Resultado final
This article will target general audience and will focus on the potential of the technology developed within the HyPhOE project
Web-site /social network coverageProject will have a dedicated website. The website will serve as a communication platform between the partners and a tool for dissemination of the project results including social media outlets. We will introduce the logo of HyPhOE.
Press release of the project kick-offPress release of the project kick off that will be distributed nationally by each partner and internationally in order to inform the public on this EU funded action.
Synthesis of multifunctional molecules encompassing a second function along with the electron connectivity Among the functions selective binding of specific cells increase of solar absorption window release of growth factors Focus will be given on sustaining proton and small ion transfer across the cell wall
Demonstration of energy storage via material production in diatoms algaeThis will be a demonstration of energy productionstorage related to diatoms algae Light collection by photosynthetic microorganisms can be used not only to store and produce energy but also to produce materials This is the case of diatoms microalgae which as the output of the photosynthetic metabolism are able to produce nanostructured biosilica that have many interesting applications as material for photonics and biomedicine The material will be explored in energy storage applications
At the end of the project the EAB will provide an evaluation report covering themost important findings and achievements of HyPhOE throughout the projects lifetime The report will also include suggestions for dissemination and exploitation of project outcomes
Paper on extraction of photosynthetic current from bacteriaThis paper will summarise our efforts on energy harvesting from simpler photosynthetic organisms and especially the extraction of photosynthetic current through the materials and chemical modification developed in WP12
Paper on electronic functionalization of rooted plantsThis paper will summarise the efforts on introducing electronic and smart materials developed in WP1 into the structure of rooted plants In order to do so we will use various methods Transpiration the material is uptaken by the xylem vasculature of the plant and is organized within the transport channels b vacuum infiltration the material is introduced in the porous space of leaves through the stomata pores c Roots materials will be coated or takenup by the roots to the internal structure of the plant Materials will be functionalized to enhance their penetration through the roots
Methodologies for the bioconjugation and binding-site identificationIdentification of the site of interactionbinding of the synthesized molecules with the photosynthetic organisms UniBaCNR
Paper on plant response to e-fertilizerThis paper will present the results on plant response to efertilizerThe eFertilizer will be based on a PEDOTbased conducting polymer bearing moieties composed of nitrogen eg ammonium ions developed in WP1 The mechanism of nitrogen release is based on the reductionoxidation of PEDOT In order to control the nitrogen release the number of ammonium species per polymer chain the crosslinking of PEDOT and the charachteristics type of the electrical stimuli and will be tuned and their efficiency to release ammonium will be evaluated We will evaluate the nitrogen gradients in soil and gel medium using various stimulation protocols constant release accelerated release and pulsing in various frequencies The electronic control offers flexibility on the release rate of the nitrogen Bordeaux INP LiUAs a next step we will evaluate the electronically controlled nitrogen response in various plants Hydroponically grown plants will be subjected to various changes in nitrogen availability through electronic control Then the release of compounds from root surfaces on potgrown plants will be monitored This will be based on a recently developed technique for monitoring of plantsoil interactions microdialysis The ultimate goal is to identifying key molecules that are released by the plant in order to design better fertilizers The experiments will be performed with various types of plants cereals ornamental plants and tree seedlings and in different growth settings This will enable generalization of results and help designing different release functions from the materials used for fertilization SLU
Paper on enhancing the light absorption of photosynthetic organismsThis paper will summarise our efforts on energy harvesting from simpler photosynthetic organisms and especially the extension of light harvesting through the materials and chemical modification developed in WP12
Report on integration of functionalised -CO2 sensor plant in real life settingsIntegration of functionalized plants in a smallscale simulated real life setting The plants will be placed in a specific area laboratory setting with elevated CO2 simulating a real life setting We will monitor the efficiency of the plants to capture CO2 in simulated real life settings LiU SLUWe will also perform a feasibility study for upscaling the integration of such plants in real life settings such as urban areas LiU SLU Bordeaux INP
Report on developing autonomous energy systemsBased on the results of WP3 and WP4 we will write a report on the possibility of developing an autonomous energy system based on functionalized photosynthetic organisms that couple energy harvesting and storage
Paper on feedback regulated bioelectronics for controlling adaptation of plants to droughtThis paper will present the results on the feedback regulated bioelectronics system for controlling adaptation of plants to drought We will develop an organic electronic ion pump OEIP for abscisic acid ABA delivery Preliminary work at LiU has shown that ABA can be delivered by fiber based OEIPs Such OEIPS will be used for targeting the xylem of the model tree hybrid aspen Populus tremula x tremuloides mimicking the natural distribution route of the ABA hormoneWe will develop printed capacitive humidity sensors The sensors will be used to monitor soil water content simultaneously with controlled ABA release to the xylem transpiration stream The sensors will be realised by printing interdigitated coplanar electrodes on plastic flexible substrates The active area will be covered with a polymeric watersensitive layer whose dielectric permittivity is a function of the water content of the surrounding atmosphere Another approach consists of using the same capacitive structure but fabricated on a hygroscopic substrate such as paper UPDFinally we will evaluate the electronically controlled ABA responses in greenhouse grown aspen trees These experiments will allow specific ABA responses to be studied in isolation without a generic drought effect To assess plant responses to the treatments we will monitor stomatal conductance and photosynthetic efficiency using a Licor instrument and also assay gene expression changes in developing wood and leaves to identify genes responding to the treatments Such genes will become targets of more detailed molecular biology studies to understand the transcriptional networks underlying drought stress and tolerance We will also test the hypothesis whether it is possible to prime trees for drought stress by applying first an ABA pulse to transpiration stream and then reducing the water potential of the soil SLU LiU
Paper on enzymatic biofuel cell in plantaeThis paper will present our efforts for achieving an enzymatic biofuel cell in plantaeIn this type of fuel cells enzymes play the role of the catalyst The high selectivity of the enzyme allows fabrication of fuel cells where the fuel and oxidant are introduced as a mixture without the need of a separator Glucose and oxygen are both products of photosynthesis making this fuel oxidant pair an ideal choice for the development of a biofuel cell in plants We aim to integrate the fuel cell within the structure of the plant and utilize the plants endogenous sugars and O2 We will biofunctionalize the in vivo manufactured electrodes WP12 with the enzymes and mediators to fabricate the bioanode and biocathode of the fuel cell and characterize its performance LiU UPDiderot SLU
Paper on energy storage in plantsThis paper will present the results on energy storage in plantsFor this purpose we will develop ia biosupercapacitor and ii a supercapacitor in plants iThe biofuel concept described in WP4 will be explored for the development of a biosupercapacitor in plants UPD will follow a novel and original approach which has been described in the most recent literature inclusion within the classical structure of the device of enzymes able to selfcharge each side of the capacitor resulting in a hybrid biofuel cellbiosupercapacitor Upon glucose oxidationoxygen reduction electrons are progressively transferred tofrom the redox hydrogel so that the anodic side of the hydrogel is reduced while the cathodic side of the hydrogel is oxidized following a Nernstian behaviour potential given by the Os3Os2 ratio the redox potentials of the anode and the cathode progressively split forming two separated Os halfcells To increase specific charge the Os hydrogel will be modified with electron rich molecules pyrene perylene in order to immobilize SWCNTs or graphene GR within the matrix UPDii Development of supercapacitors in plantLiU has demonstrated a proof of concept of in vivo manufactured supercapacitors in the stem of plants based on ePlants technology In addition it has demonstrated electrochromic pixels fabricated in the leaves of the plants We will extend these concepts for development of charge storage devices in plants To add to the intrinsic specific capacitance of the organic electronic materials LiU will be functionalized with redox molecules Depending on the location of the supercapacitor different geometries will be used 1D wires in the stem 2D in leaves and 3D in bulky leaves and roots LiU
Protocol on implanting devices in plantsThe bioelectronic devices will be microfabricated and will be implanted in specific tissues in plants This is very new for the plant biology community so specific methods and protocols have to be developed LiU SLU
Market analysis report and report on exploitationA market analysis report and report on exploitation will be prepared and followed to track and manage the innovation activities IPR marketing and business plans spinoffs new cooperation or collaboration agreements etc within the consortium during the project period
Paper for plant based CO2 environmental filter and sensorThis paper will present the results on the development of a plant based CO2 environmental filter and sensorFirst we will functionalize the plant for CO2 uptake The polyaminebased smart material that will be developed in WP1 will be infiltrated in the leaves of plants infiltration will be developed in WP2 and will be used for capturing the CO2 of the atmosphere Initial characterizations via imaging techniques optical and electron microscopy as well as spectroscopic characterizations FTIR UVvis will be performed to confirm the successful infiltration and spatial distribution of the polymers in the leaves The plant capability of capturing CO2 will be evaluated in controlled atmosphere The capture of CO2 by the infiltrated polymers will be monitored via IR spectroscopy An infrared analysis gas cell will be used exsitu to corroborate and calibrate if necessary the invivo CO2 absorption measurements LiU SLU Bordeaux INP
A Data Management Plan will be prepared to describe which data will be generated, collected and processed within the HyPhOE project.
Publicaciones
Autores:
Mihai Irimia-Vladu, Yasin Kanbur, Fausta Camaioni, Maria Elisabetta Coppola, Cigdem Yumusak, Cristian Vlad Irimia, Angela Vlad, Alessandra Operamolla, Gianluca M. Farinola, Gian Paolo Suranna, Natalia González-Benitez, Maria Carmen Molina, Luis Fernando Bautista, Heinz Langhals, Barbara Stadlober, Eric Daniel Głowacki, Niyazi Serdar Sariciftci
Publicado en:
Chemistry of Materials, Edición 31/17, 2019, Página(s) 6315-6346, ISSN 0897-4756
Editor:
American Chemical Society
DOI:
10.1021/acs.chemmater.9b01405
Autores:
Michele Di Lauro, Simona Gatta, Carlo A. Bortolotti, Valerio Beni, Vitaliy Parkula, Sofia Drakopoulou, Martina Giordani, Marcello Berto, Francesco Milano, Tobias Cramer, Mauro Murgia, Angela Agostiano, Gianluca M. Farinola, Massimo Trotta, Fabio Biscarini
Publicado en:
Advanced Electronic Materials, Edición 6/1, 2020, Página(s) 1900888, ISSN 2199-160X
Editor:
WILEY‐VCH Verlag GmbH & Co. KGaA
DOI:
10.1002/aelm.201900888
Autores:
Marco Lo Presti, Maria Michela Giangregorio, Roberta Ragni, Livia Giotta, Maria Rachele Guascito, Roberto Comparelli, Elisabetta Fanizza, Roberto R. Tangorra, Angela Agostiano, Maria Losurdo, Gianluca M. Farinola, Francesco Milano, Massimo Trotta
Publicado en:
Advanced Electronic Materials, Edición 6/7, 2020, Página(s) 2000140, ISSN 2199-160X
Editor:
WILEY‐VCH Verlag GmbH & Co. KGaA
DOI:
10.1002/aelm.202000140
Autores:
Chiara Diacci, Tayebeh Abedi, Jee Woong Lee, Erik O. Gabrielsson, Magnus Berggren, Daniel T. Simon, Totte Niittylä, Eleni Stavrinidou
Publicado en:
iScience, Edición 24/1, 2021, Página(s) 101966, ISSN 2589-0042
Editor:
Elsevier
DOI:
10.1016/j.isci.2020.101966
Autores:
Danilo Vona, Roberta Ragni, Emiliano Altamura, Paola Albanese, Maria Michela Giangregorio, Stefania Roberta Cicco, Gianluca Maria Farinola
Publicado en:
Applied Sciences, Edición 11/8, 2021, Página(s) 3327, ISSN 2076-3417
Editor:
MDPI AG
DOI:
10.3390/app11083327
Autores:
Gábor Méhes, Arghyamalya Roy, Xenofon Strakosas, Magnus Berggren, Eleni Stavrinidou, Daniel T. Simon
Publicado en:
Advanced Science, Edición 7/15, 2020, Página(s) 2000641, ISSN 2198-3844
Editor:
WILEY-VCH
DOI:
10.1002/advs.202000641
Autores:
Daniele Mantione, Emin Istif, Gwennael Dufil, Lorenzo Vallan, Daniela Parker, Cyril Brochon, Eric Cloutet, Georges Hadziioannou, Magnus Berggren, Eleni Stavrinidou, Eleni Pavlopoulou
Publicado en:
ACS Applied Electronic Materials, Edición 2/12, 2020, Página(s) 4065-4071, ISSN 2637-6113
Editor:
American Chemical Society
DOI:
10.1021/acsaelm.0c00861
Autores:
Emin Istif, Daniele Mantione, Lorenzo Vallan, Georges Hadziioannou, Cyril Brochon, Eric Cloutet, Eleni Pavlopoulou
Publicado en:
ACS Applied Materials & Interfaces, Edición 12/7, 2020, Página(s) 8695-8703, ISSN 1944-8244
Editor:
American Chemical Society
DOI:
10.1021/acsami.9b21058
Autores:
Gabriella Buscemi, Danilo Vona, Rossella Labarile, Roberta Ragni, Francesco Milano, Gianluca M. Farinola, Massimo Trotta
Publicado en:
MRS Advances, Edición 6/10, 2021, Página(s) 265-269, ISSN 2059-8521
Editor:
Cambridge Core Cambridge University Press
DOI:
10.1557/s43580-021-00003-6
Autores:
Walid Ait-Mammar, Samia Zrig, Nathalie Bridonneau, Vincent Noël, Eleni Stavrinidou, Benoît Piro, Giorgio Mattana
Publicado en:
MRS Advances, Edición 5/18-19, 2020, Página(s) 965-973, ISSN 2059-8521
Editor:
Cambridge University Press
DOI:
10.1557/adv.2020.86
Autores:
Daniela Parker, Yohann Daguerre, Gwennaël Dufil, Daniele Mantione, Eduardo Solano, Eric Cloutet, Georges Hadziioannou, Torgny Näsholm, Magnus Berggren, Eleni Pavlopoulou, Eleni Stavrinidou
Publicado en:
Materials Horizons, 2021, ISSN 2051-6347
Editor:
RCS
DOI:
10.1039/d1mh01423d
Autores:
Francesco Milano, Marco Lopresti, Danilo Vona, Gabrielle Buscemi, Mariangela Cantore, Gianluca M. Farinola, Massimo Trotta
Publicado en:
MRS Advances, Edición 5/45, 2020, Página(s) 2299-2307, ISSN 2059-8521
Editor:
Cambridge Core Cambridge University Press
DOI:
10.1557/adv.2020.275
Autores:
Gwennaël Dufil, Daniela Parker, Jennifer Y. Gerasimov, Thuc-Quyen Nguyen, Magnus Berggren, Eleni Stavrinidou
Publicado en:
Journal of Materials Chemistry B, Edición 8/19, 2020, Página(s) 4221-4227, ISSN 2050-7518
Editor:
Royal Society of Chemistry
DOI:
10.1039/d0tb00212g
Autores:
Giuseppina Tommasini, Gwennaël Dufil, Federica Fardella, Xenofon Strakosas, Eugenio Fergola, Tobias Abrahamsson, David Bliman, Roger Olsson, Magnus Berggren, Angela Tino, Eleni Stavrinidou, Claudia Tortiglione
Publicado en:
Bioactive Materials, 2021, ISSN 2452-199X
Editor:
Elsevier
DOI:
10.1016/j.bioactmat.2021.08.025
Autores:
Gabriella Leone, Gabriel De la Cruz Valbuena, Stefania Roberta Cicco, Danilo Vona, Emiliano Altamura, Roberta Ragni, Egle Molotokaite, Michela Cecchin, Stefano Cazzaniga, Matteo Ballottari, Cosimo D’Andrea, Guglielmo Lanzani, Gianluca Maria Farinola
Publicado en:
Scientific Reports, Edición 11/1, 2021, ISSN 2045-2322
Editor:
Nature Publishing Group
DOI:
10.1038/s41598-021-84690-z
Autores:
Gabriella Buscemi, Francesco Milano, Danilo Vona, Gianluca M. Farinola, Massimo Trotta
Publicado en:
MRS Advances, Edición 5/45, 2020, Página(s) 2309-2316, ISSN 2059-8521
Editor:
Cambridge Core Cambridge University Press
DOI:
10.1557/adv.2020.281
Autores:
Nicola Zappimbulso, Maria Annunziata M. Capozzi, Andrea Porcheddu, Gianluca M. Farinola, Angela Punzi
Publicado en:
ChemSusChem, Edición 14/5, 2021, Página(s) 1363-1369, ISSN 1864-5631
Editor:
Wiley - V C H Verlag GmbbH & Co.
DOI:
10.1002/cssc.202002763
Autores:
Chiara Diacci, Jee Woong Lee, Per Janson, Gwennaël Dufil, Gábor Méhes, Magnus Berggren, Daniel T. Simon, Eleni Stavrinidou
Publicado en:
Advanced Materials Technologies, 2019, Página(s) 1900262, ISSN 2365-709X
Editor:
WILEY-VCH
DOI:
10.1002/admt.201900262
Autores:
Iwona Bernacka‐Wojcik, Miriam Huerta, Klas Tybrandt, Michal Karady, Mohammad Yusuf Mulla, David J. Poxson, Erik O. Gabrielsson, Karin Ljung, Daniel T. Simon, Magnus Berggren, Eleni Stavrinidou
Publicado en:
Small, 2019, Página(s) 1902189, ISSN 1613-6810
Editor:
Wiley - V C H Verlag GmbbH & Co.
DOI:
10.1002/smll.201902189
Autores:
R. Ragni, G. Leone, G. Rizzo, S. la Gatta, F. Milano, M. Trotta, G. M. Farinola
Publicado en:
MRS Advances, Edición 4/22, 2019, Página(s) 1293-1298, ISSN 2059-8521
Editor:
Cambridge Core, Cambridge University Press
DOI:
10.1557/adv.2019.68
Autores:
Roberta Ragni, Gabriella Leone, Simona la Gatta, Giorgio Rizzo, Marco Lo Presti, Vincenzo De Leo, Francesco Milano, Massimo Trotta, G. M. Farinola
Publicado en:
MRS Advances, Edición 4/20, 2019, Página(s) 1143-1148, ISSN 2059-8521
Editor:
Cambridge Core, Cambridge University Press
DOI:
10.1557/adv.2018.640
Autores:
Marco Lo Presti, Danilo Vona, Gabriella Leone, Giorgio Rizzo, Roberta Ragni, Stefania R. Cicco, Francesco Milano, Fabio Palumbo, Massimo Trotta, Gianluca M. Farinola
Publicado en:
MRS Advances, Edición 4/31-32, 2019, Página(s) 1741-1748, ISSN 2059-8521
Editor:
Cambridge Core, Cambridge University Press
DOI:
10.1557/adv.2019.246
Autores:
Francesco Milano; Angela Punzi; Roberta Ragni; Massimo Trotta; Gianluca M. Farinola
Publicado en:
Advanced Functional Materials, Edición vol. 29, issue 21, 2019, ISSN 1616-301X
Editor:
John Wiley & Sons Ltd.
DOI:
10.1002/adfm.201970141
Autores:
Angela Punzi, Francesco Babudri, Gianluca M. Farinola
Publicado en:
European Journal of Organic Chemistry, Edición 2020/24, 2020, Página(s) 3526-3541, ISSN 1434-193X
Editor:
John Wiley & Sons Ltd.
DOI:
10.1002/ejoc.201901847
Autores:
Michele Di Lauro, Gabriella Buscemi, Michele Bianchi, Anna De Salvo, Marcello Berto, Stefano Carli, Gianluca Maria Farinola, Luciano Fadiga, Fabio Biscarini, Massimo Trotta
Publicado en:
MRS Advances, Edición 5/18-19, 2020, Página(s) 985-990, ISSN 2059-8521
Editor:
Cambridge Core Cambridge University Press
DOI:
10.1557/adv.2019.491
Autores:
Gabriella Buscemi, Danilo Vona, Massimo Trotta, Francesco Milano, Gianluca M. Farinola
Publicado en:
Advanced Materials Technologies, 2021, Página(s) 2100245, ISSN 2365-709X
Editor:
WILEY‐VCH Verlag GmbH & Co. KGaA
DOI:
10.1002/admt.202100245
Autores:
Gabriella Buscemi, Danilo Vona, Roberta Ragni, Roberto Comparelli, Massimo Trotta, Francesco Milano, Gianluca Maria Farinola
Publicado en:
Advanced Sustainable Systems, Edición 5/11, 2021, Página(s) 2000303, ISSN 2366-7486
Editor:
WILEY‐VCH Verlag GmbH & Co. KGaA
DOI:
10.1002/adsu.202000303
Autores:
Danilo Vona, Gabriella Buscemi, Roberta Ragni, Mariangela Cantore, Stefania R. Cicco, Gianluca M. Farinola, Massimo Trotta
Publicado en:
MRS Advances, Edición 5/18-19, 2020, Página(s) 957-963, ISSN 2059-8521
Editor:
Cambridge Core Cambridge University Press
DOI:
10.1557/adv.2019.466
Autores:
Cristina Sissa, Anna Painelli, Francesca Terenziani, Massimo Trotta, Roberta Ragni
Publicado en:
Physical Chemistry Chemical Physics, Edición 22/1, 2020, Página(s) 129-135, ISSN 1463-9076
Editor:
Royal Society of Chemistry
DOI:
10.1039/c9cp05473a
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