Sökning: WFRF:(Kroon Christian) > Doping and processi...
Fältnamn | Indikatorer | Metadata |
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000 | 03797naa a2200445 4500 | |
001 | oai:research.chalmers.se:7e09a5c0-041d-4136-be86-fd062c70feff | |
003 | SwePub | |
008 | 221126s2018 | |||||||||||000 ||eng| | |
024 | 7 | a https://research.chalmers.se/publication/5333712 URI |
024 | 7 | a https://doi.org/10.1016/B978-0-08-102284-9.00013-92 DOI |
040 | a (SwePub)cth | |
041 | a engb eng | |
042 | 9 SwePub | |
072 | 7 | a kap2 swepub-publicationtype |
072 | 7 | a vet2 swepub-contenttype |
100 | 1 | a Hofmann, Anna,d 1987u Chalmers tekniska högskola,Chalmers University of Technology4 aut0 (Swepub:cth)hofanna |
245 | 1 0 | a Doping and processing of organic semiconductors for plastic thermoelectrics |
264 | 1 | c 2018 |
520 | a Thermoelectrics currently attracts considerable attention as a promising branch in the field of organic electronics, with the prospect that organic semiconductors (OSCs) allow the development of light, flexible, and inexpensive thermoelectric devices, which act as alternative power sources, generating electricity from heat gradients. Thermoelectric generators are solid-state devices that convert heat directly to electricity. They do not contain any moving parts and are able to operate over an extended period of time, and furthermore can function with small heat sources and limited temperature differences, which facilitates their use in situations where traditional engines are not feasible. The absence of moving parts, low need for maintenance, and a large variety of possible device architectures render organic thermoelectrics attractive for numerous applications, ranging from waste heat recovery to wearable textiles. In this chapter, we give a short introduction to the fundamentals of the thermoelectric effect, as well as to the design principles for thermoelectric generators and their characterization. Furthermore, we discuss the role of doping (i.e., the introduction of charge carriers through the addition of dopant molecules) and of the nanostructure and present strategies for the optimization of the thermoelectric properties of OSCs. Finally, we give an overview of processing methods and point out major achievements, as well as the remaining challenges. | |
650 | 7 | a TEKNIK OCH TEKNOLOGIERx Maskinteknikx Energiteknik0 (SwePub)203042 hsv//swe |
650 | 7 | a ENGINEERING AND TECHNOLOGYx Mechanical Engineeringx Energy Engineering0 (SwePub)203042 hsv//eng |
650 | 7 | a NATURVETENSKAPx Fysikx Annan fysik0 (SwePub)103992 hsv//swe |
650 | 7 | a NATURAL SCIENCESx Physical Sciencesx Other Physics Topics0 (SwePub)103992 hsv//eng |
650 | 7 | a TEKNIK OCH TEKNOLOGIERx Elektroteknik och elektronikx Annan elektroteknik och elektronik0 (SwePub)202992 hsv//swe |
650 | 7 | a ENGINEERING AND TECHNOLOGYx Electrical Engineering, Electronic Engineering, Information Engineeringx Other Electrical Engineering, Electronic Engineering, Information Engineering0 (SwePub)202992 hsv//eng |
653 | a Thermal conductivity | |
653 | a Doping | |
653 | a Electronic textile | |
653 | a Conducting polymer | |
653 | a Seebeck coefficient | |
653 | a Bulk processing | |
653 | a Foam | |
653 | a Organic thermoelectrics | |
653 | a Anisotropy | |
700 | 1 | a Kroon, Renee,d 1982u Chalmers tekniska högskola,Chalmers University of Technology4 aut0 (Swepub:cth)reneek |
700 | 1 | a Müller, Christian,d 1980u Chalmers tekniska högskola,Chalmers University of Technology4 aut0 (Swepub:cth)cmuller |
710 | 2 | a Chalmers tekniska högskola4 org |
773 | 0 | t Handbook of Organic Materials for Electronic and Photonic Devices, Second Editiong , s. 429-449q <429-449z 9780081022849 |
856 | 4 8 | u https://research.chalmers.se/publication/533371 |
856 | 4 8 | u https://doi.org/10.1016/B978-0-08-102284-9.00013-9 |
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