High-Performance and Rapid-Response Electrical Heaters Derived from Cellulose Nanofiber/Silver Nanowire Nanopapers for Portable Thermal Management

Cheng, Rui; Wang, Bin; Zeng, Jinsong; Li, Jinpeng; Xu, Jun; Gao, Wenhua; Chen, Kefu

doi:10.1021/acsami.2c04931

Cited by 30 publications

(13 citation statements)

References 63 publications

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“…The ULCuNWs40/ANF nanopapers treated at 180 °C, for example, show λ // as high as 16.32 W·m –1 ·K –1 , resulting in an increase of 32% and 49% in comparison to that of the ULCuNWs40/ANF nanopapers with thermal treatment at 100 °C and no thermal treatment, respectively. The higher λ // after thermal treatment could be because the ULCuNWs are merged at the intersection owing to the removal of the organic layer on the ULCuNWs surface at high temperatures, which is demonstrated by previous literature . Since the alignment of 1D ULCuNWs invariably results in anisotropy in the thermal conductivity, the through-plane thermal conductivity λ ⊥ of the ULCuNWs/ANF nanopapers was also investigated, as shown in Figure S2.…”

Section: Resultsmentioning

confidence: 80%

“…The higher λ // after thermal treatment could be because the ULCuNWs are merged at the intersection owing to the removal of the organic layer on the ULCuNWs surface at high temperatures, which is demonstrated by previous literature. 15 Since the alignment of 1D ULCuNWs invariably results in anisotropy in the thermal conductivity, the throughplane thermal conductivity λ ⊥ of the ULCuNWs/ANF nanopapers was also investigated, as shown in Figure S2. It is evident that the λ ⊥ of the ULCuNWs/ANF nanopapers also shows an increase with an increase in the weight fraction of the ULCuNWs.…”

Section: Resultsmentioning

confidence: 99%

“…A combination of the two components of 1D structured nanomaterials with a high aspect ratio could result in advantageous mechanical strength of the resulting nanopapers. Ma et al 14 demonstrated a superior mechanical strength of silver nanowires/ANF-based nanopapers of ∼236 MPa, while Cheng and co-workers 15 revealed σ of silver nanowires/CNF of ∼177 MPa. From the mentioned studies, it is conspicuous that the ANF has preferable properties in escalating the thermal conductivity and mechanical properties of nanopapers compared to CNF.…”

Section: Introductionmentioning

confidence: 99%

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Thermoconductive Ultralong Copper Nanowire-Based Aramid Nanofiber Nanopapers for Electromagnetic Interference Shielding

Tran

Vu-Anh

Cong-Hau

et al. 2022

ACS Appl. Nano Mater.

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Nowadays, the advancement of thermoconductive electromagnetic interference (EMI) shielding materials for the next generation of electronics is in high demand. We present, in this research, the fabrication of the highly thermoconductive nanopapers based on aramid nanofiber (ANF) and ultralong copper nanowires (ULCuNWs) with outstanding EMI shielding effectiveness (SE) and mechanical properties. A homogeneous red brick color nanopaper (thickness 40–50 μm) was fabricated by homogenizing a mixture of the ULCuNWs (10–40 wt %) in the ANF suspension, then vacuum filtration, and drying. The morphology of the nanopapers reveals that the ULCuNWs were uniformly dispersed and interweaved with ANF to form two-dimensional (2D) layers in the nanopapers. With the increase in the ULCuNWs content, the nanopaper shows outstanding mechanical properties and reaches the optimal tensile strength (σ) of 228 MPa and Young’s modulus of 6.12 GPa at the filler content of 30 wt %. Moreover, the variation of the in-plane thermal conductivity (λ//) and EMI SE of the nanopapers strongly depends on the amount of the ULCuNWs; the ULCuNWs30/ANF nanopapers obtain a notable λ// and EMI SE of around 8.25 W·m–1·K1 and 54.7 dB, respectively, with the mass content of 30 wt % at ambient conditions. The thermal treatment of the ULCuNWs30/ANF nanopapers at 180 °C increases the λ// and EMI SE by 60% and 9%, respectively. The ULCuNWs30/ANF nanopaper demonstrates an impressive heat dissipating capability. In addition, the ULCuNWs/ANF nanopapers show eminent thermal stability up to 500 °C and flame retardancy with an extremely low total heat release of 0.72 kJ·g–1. Therefore, ULCuNWs/ANF nanopapers can be considered great potential materials alternative to the current thermoconductive materials for heat dissipating applications in modern electronics.

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Section: Resultsmentioning

confidence: 80%

Section: Resultsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

Thermoconductive Ultralong Copper Nanowire-Based Aramid Nanofiber Nanopapers for Electromagnetic Interference Shielding

Tran

Vu-Anh

Cong-Hau

et al. 2022

ACS Appl. Nano Mater.

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“…S9a †), corresponding to the theoretical prediction model. 81,82 These results conrm that the device possesses huge potential in heating systems with intelligently adjustable temperature. The heating recyclability and stability of the device were evaluated by 50 on-off cycles at 5 V. As shown in Fig.…”

Section: Snf/mxene Composite Aerogels As a Dmtm Devicementioning

confidence: 93%

An extreme condition-resistant superelastic silica nanofiber/MXene composite aerogel for synchronous sensing and thermal management

et al. 2023

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“…Wearable electronic heaters are another important subfield of wearable electronics due to their potential application in personal healthcare, thermotherapy, heat preservation in textile or clothing, and athletic rehabilitation. − Heaters based on Joule heating attracts great attention in the thermotherapy for relieving pain and revitalizing muscles of injured skin/joints/tissues. , In theory, the Joule heater and resistive-type strain sensor have similar structures mainly consisting of a functional conductive layer and substrate layer. , Thus, it is promising to integrate the Joule heater and strain sensor in one wearable electronic device. However, most resistance-type strain sensors exhibit a positive resistance variation during human motion monition; in other words, the electrical resistance of strain sensor increases with the increase of strain due to the fraction of the continuous conductive network. − Although this type of strain sensors demonstrates a high relative resistance change, good gauge factor, and excellent sensitivity, it is problematic to serve as a Joule heater because the increase of resistance results in the decrease of heating temperature according to Joule’s rule ( Q = U 2 t / R , where Q is heat energy, U is applied constant voltage, t is time, and R is resistance) . − Therefore, few studies on combining wearable strain sensors and Joule heating have been reported. − Their strain-imposed thermal stabilities were usually poor, and the Joule heating temperature considerably decreased during stretching. So, it is still a big challenge to integrate the strain sensor and heater into one device.…”

Section: Introductionmentioning

confidence: 99%

Highly Conductive Cellulose Strain Sensor with Excellent Negative Resistance Variation and Joule Heating Property

Zhao

Zhong

et al. 2023

ACS Appl. Polym. Mater.

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The rational design of a wearable strain sensor with heating property has attracted great interest. In this study, a flexible conductivity hierarchical cellulose strain sensor (MX@Ag@CY) with heating property was fabricated via in situ formation of silver nanoparticles (Ags) on cotton yarn (CY) and subsequent dipcoating with MXene (MX). Ags coupled with MX coating endowed the cotton yarn with a high conductivity, where the resistance of the optimized composite MX@Ag 0.47 @CY was about 22 Ω/cm. Compared with the previously reported strain sensors, the woven MX@Ag 0.47 @CY fabric strain sensor showed a distinctive negative resistance variation, wherein it showed an enhanced conductivity with the increased strain owing to its unique architecture. The woven MX@Ag 0.47 @CY fabric strain sensor exhibited a repeatable response and displayed long-term stability in the strain range of 0−55%. In addition, the strain sensor demonstrated great detectability on large-scale human movements when directly attached to the elbow, wrist, or knee. Furthermore, when MX@Ag 0.47 @CY served as a heater (at an applied DC voltage of 6 V), it presented high heating temperature (92.4 °C), homogeneous temperature distribution, low operation voltage (1−6 V), and excellent thermal stability even under strain.

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High-Performance and Rapid-Response Electrical Heaters Derived from Cellulose Nanofiber/Silver Nanowire Nanopapers for Portable Thermal Management

Cited by 30 publications

References 63 publications

Thermoconductive Ultralong Copper Nanowire-Based Aramid Nanofiber Nanopapers for Electromagnetic Interference Shielding

Thermoconductive Ultralong Copper Nanowire-Based Aramid Nanofiber Nanopapers for Electromagnetic Interference Shielding

An extreme condition-resistant superelastic silica nanofiber/MXene composite aerogel for synchronous sensing and thermal management

Highly Conductive Cellulose Strain Sensor with Excellent Negative Resistance Variation and Joule Heating Property

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