. Messersmith,et al.  Bioinspired antifouling polymers , 2005 .

[65]  Benjamin Recht,et al.  Random Features for Large-Scale Kernel Machines , 2007, NIPS.

[66]  H. Mizuta,et al.  Sub-10nm patterning by focused He-ion beam milling for fabrication of downscaled graphene nano devices , 2014 .

[67]  J. Shiomi,et al.  Diffusive-Ballistic Heat Conduction of Carbon Nanotubes and Nanographene Ribbons , 2010 .

[68]  K. Goodson,et al.  Modulation of thermal and thermoelectric transport in individual carbon nanotubes by fullerene encapsulation. , 2017, Nature materials.

[69]  Andre K. Geim,et al.  Electric Field Effect in Atomically Thin Carbon Films , 2004, Science.

[70]  Stefano Curtarolo,et al.  Finding Unprecedentedly Low-Thermal-Conductivity Half-Heusler Semiconductors via High-Throughput Materials Modeling , 2014, 1401.2439.

[71]  B. Gutiérrez-Medina Wave transmission through periodic, quasiperiodic, and random one-dimensional finite lattices , 2013 .

[72]  M. P. Walsh,et al.  Quantum Dot Superlattice Thermoelectric Materials and Devices , 2002, Science.

[73]  G. Fudenberg,et al.  Ultrahigh electron mobility in suspended graphene , 2008, 0802.2389.

[74]  Samuel Brunner,et al.  Mechanical properties of monolithic silica aerogels made from polyethoxydisiloxanes , 2014 .

[75]  Koji Tsuda,et al.  MDTS: automatic complex materials design using Monte Carlo tree search , 2017, Science and technology of advanced materials.

[76]  K. Kusakabe,et al.  Peculiar Localized State at Zigzag Graphite Edge , 1996 .

[77]  Seifert,et al.  Construction of tight-binding-like potentials on the basis of density-functional theory: Application to carbon. , 1995, Physical review. B, Condensed matter.

[78]  J. Bahk,et al.  Flexible thermoelectric materials and device optimization for wearable energy harvesting , 2015 .

[79]  H. Sevinçli,et al.  Control of thermal and electronic transport in defect-engineered graphene nanoribbons. , 2011, ACS nano.