Rollable, Stretchable, and Reconfigurable Graphene Hygroelectric Generators

Yang, Changxi; Huang, Yaxin; Cheng, Huhu; Jiang, Lan; Qu, Liangti

doi:10.1002/adma.201805705

Cited by 135 publications

(165 citation statements)

References 32 publications

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“…Owing to the presence of hydrophilic oxygen‐containing groups (e.g., carboxyl, hydroxyl, and epoxy groups), moisture could diffuse easily into GO membranes and dissociated H + ions from GO surfaces. With a gradient distribution of oxygen‐containing groups within a GO membrane, the concentration gradient of H + ions would be produced upon exposing to a humidity variation (e.g., human respiratory and finger touch) and hereby generated an electric pulse . The concentration gradient of H + ions was also observed in homogeneous GO membranes during the moisture diffusion process, in which the generated voltage, however, dropped down when the membranes were totally wetted by moisture.…”

Section: Introductionmentioning

confidence: 99%

Biological Nanofibrous Generator for Electricity Harvest from Moist Air Flow

Zong

Yang

et al. 2019

Adv Funct Materials

162

173

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Electricity harvest from ubiquitous water has been endeavored, using nanogenerators based on carbon nanomaterials, to acquire renewable and clean energy and cope with fossil depletion and pollution as well. Meanwhile, though many biological organisms can harness water for bioelectricity, it is still challenging to produce biological nanogenerators based on biological nanomaterials with billions of tons of annual production in nature. Herein biological nanofibrils, including cellulose, chitin, silk fibroin, and amyloid, are produced either by liquid-exfoliation of biomasses or by supramolecular assembly of bio-macromolecules. With the intrinsic hydrophilicity and charged states, they can capture moisture from air and form hydrated nanochannels, in analogue to ionic channels of cytomembranes. When exposing their aerogels to moist air flow, there is a balance of water absorption and evaporation, thus producing a streaming potential and an open-circuit voltage across the aerogel. With flexibility, sustainability, biocompatibility, and biodegradability, these biological nanogenerators can harvest electricity from moist air flow in nature (e.g., wind, respiration and perspiration) and in industry, and serve for environmentally-friendly, low-cost, high-efficiency, wearable, and miniaturized power devices.

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Section: Introductionmentioning

confidence: 99%

Biological Nanofibrous Generator for Electricity Harvest from Moist Air Flow

Zong

Yang

et al. 2019

Adv Funct Materials

162

173

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“…[2,22,24,25] Tensile strain is generated primarily from [SiN] bonds interaction, which occurs more during high-frequency (HF) deposition condition; these bonds' dominance is caused by the smaller mean free path of the radicals generated by the plasma. [22,27,28] When the annealing temperature is sufficiently higher than the film deposition temperature, the hydrogen and ammonia byproducts diffuse out and leave more [SiN] bonds causing a decrease in compressive stress and an increase in tensile strain, respectively, in both of the layers. [22,27,28] When the annealing temperature is sufficiently higher than the film deposition temperature, the hydrogen and ammonia byproducts diffuse out and leave more [SiN] bonds causing a decrease in compressive stress and an increase in tensile strain, respectively, in both of the layers.…”

mentioning

confidence: 99%

Effect of Perforation on the Thermal and Electrical Breakdown of Self‐Rolled‐Up Nanomembrane Structures

Michaels

Wood

Froeter

et al. 2019

Adv Materials Inter

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Strain‐induced self‐rolled‐up membranes (S‐RuM) are structures formed spontaneously by releasing a strained layer or layer stacks from its mechanical support, with unique applications in passive photonics, electronics, and bioengineering. Depending on the thermal properties of the strained layers, these structures can experience various thermally induced deformations. These deformations can be avoided and augmented with the addition of strategically placed perforations in the membrane. This study reports on the use of perforations to modify the thermal effects on strained silicon nitride S‐RuM structures. A programmable fuse with well‐defined thermal threshold, ultrasmall footprint, and 2–3 V voltage rating is demonstrated, which can potentially serve as an on‐chip sensing device for power electronic circuits.

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“…In summary, we have given a systematic and comprehensive review regarding general synthesis methods and advanced practical applications of 2D group-IVA materials according to the state-of-the-art research advances. As the emergence of graphene, its exotic properties and rich reserves of group-IVA elements shed light on the engineering of group-IVA 2D nanosheets with expected 26 and desirable power being realized in novel optoelectronic and thermoelectric devices.…”

Section: Discussionmentioning

confidence: 99%

Two‐dimensional materials of group‐IVA boosting the development of energy storage and conversion

Guo

Chen

2020

Carbon Energy

Self Cite

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Graphene, an emerging fabric of carbon atoms, has manifested its versatility in all kinds of fields encompassing electronics, optoelectronics, thermoelectrics, taking advantage of its excellent mechanical strength, exceptional electronic and thermal conductivities, high surface specific area, and so forth. The prosperity of graphene never seen before has led the attention to silicene, siloxene, germanene, stanene, and plumbene due to their promising applications in the quantum spin Hall effect, topological insulator, batteries, capacitors, catalysis, and topological superconductivity. Herein, we review the existing production methods, numerous applications of two‐dimensional group‐IVA materials, and critically discuss the challenges of these materials, providing potential implications to the exploration of uncharted material systems.

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Rollable, Stretchable, and Reconfigurable Graphene Hygroelectric Generators

Cited by 135 publications

References 32 publications

Biological Nanofibrous Generator for Electricity Harvest from Moist Air Flow

Biological Nanofibrous Generator for Electricity Harvest from Moist Air Flow

Effect of Perforation on the Thermal and Electrical Breakdown of Self‐Rolled‐Up Nanomembrane Structures

Two‐dimensional materials of group‐IVA boosting the development of energy storage and conversion

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