Your search keyword '"Crispin, Xavier"' showing total 13 results

1. Elastic conducting polymer composites in thermoelectric modules.

Author

Kim, Nara, Lienemann, Samuel, Petsagkourakis, Ioannis, Alemu Mengistie, Desalegn, Kee, Seyoung, Ederth, Thomas, Gueskine, Viktor, Leclère, Philippe, Lazzaroni, Roberto, Crispin, Xavier, and Tybrandt, Klas

Subjects

CONDUCTING polymer composites, WEARABLE technology, ENERGY harvesting, THERMOELECTRIC materials, THERMOELECTRIC generators, POLYMERIZED ionic liquids, THERMOPLASTIC elastomers

Abstract

The rapid growth of wearables has created a demand for lightweight, elastic and conformal energy harvesting and storage devices. The conducting polymer poly(3,4-ethylenedioxythiophene) has shown great promise for thermoelectric generators, however, the thick layers of pristine poly(3,4-ethylenedioxythiophene) required for effective energy harvesting are too hard and brittle for seamless integration into wearables. Poly(3,4-ethylenedioxythiophene)-elastomer composites have been developed to improve its mechanical properties, although so far without simultaneously achieving softness, high electrical conductivity, and stretchability. Here we report an aqueously processed poly(3,4-ethylenedioxythiophene)-polyurethane-ionic liquid composite, which combines high conductivity (>140 S cm−1) with superior stretchability (>600%), elasticity, and low Young's modulus (<7 MPa). The outstanding performance of this organic nanocomposite is the result of favorable percolation networks on the nano- and micro-scale and the plasticizing effect of the ionic liquid. The elastic thermoelectric material is implemented in the first reported intrinsically stretchable organic thermoelectric module. Though deformable thermoelectric materials are desirable for integrating thermoelectric devices into wearable electronics, typical thermoelectric materials are too brittle for practical application. Here, the authors report a high-performance elastic composite for stretchable thermoelectric modules. [ABSTRACT FROM AUTHOR]

Published

2020

2. Thermoelectric Properties of Flexible PEDOT/PU and PEDOT/PVDF Films.

Author

Karakurt, Nuri, Petsagkourakis, Ioannis, Kim, Nara, Tybrandt, Klas, Crispin, Xavier, Kimmer, Dusan, and Slobodian, Petr

Subjects

THERMOELECTRIC power, THERMOELECTRIC materials, ATOMIC force microscopy, SEEBECK coefficient, POLYVINYLIDENE fluoride, POLYURETHANES, SCIENTIFIC community

Abstract

The growing energy demands for wearable electronic devices has shifted the attention of scientific community towards flexible thermoelectric materials and devices; the main goal being the enhancement of the thermoelectric and conducting properties of such systems, without sacrificing their flexibility. This paper reports the enhancement of the thermoelectric properties of flexible Poly(3,4-ethylenedioxythiophene), (PEDOT), films with acid (HCl) exposure. Relative high conductive, flexible and uniform PEDOT/polyurethane(PU) and (PEDOT)/polyvinylidene fluoride (PVDF) films were prepared, separately. The films were dipped into acid solution with the exposure time of 5, 10, and 15 min. The sheet resistance (Ω/sq), electrical conductivity (σ), Seebeck coefficient (S) and thermoelectric power factor (σS²) were measured for those systems. The thermoelectric behavior of both films was optimized with different exposure times in acid solution, while the thermoelectric properties of the PEDOT/PVDF films remained unchanged with this treatment. The Seebeck coefficient and thermoelectric power of PEDOT/PU enhanced from 9.01 to 12.6 μV/K and from 7.4×10–2 to 12.2×10–2 μW/mK², respectively for a 10 min exposure. The origin of this enhancement was tracked down to modifications in the surface morphology of the films, identified through AFM microscopy. The presented results indicate that acid treatment is a potential and promising approach to enhance the thermoelectric properties of PEDOT/PU films for flexible, conformable and low-cost TE applications. [ABSTRACT FROM AUTHOR]

Published

2019

3. Thermoelectric materials and applications for energy harvesting power generation.

Author

Petsagkourakis, Ioannis, Tybrandt, Klas, Crispin, Xavier, Ohkubo, Isao, Satoh, Norifusa, and Mori, Takao

Subjects

ENERGY harvesting, HEAT, THERMOELECTRIC materials

Abstract

Thermoelectrics, in particular solid-state conversion of heat to electricity, is expected to be a key energy harvesting technology to power ubiquitous sensors and wearable devices in the future. A comprehensive review is given on the principles and advances in the development of thermoelectric materials suitable for energy harvesting power generation, ranging from organic and hybrid organic-inorganic to inorganic materials. Examples of design and applications are also presented. [ABSTRACT FROM AUTHOR]

Published

2018

4. Thermoelectric Polymer Aerogels for Pressure-Temperature Sensing Applications.

Author

Han, Shaobo, Jiao, Fei, Khan, Zia Ullah, Edberg, Jesper, Fabiano, Simone, and Crispin, Xavier

Subjects

THERMOELECTRIC materials, POLYMERS, DETECTORS, MICROELECTROMECHANICAL systems, THIN film transistors

Abstract

The evolution of the society is characterized by an increasing flow of information from things to the internet. Sensors have become the cornerstone of the internet-of-everything as they track various parameters in the society and send them to the cloud for analysis, forecast, or learning. With the many parameters to sense, sensors are becoming complex and difficult to manufacture. To reduce the complexity of manufacturing, one can instead create advanced functional materials that react to multiple stimuli. To this end, conducting polymer aerogels are promising materials as they combine elasticity and sensitivity to pressure and temperature. However, the challenge is to read independently pressure and temperature output signals without cross-talk. Here, a strategy to fully decouple temperature and pressure reading in a dual-parameter sensor based on thermoelectric polymer aerogels is demonstrated. It is found that aerogels made of poly(3,4-ethylenedioxythiophene):poly(styrene sulfonate) (PEDOT:PSS) can display properties of semiconductors lying at the transition between insulator and semimetal upon exposure to high boiling point polar solvents, such as dimethylsulfoxide (DMSO). Importantly, because of the temperature-independent charge transport observed for DMSO-treated PEDOT-based aerogel, a decoupled pressure and temperature sensing can be achieved without cross-talk in the dual-parameter sensor devices. [ABSTRACT FROM AUTHOR]

Published

2017

5. Ionic Thermoelectric Figure of Merit for Charging of Supercapacitors.

Author

Wang, Hui, Zhao, Dan, Khan, Zia Ulla, Puzinas, Skomantas, Jonsson, Magnus P., Berggren, Magnus, and Crispin, Xavier

Subjects

THERMOELECTRIC materials, SUPERCAPACITORS, POLYELECTROLYTES, ELECTRICAL energy, THERMAL conductivity, THERMOELECTRIC generators

Abstract

Thermoelectric materials enable conversion of heat to electrical energy. The performance of electronic thermoelectric materials is typically evaluated using a figure of merit ZT = σα2T/λ, where σ is the conductivity, α is the so‐called Seebeck coefficient, and λ is the thermal conductivity. However, it has been unclear how to best evaluate the performance of ionic thermoelectric materials, like ionic solids and electrolytes. These systems cannot be directly used in a traditional thermoelectric generator, because they are based on ions that cannot pass the interface between the thermoelectric material and external metal electrodes. Instead, energy can be harvested from the ionic thermoelectric effect by charging a supercapacitor. In this study, the authors investigate the ionic thermoelectric properties at varied relative humidity for the polyelectrolyte polystyrene sulfonate sodium and correlate these properties with the charging efficiency when used in an ionic thermoelectric supercapacitor (ITESC). In analogy with electronic thermoelectric generators, the results show that the charging efficiency of the ITESC can be quantitatively related to the figure of merit ZTi = σiαi2T/λ. This means that the performance of ionic thermoelectric materials can also be compared and predicted based on the ZT, which will be highly valuable in the design of high‐performance ITESCs. [ABSTRACT FROM AUTHOR]

Published

2017

6. Ionic Seebeck Effect in Conducting Polymers.

Author

Wang, Hui, Ail, Ujwala, Gabrielsson, Roger, Berggren, Magnus, and Crispin, Xavier

Subjects

CONDUCTING polymers, THERMOELECTRIC effects, ELECTROACTIVE substances, ORGANIC conductors, POLYSTYRENE

Abstract

Conducting polymers display an ionic thermoelectric effect in addition to the known electronic thermoelectric effect. Their Seebeck coefficient is as large as ≈200 μV K−1. This finding discloses a new possible approach to improve the thermoelectric properties of conducting polymers by combining various types of charge carriers of the same sign. [ABSTRACT FROM AUTHOR]

Published

2015

7. Solar Heat‐Enhanced Energy Conversion in Devices Based on Photosynthetic Membranes and PEDOT:PSS‐Nanocellulose Electrodes.

Author

Méhes, Gábor, Vagin, Mikhail, Mulla, Mohammad Yusuf, Granberg, Hjalmar, Che, Canyan, Beni, Valerio, Crispin, Xavier, Berggren, Magnus, Stavrinidou, Eleni, and Simon, Daniel T.

Subjects

SOLAR energy conversion, ENERGY harvesting, INFRARED absorption, CONDUCTING polymer composites, POLYMER electrodes, ENERGY conversion, THERMOELECTRIC materials

Abstract

Energy harvesting from photosynthetic membranes, proteins, or bacteria through bio‐photovoltaic or bio‐electrochemical approaches has been proposed as a new route to clean energy. A major shortcoming of these and solar cell technologies is the underutilization of solar irradiation wavelengths in the IR region, especially those in the far IR region. Here, a biohybrid energy‐harvesting device is demonstrated that exploits IR radiation, via convection and thermoelectric effects, to improve the resulting energy conversion performance. A composite of nanocellulose and the conducting polymer system poly(3,4‐ethylenedioxythiophene):polystyrene sulfonate (PEDOT:PSS) is used as the anode in biohybrid cells that includes thylakoid membranes (TMs) and redox mediators (RMs) in solution. By irradiating the conducting polymer electrode by an IR light‐emitting diode, a sixfold enhancement in the harvested bio‐photovoltaic power is achieved, without compromising stability of operation. Investigation of the output currents reveals that IR irradiation generates convective heat transfer in the electrolyte bulk, which enhances the redox reactions of RMs at the anode by suppressing diffusion limitations. In addition, a fast‐transient thermoelectric component, originating from the PEDOT:PSS‐nanocellulose‐electrolyte interphase, further increases the bio‐photocurrent. These results pave the way for the development of energy‐harvesting biohybrids that make use of heat, via IR absorption, to enhance energy conversion efficiency. [ABSTRACT FROM AUTHOR]

Published

2020

8. Thermodiffusion‐Assisted Pyroelectrics—Enabling Rapid and Stable Heat and Radiation Sensing.

Author

Shiran Chaharsoughi, Mina, Zhao, Dan, Crispin, Xavier, Fabiano, Simone, and Jonsson, Magnus P.

Subjects

HEAT radiation & absorption, THERMOELECTRIC effects, ELECTRON-ion collisions, HEAT flux, THERMOELECTRIC materials, TEMPERATURE sensors

Abstract

Sensors for monitoring temperature, heat flux, and thermal radiation are essential for applications such as electronic skin. While pyroelectric and thermoelectric effects are suitable candidates as functional elements in such devices, both concepts show individual drawbacks in terms of zero equilibrium signals for pyroelectric materials and small or slow response of thermoelectric materials. Here, these drawbacks are overcome by introducing the concept of thermodiffusion‐assisted pyroelectrics, which combines and enhances the performance of pyroelectric and ionic thermoelectric materials. The presented integrated concept provides both rapid initial response upon heating and stable synergistically enhanced signals upon prolonged exposure to heat stimuli. Likewise, incorporation of plasmonic metasurfaces enables the concept to provide both rapid and stable signals for radiation‐induced heating. The performance of the concept and its working mechanism can be explained by ion–electron interactions at the interface between the pyroelectric and ionic thermoelectric materials. [ABSTRACT FROM AUTHOR]

Published

2019

9. Aerogels: A Multiparameter Pressure–Temperature–Humidity Sensor Based on Mixed Ionic–Electronic Cellulose Aerogels (Adv. Sci. 8/2019).

Author

Han, Shaobo, Alvi, Naveed Ul Hassan, Granlöf, Lars, Granberg, Hjalmar, Berggren, Magnus, Fabiano, Simone, and Crispin, Xavier

Subjects

AEROGELS, TEMPERATURE effect, THERMOELECTRIC materials, ELECTRICAL conductors, DETECTORS

Published

2019

10. A Multiparameter Pressure–Temperature–Humidity Sensor Based on Mixed Ionic–Electronic Cellulose Aerogels.

Author

Han, Shaobo, Alvi, Naveed Ul Hassan, Granlöf, Lars, Granberg, Hjalmar, Berggren, Magnus, Fabiano, Simone, and Crispin, Xavier

Subjects

AEROGELS, TEMPERATURE effect, HUMIDITY, INTERNET of things, SIGNAL processing

Abstract

Pressure (P), temperature (T), and humidity (H) are physical key parameters of great relevance for various applications such as in distributed diagnostics, robotics, electronic skins, functional clothing, and many other Internet‐of‐Things (IoT) solutions. Previous studies on monitoring and recording these three parameters have focused on the integration of three individual single‐parameter sensors into an electronic circuit, also comprising dedicated sense amplifiers, signal processing, and communication interfaces. To limit complexity in, e.g., multifunctional IoT systems, and thus reducing the manufacturing costs of such sensing/communication outposts, it is desirable to achieve one single‐sensor device that simultaneously or consecutively measures P–T–H without cross‐talks in the sensing functionality. Herein, a novel organic mixed ion–electron conducting aerogel is reported, which can sense P–T–H with minimal cross‐talk between the measured parameters. The exclusive read‐out of the three individual parameters is performed electronically in one single device configuration and is enabled by the use of a novel strategy that combines electronic and ionic Seebeck effect along with mixed ion–electron conduction in an elastic aerogel. The findings promise for multipurpose IoT technology with reduced complexity and production costs, features that are highly anticipated in distributed diagnostics, monitoring, safety, and security applications. [ABSTRACT FROM AUTHOR]

Published

2019

11. Tuning the Thermoelectric Properties of Conducting Polymers in an Electrochemical Transistor.

Author

Bubnova, Olga, Berggren, Magnus, and Crispin, Xavier

Subjects

*ELECTRICAL properties of conducting polymers, *ELECTRIC properties of organic semiconductors, *THERMOELECTRIC materials, *ELECTRICAL conductivity measurement, *ELECTROLYTIC oxidation

Abstract

While organic field-effect transistors allow the investigation of interfacial charge transport at the semiconductor-dielectric interface, an electrochemical transistor truly modifies the oxidation level and conductivity throughout the bulk of an organic semiconductor. In this work, the thermoelectric properties of the bulk of the conducting polymer poly(3,4-ethylenedioxythiophene)-poly(styrene sulfonate) were controlled electrically by varying the gate voltage. In light of the growing interest in conducting polymers as thermoelectric generators, this method provides an easy tool to study the physics behind the thermoelectric properties and to optimize polymer thermoelectrics. [ABSTRACT FROM AUTHOR]

Published

2012

12. Correlating the Seebeck coefficient of thermoelectric polymer thin films to their charge transport mechanism.

Author

Petsagkourakis, Ioannis, Cloutet, Eric, Fleury, Guillaume, Hadziioannou, Georges, Pavlopoulou, Eleni, Chen, Yan Fang, Liu, Xjianjie, Fahlman, Mats, Berggren, Magnus, Crispin, Xavier, and Dilhaire, Stefan

Subjects

*THERMOELECTRIC materials, *THIN films, *CHARGE transfer, *SEEBECK coefficient, *CONDUCTING polymers

Abstract

Room temperature flexible heat harvesters based on conducting polymers are ideally suited to cover the energy demands of the modern nomadic society. The optimization of their thermoelectric efficiency is usually sought by tuning the oxidation levels of the conducting polymers, even if such methodology is detrimental to the Seebeck coefficient ( S ) as both the Seebeck coefficient and the electrical conductivity ( σ ) are antagonistically related to the carrier concentration. Here we report a concurrent increase of S and σ and we experimentally derive the dependence of Seebeck coefficient on charge carrier mobility for the first time in organic electronics. Through specific control of the conducting polymer synthesis, we enabled the formation of a denser percolation network that facilitated the charge transport and the thermodiffusion of the charge carriers inside the conducting polymer layer, while the material shifted from a Fermi glass towards a semi-metal, as its crystallinity increased. This work sheds light upon the origin of the thermoelectric properties of conducting polymers, but also underlines the importance of enhanced charge carrier mobility for the design of efficient thermoelectric polymers. [ABSTRACT FROM AUTHOR]

Published

2018

13. Significant Electronic Thermal Transport in the Conducting Polymer Poly(3,4-ethylenedioxythiophene)

Author

Michael T. Pettes, Zia Ullah Khan, Drew Evans, Annie Weathers, Xavier Crispin, Li Shi, Jens Wenzel Andreasen, Robert Brooke, Weathers, Annie, Khan, Zia Ullah, Brooke, Robert, Evans, Drew, Pettes, Michael T, Andreasen, Jens Wenzel, Crispin, Xavier, and Shi, Li

Subjects

Conductive polymer, Materials science, Mechanical Engineering, thermoelectric materials, Wiedemann–Franz law, Electrical Engineering, Electronic Engineering, Information Engineering, Thermoelectric materials, chemistry.chemical_compound, Thermal conductivity, PEDOT:PSS, chemistry, Mechanics of Materials, Electrical resistivity and conductivity, Seebeck coefficient, Polymer chemistry, 4-ethylenedioxythiophene), thermal conductivity, Wiedemann-Franz law, poly(3,4-ethylenedioxythiophene), General Materials Science, Composite material, conducting polymers, poly(3, Elektroteknik och elektronik, Poly(3,4-ethylenedioxythiophene)

Abstract

Suspended microdevices are employed to measure the in-plane electrical conductivity, thermal conductivity, and Seebeck coefficient of suspended poly(3,4-ethylenedioxythiophene) (PEDOT) thin films. The measured thermal conductivity is higher than previously reported for PEDOT and generally increases with the electrical conductivity. The increase exceeds that predicted by the Wiedemann-Franz law for metals and can be explained by significant electronic thermal transport in PEDOT. Funding Agencies|US National Science Foundation Thermal Transport Processes Program [CBET-0933454]; European Research Council (ERC) [307596]; Swedish foundation for strategic research; Knut and Alice Wallenberg foundation; Swedish Energy Agency; NSF Graduate Research Fellowship Program

Published

2015