Edible energy storage devices
A Coplanar Edible Rechargeable Battery with Enhanced Capacity
Edible rechargeable batteries represent a novel opportunity for energy storage, which currently involves the use of toxic materials. Being entirely made of food-derived materials and additives, such batteries open the way to electronic systems characterized by
An Edible Supercapacitor Based on Zwitterionic Soy
Introducing an edible soy sauce-based gel with impressive ionic performance provides a promising alternative to conventional energy storage devices, enabling the advancement of cutting-edge ingestible
An Edible and Nutritive Zinc-Ion Micro
Miniature energy storage devices simultaneously combining high energy output and bioavailability could greatly promote the practicability of green, safe, and nontoxic in vivo detection, such as for noninvasive monitoring or
An Edible and Nutritive Zinc-Ion Micro-supercapacitor in the
An Edible and Nutritive Zinc-Ion Micro-supercapacitor in the Stomach with Ultrahigh Energy Density. Kaiyue Chen, Liben Yan, Yukai Sheng, Yu Ma, Liangti Qu, Miniature energy storage devices simultaneously combining high energy output and bioavailability could greatly promote the practicability of green, safe, and nontoxic in vivo detection
An Edible and Nutritive Zinc-Ion Micro
Miniature energy storage devices simultaneously combining high energy output and bioavailability could greatly promote the practicability of green, safe, and nontoxic in vivo detection, such as for noninvasive monitoring or treatment in the gastrointestinal tract, which is still challenging. Herein, we report ingestible and nutritive zinc-ion-based hybrid micro
Edible Transistors: from Fabrication to Tips for Storage
These results show that the combination of ethyl cellulose and activated carbon, and the control over their mixture, allow on-demand edible devices for energy generation and storage, serving
(PDF) Edible and Nutritive Electronics: Materials, Fabrications
He received his Ph.D. in solid mechanics from Tsinghua University in 2001. His research interests include mechanics and devices of novel electronics, such as stretchable electronics and edible electronics, along with energy storage devices and mechanical metamaterials. 2.1. Materials for Making Electronic Components 2.1.1.
Towards edible robots and robotic food | Nature Reviews Materials
Several edible supercapacitors, another type of storage component, with energy density of up to 3.36 mWh g −1 (ref. 103) have been implemented by combining a variety of edible materials, such as
An Edible and Nutritive Zinc-Ion Micro-supercapacitor in the
Miniature energy storage devices simultaneously combining high energy output and bioavailability could greatly promote the practicability of green, safe, and nontoxic in vivo detection, such as for noninvasive monitoring or treatment in the gastrointestinal tract, which is still challenging.
Autonomous Chemistry Enabling Environment-Adaptive
Energy harvesting devices (solar cells, biofuel cells, triboelectric nanogenerators, etc.), and other electronic components (transistors, actuators, sensors, etc.) are also expected to generate an all-in-one and fully self-adaptable device. 106 – 111 Moving forward, we believe that synergy between novel chemical designs and advanced device
An Edible and Nutritive Zinc-Ion Micro-supercapacitor in the
Miniature energy storage devices simultaneously combining high energy output and bioavailability could greatly promote the practicability of green, safe, and nontoxic in vivo detection, such as for noninvasive monitoring or treatment in the gastrointestinal tract, which is still challenging. Herein,
An Edible and Nutritive Zinc-Ion Micro
This work provides an example for the design and fabrication of edible energy storage devices with high performance. Miniature energy storage devices simultaneously combining high energy output and bioavailability could greatly promote the practicability of green, safe, and nontoxic in vivo detection, such as for noninvasive monitoring or
Edible cellulose-based conductive composites for triboelectric
Their use as electrodes in edible energy harvesting and storage devices with promising figures of merits, combined with simple and scalable fabrication schemes, shows a concrete path to fulfill the energetic requirements of envisioned edible systems, from edible smart pills, to food tags and control units in edible actuators (e.g. TENGs and SC
An Edible and Nutritive Zinc-Ion Micro-supercapacitor in the
Miniature energy storage devices simultaneously combining high energy output and bioavailability could greatly promote the practicability of green, safe, and nontoxic in vivo detection, such as for noninvasive monitoring or treatment in the gastrointestinal tract, which is still challenging. Herein, we report ingestible and nutritive zinc-ion-based hybrid micro-supercapacitors (ZMSCs
Recent progress in self-healable energy harvesting and storage devices
Electronic devices with multiple features bring in comfort to the way we live. However, repeated use causes physical as well as chemical degradation reducing their lifetime. The self-healing ability is the most crucial property of natural systems for survival in unexpected situations and variable environment
Edible Electronics: The Vision and the Challenge
3.4 Power Supply: Energy Storage Devices and Harvesting Technologies. Powering edible electronic devices is a formidable challenge. An efficient power supply embedded in the device is essential for the operation of most of the
The Integration of Triboelectric Nanogenerators and
Supercapacitors, also known as ultracapacitors or electrochemical capacitors, are energy storage devices that bridge the gap between conventional capacitors and batteries. They possess high power density, Lamanna et al. explore the use of ethyl cellulose and activated carbon composites for edible energy harvesting devices,
An Edible Supercapacitor Based on Zwitterionic Soy Sauce‐Based
biodegradable, and edible energy storage devices. [9,20–25] Supe r-capacitors (SCs) are excellent candidates for energy storage in. edible electronics due to their long lifetime, high power densi-
Edible Cellulose-based Conductive Composites for Triboelectric
These results show that the combination of ethyl cellulose and activated carbon, and the control over their mixture, allow on-demand edible devices for energy generation and storage, serving
Towards Edible Electronic Systems for Biomedical and Food
Edible electronics envisions a technology that is safe for ingestion, environmentally friendly, and cost-effective. Differently from "ingestible" electronics, it aims at realizing electronic devices that are degraded within the body after performing their function, either digested or even metabolized, thus removing any retention hazard.
Materials Advances for Next-Generation Ingestible Electronic Medical
Anticipated challenges and future opportunities in next-generation devices are also outlined with a focus on the need for novel materials. Specific focus is granted to new materials for energy storage, flexible electronic components, and biodegradable circuitry for potential use in edible electronic devices.
Flexible Energy Storage Devices to Power the Future
Consequently, there is an urgent demand for flexible energy storage devices (FESDs) to cater to the energy storage needs of various forms of flexible products. FESDs can be classified into three categories based on spatial dimension, all of which share the features of excellent electrochemical performance, reliable safety, and superb flexibility.
Autonomous Chemistry Enabling Environment
Energy harvesting devices (solar cells, biofuel cells, triboelectric nanogenerators, etc.), and other electronic components (transistors, actuators, sensors, etc.) are also expected to generate an all-in-one and fully self
Energy storage
Storage capacity is the amount of energy extracted from an energy storage device or system; usually measured in joules or kilowatt-hours and their multiples, it may be given in number of hours of electricity production at power plant
Flexible electrochemical energy storage devices and related
The rapid consumption of fossil fuels in the world has led to the emission of greenhouse gases, environmental pollution, and energy shortage. 1,2 It is widely acknowledged that sustainable clean energy is an effective way to solve these problems, and the use of clean energy is also extremely important to ensure sustainable development on a global scale. 3–5 Over the past
Flexible Energy Storage Devices to Power the Future
Consequently, there is an urgent demand for flexible energy storage devices (FESDs) to cater to the energy storage needs of various forms of flexible products. FESDs can be classified into three categories based on spatial
An Edible and Nutritive Zinc-Ion Micro-supercapacitor in the
Miniature energy storage devices simultaneously combining high energy output and bioavailability could greatly promote the practicability of green, safe, and nontoxic in vivo detection, such as
Edible cellulose-based conductive composites for triboelectric
TENGs and SCs offering strategies for the development of fully edible energy harvesting and storage devices. In particular, we paid attention to the sustainability and non-toxicity of the preparation process, aiming at a scalable solution-based approach adopting only water and ethanol. The AC/EC composite films were fabricated by dispersing the
An Edible and Nutritive Zinc-Ion Micro-supercapacitor in the
Miniature energy storage devices simultaneously combining high energy output and bioavailability could greatly promote the practicability of green, safe, and nontoxic in vivo detection, such as for noninvasive monitoring or treatment in the gastrointestinal tract, which is still challenging. consisting of an edible active carbon
An Edible and Nutritive Zinc-Ion Micro-supercapacitor in the
Mentioning: 11 - Miniature energy storage devices simultaneously combining high energy output and bioavailability could greatly promote the practicability of green, safe, and nontoxic in vivo detection, such as for noninvasive monitoring or treatment in the gastrointestinal tract, which is still challenging. Herein, we report ingestible and nutritive zinc-ion-based hybrid micro
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