PEDOT: PSS Thermoelectric Generators Printed on Paper Substrates

Andersson, Henrik; Šuly, Pavol; Thungström, Göran; Engholm, Magnus; Zhang, Renyun; Mašlík, Jan; Olin, Håkan

doi:10.3390/jlpea9020014

Cited by 19 publications

(24 citation statements)

References 31 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…Carbon-based thermoelectric materials have been shown to be processable onto flexible substrates such as polyimides, polyethylene terephthalates (PETs), and paper. [118,119] When examining the materials properties for use in wearable textile TEG devices for example, it is essential that the design considerations account for mechanical durability and allow tuning for desired viscoelastic traits. [120] This is because the devices will be under mechanical stress when bent or stretched.…”

Section: Organic/carbonmentioning

confidence: 99%

Printed Thermoelectrics

et al. 2022

View full text Add to dashboard Cite

show abstract

Section: Organic/carbonmentioning

confidence: 99%

Printed Thermoelectrics

et al. 2022

View full text Add to dashboard Cite

show abstract

“…The thermal conductivity of cellulose papers with a copper filler content of up 14.3 wt% (or a ratio of 1:6 between copper particles and pulp fibers) could already be dramatically increased . In previous studies, electronic circuits and piezoelectric structures had been printed onto cellulose papers . Similarly, circuit structures made from Ti 2 SiC 3 could be successfully ink‐jet printed onto preceramic alumina papers by Carrijo et al The circuitry patterns on highly filled papers might be integrated into low voltage energy sources, memory cells or a variety of sensors.…”

Section: Applications Of Highly Filled Papers and Paper‐derived Matermentioning

confidence: 99%

“…While the Ti 2 SiC 3 ink, which has been developed by Carrijo et al, contained submicron‐sized particles, Milardović et al presented an ink for cellulose papers with spherical silver nanoparticles of an average diameter of 2.5 nm, which is the finest particle size for particles in silver metal inks to this date. By printing patterns of precious metal nanoparticles on cellulose papers several different microelectronic structures could be generated: RFID sensors and sensors with a memory effect to measure humidity, thermoelectric generators and gas sensors oxygen sensors for hydrogen sulfide or oxygen . The printed thermoelectric low voltage energy sources and sensors tested on cellulose papers can be installed onto a wide range of food packaging materials, including card board boxes.…”

Section: Applications Of Highly Filled Papers and Paper‐derived Matermentioning

confidence: 99%

Highly Filled Papers, on their Manufacturing, Processing, and Applications

et al. 2019

View full text Add to dashboard Cite

Since more than a decade ago, the research on highly filled papers, as well as paper-derived inorganic materials, has greatly intensified. As presented in this review, highly filled papers as preforms allow for the design of porous or dense, multilayered, and geometrically complex structures. These paperderived ceramic-or metal-based materials are generated by the heattreatment of highly filled papers. Paper-derived materials are potential materials of choice for applications in transportation, energy-generation, environmental conservation, support structures, medical uses, and electronic components. Due to the adjustability of the filler content and the good machinability of highly filled papers, paper-derived sheets or multilayers may include intricate structures and tailored gradients in phase structure or porosity. Paper-derived multilayers also may contain cast ceramic tapes or other functionalized layers, as presented in some examples. Computer-aided manufacturing processes for paper-derived materials can be supplemented by prediction models for the sintering shrinkage in order to identify optimal post-processing steps, stacking orders and orientations for highly filled paper layers within multilayer green bodies. The accuracy of established component-level sintering models can be significantly increased by microstructure models of the highly filled paper. ParameterName Unit α Mismatch parameter for fiber cross-sections, Equation (5) Dimensionless α p Layer position in viscoelastic paper structure model, Equation (2) Dimensionless A 0 Initial amplitude of perturbation, Equations (15) 10 À6 m A(f) Parameter for evolution of instantaneous carbon conversion rate, Equation (7) Dimensionless A diff Source controlled diffusion parameter, Equations (9) 10 À7 N A match Modeling parameter, Equations (8) Dimensionless a Inter-particle contact-area radius, Equations (19) 10 À8 m a Local average pore area, Equation (4) 10 À6 m 2 b Pore geometry constant, Equation (20) Dimensionless ß evo , m evo Empirical constants for grain evolution in SOVS model, Equation (8) Dimensionless ß r(c)p Proportionality constant for bimodal packing fraction determination, Equation (18) Dimensionless C Modeling constant for debindering pressure calculation, Equation (7) 10 À6 (m 2 Á s)/K C 1 , C 2 , C 3 , C 4 , C 5 Parameters in the Riedel model that are determined by the dihedral angle, Equations (9) Dimensionless c glue Heat capacity of the adhesive layers, Equation (3) 10 À6 s c L , c s Volume fraction of larger-sized/smaller-sized particles in a multimodal mixture of particles, Equation (17)and (18) 10 0 vol% c vol Volume concentration of pulp fibers, Equation (4) 10 0 vol% γ, γ 0 Strain relaxation rate of calendered paper with initial value, Equation (2) Dimensionless γ B Grain boundary energy density, Equation (13) 10 0 J m À2 γ b Specific energy for grain boundary diffusion, Equation (9) 10 3 J mol À1 γ S Material surface energy, Equation (8, 11, and 13) 10 0 J m À2 Δ Half of the inter-particle boundary thickness, Equation (19) 10 À8...

show abstract

“…Temperature sensor and thermoelectric generator applications. We would like to refer the reader to two other studies 26,63 that were performed in parallel to the present research where some of the substrates studied here were used to print a thermosensor 63 and a triboelectric generator applications. 26…”

Section: Part 3: Electrical Properties and Applicationsmentioning

confidence: 99%