Heat Dissipation of Transparent Graphene Defoggers

Bae, Jung Jun; Lim, Seong Chu; Han, Gang; Jo, Young Tak; Doung, Dinh Loc; Kim, Eun Sung; Chae, Seung Jin; Huy, Ta Quang; Luan, Nguyen Van; Lee, Young Hee

doi:10.1002/adfm.201201155

Cited by 243 publications

(256 citation statements)

References 31 publications

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“…For a given combination of electrical and thermal properties the steady state temperature increase is set by balance of Joule heating and heat dissipation and can be controlled via the voltage. Such devices are important for a number of applications from defogging of windows or mirrors 21 to performance optimisation of liquid crystalline displays via temperature control 31 to art conservation.…”

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confidence: 99%

“…19,20 However, more recently, attention has turned to using nanostructured transparent conductors as transparent heaters. [21][22][23][24][25][26][27][28][29][30] Transparent heaters are simply conducting films which are thin enough to be transparent but can be heated up on application of a voltage. For a given combination of electrical and thermal properties the steady state temperature increase is set by balance of Joule heating and heat dissipation and can be controlled via the voltage.…”

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confidence: 99%

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Relationship between Material Properties and Transparent Heater Performance for Both Bulk-like and Percolative Nanostructured Networks

2014

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Transparent heaters are important for many applications and in the future are likely to be fabricated from thin, conducting, nanostructured networks. However, the electrical properties of such networks are almost always controlled by percolative effects.The impact of percolation on heating effects has not been considered and the material parameter combinations which lead to efficient performance are not known. In fact, figures of merit for transparent heaters have not been elucidated, either in bulk-like or percolative systems. Here, we develop a simple yet comprehensive model describing the operation of transparent heaters. By considering the balance of Joule heating versus power dissipated by both convection and radiation, we derive an expression for the time-dependent heater temperature as a function of both electrical and thermal parameters. This equation can be modified to describe the relationship between temperature, optical transmittance and electrical/thermal parameters in both bulk-like and percolative systems. By performing experiments on silver nanowire networks, systems known to display both bulk-like and percolative regimes, we show the model to describe real systems extremely well. This work shows the performance of transparent heaters in the percolative regime to be significantly less efficient compared to the bulk-like regime, implying the diameter of the nanowires making up the network to be critical. The model allows the identification of figures of merit for networks in both bulk-like and percolative regimes. We show that metallic nanowire networks are most promising, closely followed by CVD graphene with networks of solutionprocessed graphene and carbon nanotubes being much less efficient.

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confidence: 99%

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Relationship between Material Properties and Transparent Heater Performance for Both Bulk-like and Percolative Nanostructured Networks

2014

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“…The Ni-based micromesh film without Pt-decoration reaches the steady-state temperature of 160 • C. Meanwhile, the steady-state temperature of the Nibased micromesh film decorated with Pt for 180 s reaches to 200 • C. After the metallic mesh film is heated by Joule heating, the heat dissipates by conduction through the substrate, and by convection and radiation to the air. 24 The heat lost by conduction and radiation is negligible compared to the convective heat loss, because of the low thermal-conductivity substrate and the low emissivity of the electrode material. Thus, it is presumed that air convection is the main path of heat dissipation for the Ni-based micromesh films.…”

Section: Resultsmentioning

confidence: 99%

“…Thus, it is presumed that air convection is the main path of heat dissipation for the Ni-based micromesh films. 24,25 The convective heat power loss is expressed by 24,25 …”

Section: Resultsmentioning

confidence: 99%

Observation of convection phenomenon by high-performance transparent heater based on Pt-decorated Ni micromesh

Kim

et al. 2017

AIP Advances

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In this study, we report for the first time on the convection phenomenon for the consistent and sensitive detection of target materials (particulate matter (PM) or gases) with a high-performance transparent heater. The high-performance transparent heater, based on Pt-decorated Ni micromesh, was fabricated by a combination of transfer printing process and Pt sputtering. The resulting transparent heater exhibited excellent mechanical durability, adhesion with substrates, flexibility, and heat-generating performance. We monitored the changes in the PM concentration and temperature in an airtight chamber while operating the heater. The temperature in the chamber was increased slightly, and the PM2.5 concentration was increased by approximately 50 times relative to the initial state which PM is deposed in the chamber. We anticipate that our experimental findings will aid in the development and application of heaters for sensors and actuators as well as transparent electrodes and heating devices.

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“…Above all, the most critical issue is the limited power (P) that can be supplied to such materials. This severely restricts the maximum attainable temperature (T s ), since T s ∝ P. For example, the temperature ranges of graphene heaters, silver nanowire heaters, and heaters utilizing hybrid materials combining graphene and silver nanowires are 100-206°C, [19][20][21] 48-160°C, [22][23][24][25][26][27] and up to 225°C, 28,29 respectively.…”

Section: Introductionmentioning

confidence: 99%

Highly flexible, stretchable, patternable, transparent copper fiber heater on a complex 3D surface

Jo¹,

An²,

Lee³

et al. 2017

NPG Asia Mater

118

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A highly transparent, flexible, stretchable and patternable copper fiber heater was successfully fabricated for potential use in smart windows and other applications. The thickness of the electrospun polymer nanofibers was controlled during subsequent copper plating by adjusting the electroplating time, with minimal sacrifice in transparency. Self-fused junctions, formed via electroplating, significantly reduced the contact resistance between the intersecting copper-plated fibers. The heater temperature remained constant up to 300% sheet stretching. De-icing tests confirmed the potential applicability of such heaters in smart windows or vehicle defrosters. The copper-plated fibers may be transferred onto any surface with a complex 3D structure, as demonstrated by fabricating a heat-radiating Venus statue covered with the copper-plated fibers. The highest temperature of 328°C was achieved by using a transparent fibrous film having 90% transparency and 0.058 Ω sq − 1 sheet resistance.

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Heat Dissipation of Transparent Graphene Defoggers

Cited by 243 publications

References 31 publications

Relationship between Material Properties and Transparent Heater Performance for Both Bulk-like and Percolative Nanostructured Networks

Relationship between Material Properties and Transparent Heater Performance for Both Bulk-like and Percolative Nanostructured Networks

Observation of convection phenomenon by high-performance transparent heater based on Pt-decorated Ni micromesh

Highly flexible, stretchable, patternable, transparent copper fiber heater on a complex 3D surface

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