Your search keyword '"Campoy-Quiles Mariano"' showing total 7 results

1. Design Rules for Polymer Blends with High Thermoelectric Performance.

Author

Zapata‐Arteaga, Osnat, Marina, Sara, Zuo, Guangzheng, Xu, Kai, Dörling, Bernhard, Pérez, Luis Alberto, Reparaz, Juan Sebastián, Martín, Jaime, Kemerink, Martijn, and Campoy‐Quiles, Mariano

Subjects

POLYMER blends, FRONTIER orbitals, ATOMIC force microscopy, MONTE Carlo method, THERMOELECTRIC materials, DIFFERENTIAL scanning calorimetry

Abstract

A combinatorial study of the effect of in‐mixing of various guests on the thermoelectric properties of the host workhorse polymer poly[2,5‐bis(3‐tetradecylthiophen‐2‐yl)thieno[3,2‐b]thiophene] (PBTTT) is presented. Specifically, the composition and thickness for doped films of PBTTT blended with different polymers are varied. Some blends at guest weight fractions around 10–15% exhibit up to a fivefold increase in power factor compared to the reference material, leading to zT values around 0.1. Spectroscopic analysis of the charge‐transfer species, structural characterization using grazing‐incidence wide‐angle X‐ray scattering, differential scanning calorimetry, Raman, and atomic force microscopy, and Monte Carlo simulations are employed to determine that the key to improved performance is for the guest to promote long‐range electrical connectivity and low disorder, together with similar highest occupied molecular orbital levels for both materials in order to ensure electronic connectivity are combined. [ABSTRACT FROM AUTHOR]

Published

2022

2. Soluble alkali-metal carbon nanotube salts for n-type thermoelectric composites with improved stability.

Author

Dörling, Bernhard, Rodríguez-Martínez, Xabier, Álvarez-Corzo, Ivan, Reparaz, J. Sebastian, and Campoy-Quiles, Mariano

Subjects

CARBON nanotubes, SEEBECK coefficient, CROWN ethers, HIGH temperatures, ELECTRIC conductivity, SONICATION, THERMOELECTRIC generators, THERMOELECTRIC materials

Abstract

We present a method to dissolve carbon nanotubes that simultaneously allows to prepare n-doped films. These films are composed of thinner bundles of longer tubes when compared to films prepared using surfactants and sonication. Their negative Seebeck coefficient and high electrical conductivity make them good candidates for thermoelectric applications. We investigate their stability in air by aging them at elevated temperatures, showing stabilities over 500 h, which is further improved by the use of crown ethers. Finally, we demonstrate the usefulness of the prepared materials by fabricating an organic thermoelectric generator comprising 40 legs. [ABSTRACT FROM AUTHOR]

Published

2021

3. Controlling the Thermoelectric Properties of Organometallic Coordination Polymers via Ligand Design.

Author

Liu, Zilu, Liu, Tianjun, Savory, Christopher N., Jurado, José P., Reparaz, Juan Sebastián, Li, Jianwei, Pan, Long, Faul, Charl F. J., Parkin, Ivan P., Sankar, Gopinathan, Matsuishi, Satoru, Campoy‐Quiles, Mariano, Scanlon, David O., Zwijnenburg, Martijn A., Fenwick, Oliver, and Schroeder, Bob C.

Subjects

THERMOELECTRIC materials, COORDINATION polymers, ORGANOMETALLIC polymers, SEEBECK coefficient, MOLECULAR structure, RADICAL cations, ZINTL compounds

Abstract

Organometallic coordination polymers (OMCPs) are a promising class of thermoelectric materials with high electrical conductivities and thermal resistivities. The design criteria for these materials, however, remain elusive and so far material modifications have been focused primarily on the nature of the metal cation to tune the thermoelectric properties. Herein, an alternative approach is described by synthesizing new organic ligands for OMCPs, allowing modulation of the thermoelectric properties of the novel OMCP materials over several orders of magnitude, as well as controlling the polarity of the Seebeck coefficient. Extensive material purification combined with spectroscopy experiments and calculations furthermore reveal the charge‐neutral character of the polymer backbones. In the absence of counter‐cations, the OMCP backbones are composed of air‐stable, ligand‐centered radicals. The findings open up new synthetic possibilities for OMCPs by removing structural constraints and putting significant emphasis on the molecular structure of the organic ligands in OMCP materials to tune their thermoelectric properties. [ABSTRACT FROM AUTHOR]

Published

2020

4. Will organic thermoelectrics get hot?

Author

Campoy-Quiles, Mariano

Subjects

*CHARGE carrier mobility, *THERMOELECTRIC materials, *CARBON nanotubes, *CONDUCTING polymers, *COMPOSITE materials, *STEAM engines

Abstract

The generally low energy density from most heat sources—the Sun, Earth as well as most human activities—implies that solid-state thermoelectric devices are the most versatile heat harvesters since, unlike steam engines, they can be used on a small scale and at small temperature differences. In this opinion piece, we first discuss the materials requirements for the widespread use of thermoelectrics. We argue that carbon-based materials, such as conducting polymers and carbon nanotubes, are particularly suited for large area and low-temperature operation applications, as they are abundant, low-toxicity and easy to process. We combine experimentally observed macro-trends and basic thermoelectric relations to evaluate the major performance limitations of this technology thus far and propose a number of avenues to take the thermoelectric efficiency of organic materials beyond the state of the art. First, we emphasize how charge carrier mobility, rather than charge density, is currently limiting performance, and discuss how to improve mobility by exploiting anisotropy, high persistence length materials and composites with long and well-dispersed carbon nanotubes. We also show that reducing thermal conductivity could double efficiency while reducing doping requirements. Finally, we discuss several ways in which composites could further boost performance, introducing the concept of interface engineering to produce phonon stack-electron tunnel composites. This article is part of a discussion meeting issue 'Energy materials for a low carbon future'. [ABSTRACT FROM AUTHOR]

Published

2019

5. Solar Harvesting: a Unique Opportunity for Organic Thermoelectrics?

Author

Jurado, José P., Dörling, Bernhard, Zapata‐Arteaga, Osnat, Roig, Anna, Mihi, Agustín, and Campoy‐Quiles, Mariano

Subjects

THERMOELECTRIC generators, THERMOELECTRIC materials, CARBON nanotubes, HARVESTING, LIGHT sources, THERMOGRAPHY, SEEBECK coefficient

Abstract

Thermoelectrics have emerged as a strategy for solar‐to‐electricity conversion, as they can complement photovoltaic devices as IR harvesters or operate as stand‐alone systems often under strong light and heat concentration. Inspired by the recent success of inorganic‐based solar thermoelectric generators (STEGs), in this manuscript, the potential of benchmark organic thermoelectric materials for solar harvesting is evaluated. It is shown that the inherent properties of organic semiconductors allow the possibility of fabricating organic STEGs (SOTEGs) of extraordinary simplicity. The broadband light absorption exhibited by most organic thermoelectrics combined with their low thermal conductivities results in a significant temperature rise upon illumination as seen by IR thermography. Under 2 sun illumination, a temperature difference of 50 K establishes between the illuminated and the non‐illuminated sides of a poly(3,4‐ethylenedioxythiophene) polystyrene sulfonate (PEDOT:PSS) film, and ≈40 K for a carbon nanotube/cellulose composite. Moreover, when using light as a heat source, the Seebeck coefficient remains unaffected, while a small photoconductivity effect is observed in PEDOT:PSS and carbon nanotubes. Then, the effect of several geometrical factors on the power output of a solar organic thermoelectric generator is investigated, enabling us to propose simple SOTEG geometries that capitalize on the planar geometry typical of solution‐processable materials. Finally, a proof‐of‐concept SOTEG is demonstrated, generating 180 nW under 2 suns. [ABSTRACT FROM AUTHOR]

Published

2019

6. Thermoelectrics: From history, a window to the future.

Author

Beretta, Davide, Neophytou, Neophytos, Hodges, James M., Kanatzidis, Mercouri G., Narducci, Dario, Martin- Gonzalez, Marisol, Beekman, Matt, Balke, Benjamin, Cerretti, Giacomo, Tremel, Wolfgang, Zevalkink, Alexandra, Hofmann, Anna I., Müller, Christian, Dörling, Bernhard, Campoy-Quiles, Mariano, and Caironi, Mario

Subjects

*ENERGY harvesting, *THERMOELECTRIC generators, *THERMOELECTRIC materials, *TRANSPORT theory, *THERMOELECTRIC conversion, *SEEBECK effect, *NANOSTRUCTURED materials, *WASTE heat

Abstract

Thermoelectricity offers a sustainable path to recover and convert waste heat into readily available electric energy, and has been studied for more than two centuries. From the controversy between Galvani and Volta on the Animal Electricity , dating back to the end of the XVIII century and anticipating Seebeck's observations, the understanding of the physical mechanisms evolved along with the development of the technology. In the XIX century Ørsted clarified some of the earliest observations of the thermoelectric phenomenon and proposed the first thermoelectric pile, while it was only after the studies on thermodynamics by Thomson, and Rayleigh's suggestion to exploit the Seebeck effect for power generation, that a diverse set of thermoelectric generators was developed. From such pioneering endeavors, technology evolved from massive, and sometimes unreliable, thermopiles to very reliable devices for sophisticated niche applications in the XX century, when Radioisotope Thermoelectric Generators for space missions and nuclear batteries for cardiac pacemakers were introduced. While some of the materials adopted to realize the first thermoelectric generators are still investigated nowadays, novel concepts and improved understanding of materials growth, processing, and characterization developed during the last 30 years have provided new avenues for the enhancement of the thermoelectric conversion efficiency, for example through nanostructuration, and favored the development of new classes of thermoelectric materials. With increasing demand for sustainable energy conversion technologies, the latter aspect has become crucial for developing thermoelectrics based on abundant and non-toxic materials, which can be processed at economically viable scales, tailored for different ranges of temperature. This includes high temperature applications where a substantial amount of waste energy can be retrieved, as well as room temperature applications where small and local temperature differences offer the possibility of energy scavenging, as in micro harvesters meant for distributed electronics such as sensor networks. While large scale applications have yet to make it to the market, the richness of available and emerging thermoelectric technologies presents a scenario where thermoelectrics is poised to contribute to a future of sustainable future energy harvesting and management. This work reviews the broad field of thermoelectrics. Progress in thermoelectrics and milestones that led to the current state-of-the-art are presented by adopting an historical footprint. The review begins with an historical excursus on the major steps in the history of thermoelectrics, from the very early discovery to present technology. Then, the most promising thermoelectric material classes are discussed one by one in dedicated sections and subsections, carefully highlighting the technological solutions on materials growth that have represented a turning point in the research on thermoelectrics. Finally, perspectives and the future of the technology are discussed in the framework of sustainability and environmental compatibility. An appendix on the theory of thermoelectric transport in the solid state reviews the transport theory in complex crystal structures and nanostructured materials. [ABSTRACT FROM AUTHOR]

Published

2019

7. Will organic thermoelectrics get hot?

Author

Mariano Campoy-Quiles, European Research Council, Ministerio de Economía, Industria y Competitividad (España), Campoy Quiles, Mariano [0000-0002-8911-640X], and Campoy Quiles, Mariano

Subjects

Materials science, Polymers, organic thermoelectrics, General Mathematics, Carbon nanotubes, General Physics and Astronomy, doping, anisotropy, 02 engineering and technology, Carbon nanotube, 010402 general chemistry, 01 natural sciences, 7. Clean energy, law.invention, Thermal conductivity, law, Thermoelectric effect, Doping, thermal conductivity, Anisotropy, polymers, chemistry.chemical_classification, carbon nanotubes, General Engineering, Organic thermoelectrics, Articles, Polymer, 021001 nanoscience & nanotechnology, Thermoelectric materials, Engineering physics, 0104 chemical sciences, Opinion Piece, chemistry, 13. Climate action, 0210 nano-technology, Earth (classical element)

Abstract

One contribution of 13 to a discussion meeting issue ‘Energy materials for a low carbon future’., The generally low energy density from most heat sources—the Sun, Earth as well as most human activities—implies that solid-state thermoelectric devices are the most versatile heat harvesters since, unlike steam engines, they can be used on a small scale and at small temperature differences. In this opinion piece, we first discuss the materials requirements for the widespread use of thermoelectrics. We argue that carbon-based materials, such as conducting polymers and carbon nanotubes, are particularly suited for large area and low-temperature operation applications, as they are abundant, low-toxicity and easy to process. We combine experimentally observed macro-trends and basic thermoelectric relations to evaluate the major performance limitations of this technology thus far and propose a number of avenues to take the thermoelectric efficiency of organic materials beyond the state of the art. First, we emphasize how charge carrier mobility, rather than charge density, is currently limiting performance, and discuss how to improve mobility by exploiting anisotropy, high persistence length materials and composites with long and well-dispersed carbon nanotubes. We also show that reducing thermal conductivity could double efficiency while reducing doping requirements. Finally, we discuss several ways in which composites could further boost performance, introducing the concept of interface engineering to produce phonon stack-electron tunnel composites.This article is part of a discussion meeting issue ‘Energy materials for a low carbon future'., Project SEV-2015-0496 from Spanish Ministry of Economy, Industry and Competitiveness through the ‘Severo Ochoa' Programme for Centers of Excellence in R&D. European Research Council (ERC) under grant agreement no. 648901.