PERTPROTONDYN

Aqueous Proton Mobility near Ions and in Nano-Confined Geometries

 Coordinatore STICHTING VOOR FUNDAMENTEEL ONDERZOEK DER MATERIE - FOM 

 Organization address address: Van Vollenhovenlaan 659
city: UTRECHT
postcode: 3527 JP

contact info
Titolo: Mr.
Nome: Bart
Cognome: Van Leijen
Email: send email
Telefono: +31 20 7547100
Fax: 31207547290

 Nazionalità Coordinatore Netherlands [NL]
 Totale costo 191˙675 €
 EC contributo 191˙675 €
 Programma FP7-PEOPLE
Specific programme "People" implementing the Seventh Framework Programme of the European Community for research, technological development and demonstration activities (2007 to 2013)
 Code Call FP7-PEOPLE-2011-IEF
 Funding Scheme MC-IEF
 Anno di inizio 2012
 Periodo (anno-mese-giorno) 2012-03-01   -   2014-02-28

 Partecipanti

# participant  country  role  EC contrib. [€] 
1    STICHTING VOOR FUNDAMENTEEL ONDERZOEK DER MATERIE - FOM

 Organization address address: Van Vollenhovenlaan 659
city: UTRECHT
postcode: 3527 JP

contact info
Titolo: Mr.
Nome: Bart
Cognome: Van Leijen
Email: send email
Telefono: +31 20 7547100
Fax: 31207547290

NL (UTRECHT) coordinator 191˙675.40

Mappa


 Word cloud

Esplora la "nuvola delle parole (Word Cloud) per avere un'idea di massima del progetto.

protons    techniques    studied    drs    infrared    water    ir    charge    nanopools    ions    linear    network    powerful    chemical    transport    dynamics    solutions    hydrated    sub    time    host    spectroscopy    rotational    broadband    local    aqueous    critical    ion    nanochannels    hydration    hydrogen    mobility    ensembles    spectroscopic    transfer    scientists    biological    proton    mid    ionic    solutes    molecular    co    confined    affects    technique    team    geometries    patterns    environments    natural    pertprotondyn    small    mechanisms   

 Obiettivo del progetto (Objective)

'Protons in liquid water posses an anomalously high mobility compared to other ions. This high mobility results from the fact that hydrated protons are not transported as intact units, i.e. by so called mass transport, but rather form defects that diffuse “structurally” through the water hydrogen-bond network. As such, aqueous proton transfer strongly relies on the structure and dynamics of the water network. Many natural and technologically relevant proton transfer reactions occur in the direct presence of ions, proteins or in geometrically confined volumes (e.g. nanopools, nanochannels). We propose to study how the nature and concentration of ionic co-solutes affects the dominant hydration patterns, conversion time-scales and local reactivity of the proton. We will also study how the structuring of the water network in nanopools and nanochannels affects the rate and mechanism of proton transfer. This will be experimentally realized by powerful spectroscopic techniques including femtosecond mid-infrared pump-probe spectroscopy and time-domain terahertz spectroscopy, which are available at the proposed host organization AMOLF (FOM) in Amsterdam, The Netherlands. Compared to conventional linear spectroscopies, these non-linear techniques are ideally suited to discriminate between the large number of sub-ensembles of local hydration patterns of the aqueous proton present in solution. The techniques will allow the measurement of the evolution of these sub-ensembles in time. The researcher, Dr. Ottosson, has a strong background in X-ray spectroscopic investigations of aqueous solutions from his Ph.D. work at Uppsala University, Sweden, making him an ideal candidate for this challenging project. With the guidance of the host scientist, Prof. H.J. Bakker – a world-leading expert in time-resolved studies of water and aqueous solutions – we believe that the chances for success are high.'

Introduzione (Teaser)

Proton transfer, and the associated current (flow of charge), is critical to numerous biological and chemical processes. Scientists have provided groundbreaking insight into mechanisms affecting mobility in aqueous solutions with advanced spectroscopy.

Descrizione progetto (Article)

A proton is a positively charged ion, a hydrogen atom that has lost its one and only electron. Compared to other ions, protons have an abnormally high mobility in water that is explained by interactions with the water network itself.

Mechanisms of transport in bulk water have been studied in great detail. However, in most processes, protons co-exist with other solutes and traverse interesting geometries such as ion channels and other architectures.

Scientists have now added a wealth of knowledge to the less understood processes in these complex and strongly perturbed environments. EU support of the 'Aqueous proton mobility near ions and in nano-confined geometries' (PERTPROTONDYN) project gave them the opportunity they were seeking.

Powerful non-linear spectroscopic techniques formed the basis of measurement. The team significantly improved capabilities of an advanced broadband technique (high-frequency broadband dielectric relaxation spectroscopy (DRS)) that provides important information about molecular dipole moments and free charge carriers. They also used an infrared (IR) technique to visualise rotational mobility of water hydroxyl (-OH) groups.

The divalent cations calcium (Ca2+) and magnesium (Mg2+) are important components of biological fluids. DRS revealed for the first time their influence on the number of water molecules affected by the presence of protons.

Studying proton mobility when confined to very small spaces is difficult because the generated current is so small it is nearly impossible to measure. DRS also provided a window on the unexpected polarisation response of protons constrained in nanometre-sized water droplets.

Researchers studied the effects of Nafion membrane hydration on the rotational mobility of water and the mobility of protons and sodium ions. Increased understanding is relevant to crucial processes, including energy transport in biological systems and ionic mechanisms in fuel cells.

Finally, the team exploited DRS together with fast mid-IR spectroscopy to elucidate the molecular dynamics of a common inhibitory neurotransmitter and urea, an important chemical found in urine. Novel results are in various stages of publication.

PERTPROTONDYN has provided important insight into the transport mechanisms of hydrated protons in complex environments that are so critical to many natural and industrially relevant processes.

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