Graphene-on-Paper Sound Source Devices

Tian, He; Ren, Tian‐Ling; Xie, Dan; Wang, Yufeng; Zhou, Changjian; Feng, Tingting; Fu, Di; Yang, Yi; Peng, Pinggang; Wang, Ligang; Liu, Litian

doi:10.1021/nn2009535

Cited by 203 publications

(207 citation statements)

References 40 publications

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“…1 In particular, graphene exhibits striking mechanical stiffness (with 1 TPa Young's modulus), ultrathin structure (down to a single atomic layer) and exceptional robustness (stretchable up to 20%), which make it an ideal platform for NEMS. [2][3][4][5][6][7][8] In the context of NEMS, electromechanical coupling is an important and highly desirable property. Among the various coupling methods, the piezoelectric effect, in which a material becomes electrically polarized under external strain, is the most popular method.…”

Section: Introductionmentioning

confidence: 99%

Observation of a giant two-dimensional band-piezoelectric effect on biaxial-strained graphene

et al. 2015

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Piezoelectric materials used in the development of nanoscale mechanical sensors, actuators and energy harvesters have received much attention. More recently, devices made of graphene are of particular interest because of graphene's intriguing electronic and mechanical properties. Intrinsic graphene has long been considered devoid of the piezoelectric effect, although flexoelectricity has been exploited to demonstrate piezoelectricity in functionalized graphene and graphene nanoribbons. The perceived lack of this property has restricted graphene's use in nanoelectromechanical systems (NEMS) for electromechanical coupling purposes. Here an unprecedented two-dimensional (2D) piezoelectric effect on a strained/unstrained graphene junction is reported. In stark contrast to the bulk piezoelectric effect that results from the occurrence of electric dipole moments in solids, the 2D piezoelectric effect arises from the charge transfer along a work function gradient introduced by the biaxial-strainengineered band structure. The observed effect, termed the band-piezoelectric effect, exhibits an enormous magnitude due to the ultrathin structure of graphene. On the basis of the band-piezoelectric effect, a graphene nanogenerator and a pressure gauge were fabricated. The results not only provide a versatile NEMS platform for sensing, actuating and energy harvesting, but also pave the way for efficiently modulating graphene via strain engineering.

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Section: Introductionmentioning

confidence: 99%

Observation of a giant two-dimensional band-piezoelectric effect on biaxial-strained graphene

et al. 2015

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“…Their extreme thinness, down to a single layer, allows almost perfect electrostatic control of the transistor channel, making them robust to short channel effects and ideal for low power applications 8 . In addition, these materials offer excellent mechanical flexibility, optical transparency, and favorable transport properties for realizing electronic, sensing, and optical systems on arbitrary surfaces [9][10][11][12] . These thin, lightweight, bendable, highly rugged and low-power devices could bring dramatic changes to information processing, communications and human-electronic interaction.…”

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confidence: 99%

High-Performance WSe₂ Complementary Metal Oxide Semiconductor Technology and Integrated Circuits

et al. 2015

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Due to their extraordinary structural and electrical properties, two dimensional materials are currently being pursued for applications such as thin-film transistors and integrated circuit. One of the main challenges that still needs to be overcome for these applications is the fabrication of air-stable transistors with industry-compatible complementary metal oxide semiconductor (CMOS) technology. In this work, we experimentally demonstrate a novel high performance air-stable WSe 2 CMOS technology with almost ideal voltage transfer characteristic, full logic swing and high noise margin with different supply voltages. More importantly, the inverter shows large voltage gain (~38) and small static power (Pico-Watts), paving the way for low power electronic system in 2D materials.

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“…In 2011, Ren et al first patterned graphene on paper substrates and demonstrated that graphene can emit sound 94. It was found that graphene has a significant flat frequency response in the wide ultrasound range ≈20–50 kHz.…”

Section: The Human‐like Senses and Feedbacksmentioning

confidence: 99%

“…It was found that graphene has a significant flat frequency response in the wide ultrasound range ≈20–50 kHz. Additionally, graphene exhibits ultra‐small heat capacity per unit area (HCPUA), more efficiently converting joule heating to sound waves 94, 95, 96, 97, 98, 99, 100. It has been also reported that single‐layer graphene (SLG) presents the lowest HCPUA,101 demonstrating more efficient than other materials.…”

Section: The Human‐like Senses and Feedbacksmentioning

confidence: 99%

Human‐Like Sensing and Reflexes of Graphene‐Based Films

et al. 2016

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Humans have numerous senses, wherein vision, hearing, smell, taste, and touch are considered as the five conventionally acknowledged senses. Triggered by light, sound, or other physical stimulations, the sensory organs of human body are excited, leading to the transformation of the afferent energy into neural activity. Also converting other signals into electronical signals, graphene‐based film shows its inherent advantages in responding to the tiny stimulations. In this review, the human‐like senses and reflexes of graphene‐based films are presented. The review starts with the brief discussions about the preparation and optimization of graphene‐based film, as where as its new progress in synthesis method, transfer operation, film‐formation technologies and optimization techniques. Various human‐like senses of graphene‐based film and their recent advancements are then summarized, including light‐sensitive devices, acoustic devices, gas sensors, biomolecules and wearable devices. Similar to the reflex action of humans, graphene‐based film also exhibits reflex when under thermal radiation and light actuation. Finally, the current challenges associated with human‐like applications are discussed to help guide the future research on graphene films. At last, the future opportunities lie in the new applicable human‐like senses and the integration of multiple senses that can raise a revolution in bionic devices.

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Graphene-on-Paper Sound Source Devices

Cited by 203 publications

References 40 publications

Observation of a giant two-dimensional band-piezoelectric effect on biaxial-strained graphene

Observation of a giant two-dimensional band-piezoelectric effect on biaxial-strained graphene

High-Performance WSe₂ Complementary Metal Oxide Semiconductor Technology and Integrated Circuits

Human‐Like Sensing and Reflexes of Graphene‐Based Films

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Graphene-on-Paper Sound Source Devices

Cited by 203 publications

References 40 publications

Observation of a giant two-dimensional band-piezoelectric effect on biaxial-strained graphene

Observation of a giant two-dimensional band-piezoelectric effect on biaxial-strained graphene

High-Performance WSe2 Complementary Metal Oxide Semiconductor Technology and Integrated Circuits

Human‐Like Sensing and Reflexes of Graphene‐Based Films

Contact Info

Product

Resources

About

High-Performance WSe₂ Complementary Metal Oxide Semiconductor Technology and Integrated Circuits