Paper Thermoelectrics by a Solvent-Free Drawing Method of All Carbon-Based Materials

Rafique, Shazia; Badiei, Nafiseh; Burton, Matthew R.; Gonzalez-Feijoo, Jorge Eduardo; Carnie, Matthew J.; Tarat, Afshin; Li, Lijie

doi:10.1021/acsomega.0c06221

Cited by 13 publications

(11 citation statements)

References 68 publications

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“…Figure 5d shows the I–V characteristics of our six‐pair device for different temperature gradients, which suggest that the fabricated PTEG is a typical linear voltage source. The output power of the device is calculated using the relation P M = ( V oc

\times

I sc )/4, [ 38 ] which is ≈14.6 nW for Δ T = 70 K. It is to be noted that our obtained value is very much comparable to the recent literature reports, [ 16,17,19 ] furthermore with added advantages of using simpler and even more economic processing methods. To check the scalability of the PTEG, we extended the device geometry to 60‐pair (device image Figure S7, Supporting Information) and the output performance is shown in Figure 5e,f.…”

Section: Resultssupporting

confidence: 72%

“…The RT σ for the bismuth trace is measured as 5.6 S cm À1 and that of the graphite trace is 84.4 S cm À1 (Figure 3a,c). Even at RT, measured value of σ of the graphite trace is several orders higher than that reported for contemporary works on graphite traces on regular paper (6 [16] and 3.3 S cm À1 [17] ), which might be due to extra roughness of the emery paper compared to regular office paper. At RT, σ value for our bismuth trace is however less compared to bulk or thin film.…”

Section: Temperature-dependent Thermoelectric Properties Of Individua...contrasting

confidence: 60%

“…[14] In that direction, inorganic film-based paper TEGs (PTEGs) have drawn attention due to their lightweight, foldability, low cost, simplicity in fabrication, improved functionality, environment friendliness, and market readiness. [15][16][17][18][19][20] Increasing research reports on PTEGs invariably suggests that by carefully designing the devices and by manipulating the rigidity of inorganic TE semiconductors, larger output voltages and power and thereby better performance can be obtained and practically implementable for thermal sensing and microenergy harvesting.In the present work, we introduce a highly feasible emery paper-based PTEG composed of graphite as p-type leg and bismuth as n-type leg from their bulk traces, without additional complex growth and processing steps of the constituent TE materials or intermediate chemical modification. We show that just simple bulk tracing method and by choosing proper roughness of the emery paper, an output power as good as 137.5 nW can be obtained for ΔT % 70 K, which is also supported by finite-elemental analysis.…”

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confidence: 99%

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confidence: 99%

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Flexible Thermoelectric Generator from Bulk Graphite and Bismuth Traces on Emery Paper

et al. 2023

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Flexible thermoelectrics (TEs) involving simplified processeability are attractive, with limited choice of materials and low endurance, remaining as major challenges. Herein, an economic emery paper‐based thermoelectric generator (PTEG) from graphite as p‐type leg and bismuth as n‐type leg is introduced, prepared by simple bulk tracing. Tracing provides a feasible approach to modulate the TE properties, as supported by finite‐element analysis. From individual bismuth trace a power factor of 5.85 μW m−1 K−2 ≈100 °C (2.09 μWm−1 K−2 at room temperature (RT)) and for graphite a power factor 7.7 μW m−1 K−2 at ≈100 °C (≈5.1 μW m−1 K−2 at RT) is obtained. A six‐pair p–n module‐integrated PTEG drives an open‐circuit voltage of 35.8 mV producing an output power of 14.6 nW whereas from a 60‐pair PTEG, voltage ≈348 mV with ≈137.5 nW output power is produced for ΔT ≈ 70 K. The scalability of the fabricated PTEGs is understood from Seebeck voltage being directly proportional to the number of p–n modules and is further tested for harvesting waste heat from electronics. This facile approach may be extended to other organic and inorganic TE materials, contributing to the research in self‐powered heat sensors, wearables, and as thermal harvesters in IoT equipment.

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Section: Resultssupporting

confidence: 72%

Section: Temperature-dependent Thermoelectric Properties Of Individua...contrasting

confidence: 60%

mentioning

confidence: 99%

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Flexible Thermoelectric Generator from Bulk Graphite and Bismuth Traces on Emery Paper

et al. 2023

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“…Therefore, the current thermoelectric research is focused on finding low-cost and non-toxic thermoelectric conductors for the application [29] , [30] , [31] , [32] , [33] , [34] , [35] , [36] , [37] . With some improvements and modifications in the thermoelectric properties of graphite such as by organic doping or alloying with other semiconductors, they can also be utilized in the fabrication of thermoelectric devices [19] , [38] , [39] , [40] , [41] , [42] , [43] , [44] , [45] .…”

Section: Validation and Characterisationmentioning

confidence: 99%

Sensors-on-paper: Fabrication of graphite thermal sensor arrays on cellulose paper for large area temperature mapping

Mulla¹,

Dunnill²

2022

HardwareX

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Optimizing Output Performances in Stationery Papers–Based Hybrid Inorganic–Organic Flexible Thermoelectric Generators

Mondal

Das

Ranjan

et al. 2023

Physica Status Solidi (a)

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Flexible and foldable paper-based thermoelectric generators (PTEGs) have drawn industrial attention due to the wide applications in heat energy harvesting and sensing. Herein, optimization of the output performances of flexible and hybrid inorganic-organic PTEGs fabricated on stationery paper substrates from poly(3,4-ethylenedioxythiophene) polystyrene sulfonate (PEDOT:PSS) and graphite as p-type and n-type materials, respectively, is presented. By choosing simplistic processes such as polyethyleneimine (PEI)-treated graphite pencil traces and brush-painted PEDOT:PSS films, robust and sustainable PTEG devices are fabricated. It is first time shown that different qualities of stationery papers can have significant impact on the output performance of PTEGs, attributed to their variance in substrate roughness. Thus, output powers of %1.93 and %0.68 nW for ΔT = 70 K are obtained for TE generators prepared from emery and office paper legs (four-pair assembled on Kapton), respectively, suggesting emery paper to have significant better performance. Transient flexibility and fatigue of each device type are also tested where emery paper-based PTEG appears to be more robust. A detail comparison of the device performances on the different types of paper substrates are exclusively presented experimentally and thereafter computationally validated by COMSOL modeling to predictably control and enhance the output performance of reported PTEGs.

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Paper Thermoelectrics by a Solvent-Free Drawing Method of All Carbon-Based Materials

Cited by 13 publications

References 68 publications

Flexible Thermoelectric Generator from Bulk Graphite and Bismuth Traces on Emery Paper

Flexible Thermoelectric Generator from Bulk Graphite and Bismuth Traces on Emery Paper

Sensors-on-paper: Fabrication of graphite thermal sensor arrays on cellulose paper for large area temperature mapping

Optimizing Output Performances in Stationery Papers–Based Hybrid Inorganic–Organic Flexible Thermoelectric Generators

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