FRINK Linked Data Fragments server

Matches in SemOpenAlex for { <https://semopenalex.org/work/W3100753988> ?p ?o ?g. }

• W3100753988 endingPage "40618" @default.
• W3100753988 startingPage "40608" @default.
• W3100753988 abstract "Water in its various forms has been found to be one of the most abundant sources of energy on the planet after solar energy, and hydroelectric power plays a key role in renewable-energy supplies. Traditionally, harvesting tremendous amounts of hydrodynamic energy requires the deployment of complex, bulky, and expensive electromagnetic generators, which become inefficient at lower volumes of flowing or falling water, and then the energy is stored when there is an excess, but these techniques remain largely unperfected. Regardless of the diversity of development strategies, adopted methodologies, and working mechanisms, there are a wide range of energy scavengers, to effectively harness environmental friendly alternative energy sources. Robust, sustainable and technologically effective water energy harvesting devices, especially hydroelectric nanogenerators, are in the research spotlight globally, due to their numerous benefits to society, including cost effectiveness, clean and continuous electricity generation, and environmental applicability. Here the design and working mechanism involved in the development of a microporous polymer membrane assisted unique hydroelectric generator (MPA-HEG) based on triboelectrification and electrostatic induction phenomena is reported, which scavenges energy from continuously dripping water droplets sliding onto the surface of a hydrophobic microporous polymer membrane. MPA-HEG utilizes a very simple architecture that consists of a hydrophobic microporous polymer, poly(tetrafluoroethylene) (PTFE), membrane on a single-sided copper-clad laminate as a substrate and an aluminium electrode. Unlike other reported water energy harvesting devices with similar functionalities, the rational design of MPA-HEG does not necessitate any technologically complex structures to be embedded in the substrate. It has also been revealed that the interaction of water droplets on the smooth, water-resistant solid polymer surface in MPA-HEG switches 'ON' and connects the originally disconnected equivalent electrical components at the solid-liquid-solid interfaces, giving an uninterrupted electrical circuit, and transmuting the conservative interfacial effects into a bulk mechanism. Consequently, the instantaneous power output shows a vast increase over equivalent devices that are constrained either to triboelectric interfacial effects or moisture-induced electricity generation. This could serve the purpose of validating the inherent advantages of developing self-powered electronic devices, and this approach can also be effectively exploited for boosted power generation with realistic future applications." @default.
• W3100753988 created "2020-11-23" @default.
• W3100753988 creator A5027466187 @default.
• W3100753988 creator A5053178517 @default.
• W3100753988 creator A5064446575 @default.
• W3100753988 creator A5075511998 @default.
• W3100753988 date "2020-01-01" @default.
• W3100753988 modified "2023-09-30" @default.
• W3100753988 title "Microporous polymer membrane assisted water induced electricity generation based on triboelectrification and electrostatic induction" @default.
• W3100753988 cites W1000605845 @default.
• W3100753988 cites W1898417878 @default.
• W3100753988 cites W1965155074 @default.
• W3100753988 cites W1966587014 @default.
• W3100753988 cites W1973745957 @default.
• W3100753988 cites W2008107497 @default.
• W3100753988 cites W2015624574 @default.
• W3100753988 cites W2018323122 @default.
• W3100753988 cites W2018417587 @default.
• W3100753988 cites W2037881139 @default.
• W3100753988 cites W2038216093 @default.
• W3100753988 cites W2043184024 @default.
• W3100753988 cites W2063406628 @default.
• W3100753988 cites W2065853833 @default.
• W3100753988 cites W2070349998 @default.
• W3100753988 cites W2072137827 @default.
• W3100753988 cites W2078476783 @default.
• W3100753988 cites W2078919514 @default.
• W3100753988 cites W2078981803 @default.
• W3100753988 cites W2092615666 @default.
• W3100753988 cites W2097970185 @default.
• W3100753988 cites W2113269771 @default.
• W3100753988 cites W2137163426 @default.
• W3100753988 cites W2137422413 @default.
• W3100753988 cites W2138581904 @default.
• W3100753988 cites W2143734742 @default.
• W3100753988 cites W2145026532 @default.
• W3100753988 cites W2145396338 @default.
• W3100753988 cites W2146965765 @default.
• W3100753988 cites W2154707832 @default.
• W3100753988 cites W2156974809 @default.
• W3100753988 cites W2162940682 @default.
• W3100753988 cites W2168100296 @default.
• W3100753988 cites W2170752656 @default.
• W3100753988 cites W2232699504 @default.
• W3100753988 cites W2320626778 @default.
• W3100753988 cites W2336682422 @default.
• W3100753988 cites W2504524516 @default.
• W3100753988 cites W2574987849 @default.
• W3100753988 cites W2585355828 @default.
• W3100753988 cites W2785850796 @default.
• W3100753988 cites W2843738294 @default.
• W3100753988 cites W2898608289 @default.
• W3100753988 cites W2899525174 @default.
• W3100753988 cites W2921085362 @default.
• W3100753988 cites W2926834417 @default.
• W3100753988 cites W2944596307 @default.
• W3100753988 cites W2962974526 @default.
• W3100753988 cites W2971753410 @default.
• W3100753988 cites W2971844154 @default.
• W3100753988 cites W2982659874 @default.
• W3100753988 cites W3008931447 @default.
• W3100753988 cites W3048752895 @default.
• W3100753988 doi "https://doi.org/10.1039/d0ra07982k" @default.
• W3100753988 hasPubMedId "https://pubmed.ncbi.nlm.nih.gov/35519233" @default.
• W3100753988 hasPublicationYear "2020" @default.
• W3100753988 type Work @default.
• W3100753988 sameAs 3100753988 @default.
• W3100753988 citedByCount "12" @default.
• W3100753988 countsByYear W31007539882021 @default.
• W3100753988 countsByYear W31007539882022 @default.
• W3100753988 countsByYear W31007539882023 @default.
• W3100753988 crossrefType "journal-article" @default.
• W3100753988 hasAuthorship W3100753988A5027466187 @default.
• W3100753988 hasAuthorship W3100753988A5053178517 @default.
• W3100753988 hasAuthorship W3100753988A5064446575 @default.
• W3100753988 hasAuthorship W3100753988A5075511998 @default.
• W3100753988 hasBestOaLocation W31007539881 @default.
• W3100753988 hasConcept C105795698 @default.
• W3100753988 hasConcept C119599485 @default.
• W3100753988 hasConcept C121332964 @default.
• W3100753988 hasConcept C127413603 @default.
• W3100753988 hasConcept C159985019 @default.
• W3100753988 hasConcept C163258240 @default.
• W3100753988 hasConcept C171250308 @default.
• W3100753988 hasConcept C186370098 @default.
• W3100753988 hasConcept C188573790 @default.
• W3100753988 hasConcept C192562407 @default.
• W3100753988 hasConcept C2781155771 @default.
• W3100753988 hasConcept C33923547 @default.
• W3100753988 hasConcept C39432304 @default.
• W3100753988 hasConcept C423512 @default.
• W3100753988 hasConcept C521977710 @default.
• W3100753988 hasConcept C62520636 @default.
• W3100753988 hasConcept C80640880 @default.
• W3100753988 hasConcept C86381522 @default.
• W3100753988 hasConcept C98576551 @default.
• W3100753988 hasConceptScore W3100753988C105795698 @default.
• W3100753988 hasConceptScore W3100753988C119599485 @default.

• next