Harvesting biomechanical energy is an important route for providing electricity to sustainably drive wearable electronics, which currently still use batteries and therefore need to be charged or replaced/disposed frequently. Here we report an approach that can continuously power wearable electronics only by human motion, realized through a triboelectric nanogenerator (TENG) with optimized materials and structural design. Fabricated by elastomeric materials and a helix inner electrode sticking on a tube with the dielectric layer and outer electrode, the TENG has desirable features including flexibility, stretchability, isotropy, weavability, water-resistance and a high surface charge density of 250 μC m−2. With only the energy extracted from walking or jogging by the TENG that is built in outsoles, wearable electronics such as an electronic watch and fitness tracker can be immediately and continuously powered.
Triboelectric nanogenerators (TENG) are a possible power source for wearable electronics, but the conventional electrode materials for TENG are metals such as Cu and Al that are easy to be oxidized or corroded in some harsh environments. In this paper, metal electrode material is replaced by an electrical conducting polymer, polypyrrole (PPy), for the first time. Moreover, by utilizing PPy with micro/nanostructured surface as the triboelectric layer, the charge density generated is significantly improved, more superior to that of TENG with metals as the triboelectric layer. As this polymer‐based TENG is further integrated with PPy‐based supercapacitors, an all‐plastic‐materials based self‐charging power system is built to provide sustainable power with excellent long cycling life. Since the environmental friendly materials are adopted and the facile electrochemical deposition technique is applied, the new self‐charging power system can be a practical and low cost power solution for many applications.
Multifunctional peptide-polymer hybrid materials have been applied as efficient and biocompatible quantum-dot coating materials. Significant pH responsiveness (e.g., an influence of the pH on the quantum yields of the peptide-polymer/QDs) was found and is attributed to conformational rearrangements of the peptide backbone.
Highly luminescent quantum dot beads
(QBs) were synthesized by
encapsulating CdSe/ZnS and used for the first time as immunochromatographic
assay (ICA) signal amplification probe for ultrasensitive detection
of aflatoxin B1 (AFB1) in maize. The challenges
to using high brightness QBs as probes for ICA are smooth flow of
QBs and nonspecific binding on nitrocellulose (NC) membrane, which
are overcome by unique polymer encapsulation of quantum dots (QDs)
and surface blocking method. Under optimal conditions, the QB-based
ICA (QB-ICA) sensor exhibited dynamic linear detection of AFB1 in maize extract from 5 to 60 pg mL–1,
with a median inhibitory concentration (IC50) of 13.87
± 0.16 pg mL–1, that is significantly (39-fold)
lower than those of the QD as a signal probe (IC50 = 0.54
± 0.06 ng mL–1). The limit of detection (LOD)
for AFB1 using QB-ICA sensor was 0.42 pg mL–1 in maize extract, which is approximately 2 orders of magnitude better
than those of previously reported gold nanoparticle based immunochromatographic
assay (AuNP-ICA) and is even comparable with or better than the conventional
enzyme-linked immunosorbent assay (ELISA) method. The performance
and practicability of our QB-ICA sensor were validated with a commercial
ELISA kit and further confirmed with liquid chromatography tandem
mass spectrometry (LC–MS/MS). Given its efficient signal amplification
performance, the proposed QB-ICA offers great potential for rapid,
sensitive, and cost-effective quantitative detection of analytes in
food safety monitoring.
A soft, stretchable, and fully enclosed self-charging power system is developed by seamlessly combining a stretchable triboelectric nanogenerator with stretchable supercapacitors, which can be subject to and harvest energy from almost all kinds of large-degree deformation due to its fully soft structure. The power system is washable and waterproof owing to its fully enclosed structure and hydrophobic property of its exterior surface. The power system can be worn on the human body to effectively scavenge energy from various kinds of human motion, and it is demonstrated that the wearable power source is able to drive an electronic watch. This work provides a feasible approach to design stretchable, wearable power sources and electronics.
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