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Statements

Subject Item
n2:7E13024
rdf:type
n3:Projekt
rdfs:seeAlso
http://www.isvav.cz/projectDetail.do?rowId=7E13024
dcterms:description
The goal of the project is to create a programmable microscale electronic chemistry forming a bridge between electronic and chemical computing. Microscopic reactive electronic agents will contain circuit elements on autonomous pairwise self-assembling microchips (target =< 100 µm) in aqueous solution with reversible nanoscale coatings, which we call lablets, to direct reversible association between them to form twin lablets, called gemlabs, and control entry to and chemical reactions in the enclosed transient reaction compartments. The lablet device integrates transistors, supercapacitors, energy transducers, sensors and actuators, involving electronically constructed nanofilms, and will be essentially genetically encoded, translating electronic signals into constructive chemical processing and recording the results of this processing. This will provide an unconventional form of computation that microscopically links reaction processing with computation in autonomous mobile smart reactors. This is a next major step towards the integration of computation and reactive chemical processing in electronically programmable systems: it corresponds to a radical integration of autonomous chemical experimentation and represents a novel form of computation intertwined with construction. The self-assembling smart micro reactors can be programmed for molecular amplification and other chemical processing pathways, that start from complex mixtures, concentrate and purify chemicals, perform reactions in programmed cascades, sense completion, and transport and release products to defined locations. The project defines a continuous achievable path towards this ambitious goal, making use of a novel pairwise local communication strategy to overcome the limitations of current smart dust and autonomous sensor network communication. The 8 groups from 8 countries incl. NZ are all pioneers in the multidisciplinary areas required to achieve the project goals, with a common grounding in IT. The goal of the project is to create a programmable microscale electronic chemistry forming a bridge between electronic and chemical computing. Microscopic reactive electronic agents will contain circuit elements on autonomous pairwise self-assembling microchips (target =< 100 µm) in aqueous solution with reversible nanoscale coatings, which we call lablets, to direct reversible association between them to form twin lablets, called gemlabs, and control entry to and chemical reactions in the enclosed transient reaction compartments. The lablet device integrates transistors, supercapacitors, energy transducers, sensors and actuators, involving electronically constructed nanofilms, and will be essentially genetically encoded, translating electronic signals into constructive chemical processing and recording the results of this processing. This will provide an unconventional form of computation that microscopically links reaction processing with computation in autonomous mobile smart reactors. This is a next major step towards the integration of computation and reactive chemical processing in electronically programmable systems: it corresponds to a radical integration of autonomous chemical experimentation and represents a novel form of computation intertwined with construction. The self-assembling smart micro reactors can be programmed for molecular amplification and other chemical processing pathways, that start from complex mixtures, concentrate and purify chemicals, perform reactions in programmed cascades, sense completion, and transport and release products to defined locations. The project defines a continuous achievable path towards this ambitious goal, making use of a novel pairwise local communication strategy to overcome the limitations of current smart dust and autonomous sensor network communication. The 8 groups from 8 countries incl. NZ are all pioneers in the multidisciplinary areas required to achieve the project goals, with a common grounding in IT.
dcterms:title
Microscale Chemically Reactive Electronic Agents Microscale Chemically Reactive Electronic Agents
skos:notation
7E13024
n4:aktivita
n11:7E
n4:celkovaStatniPodpora
n5:celkovaStatniPodpora
n4:celkoveNaklady
n5:celkoveNaklady
n4:datumDodatniDoRIV
2015-04-02+02:00
n4:druhSouteze
n15:RP
n4:duvernostUdaju
n20:C
n4:fazeProjektu
n21:101089254
n4:hlavniObor
n16:CI
n4:kategorie
n19:AP
n4:klicovaSlova
Self Assembly; CMOS; MEMS; DNA; Computing; Self Repair; Electronic microreactors; Hybrid systems; Elektrochemistry; Electrochemistry; Constructive computing; Chemical sensing; Chemical robotics; Evolution; Bioelectronics
n4:partnetrHlavni
n14:orjk%3A22340
n4:pocetKoordinujicichPrijemcu
0
n4:pocetPrijemcu
1
n4:pocetSpoluPrijemcu
0
n4:pocetVysledkuRIV
0
n4:pocetZverejnenychVysledkuVRIV
0
n4:posledniUvolneniVMinulemRoce
2014-03-20+01:00
n4:prideleniPodpory
n10:MSMT-42111%2F2013
n4:sberDatUcastniciPoslednihoRoku
n6:2015
n4:sberDatUdajeProjZameru
n6:2015
n4:statusZobrazovaneFaze
n13:DRRVK
n4:typPojektu
n9:P
n4:ukonceniReseni
2015-08-31+02:00
n4:zahajeniReseni
2013-01-01+01:00
n4:zivotniCyklusProjektu
n18:ZBK
n4:vyzva
n17:FP7-ICT-2011-8
n4:klicoveSlovo
Hybrid systems DNA Chemical sensing Constructive computing Self Assembly MEMS Computing Electronic microreactors CMOS Elektrochemistry Self Repair Evolution Chemical robotics Electrochemistry