Consequences of Interfacial Interactions on Adsorption and Adhesion

Singla, Saranshu

January 2018

No description available.

Materials Science

Polymers

adsorption

adhesion

sum frequency generation

spider silk

graphene

ice-nucleation

SFG

self-assembled monolayer

SAM

water

interfacial interactions

humidity

acid-base

friction

headgroups

non-linear optics

competitive adsorption

glycoproteins

Theoretical modeling and computer simulations of protein adsorption onto soft polymeric layers

Yigit, Cemil

30 May 2016

Proteinadsorption ist in vielen biotechnologischen Anwendungen ubiquitär und ein zentrales Forschungsfeld in der Physik der weichen Materie. Das Verstehen der treibenden Kräfte hinter der Proteinadsorption würde zu einer besseren Kontrolle des Adsorptionsprozesses führen und die Entwicklung von Biosystemen mit beispielloser Funktionalität ermöglichen. In der vorliegenden Arbeit wird die Proteinadsorption an weichen polymerartigen Biomaterialien sowie deren physikalische Wechselwirkungen unter Verwendung von zwei unterschiedlichen neu entwickelten Ansätzen theoretisch untersucht. Im ersten Teil wird ein neues mehrkomponentiges kooperatives Bindungsmodell entwickelt, um die Gleichgewichts-Adsorption von Proteinen auf Mikrogelen zu beschreiben. Es war somit möglich, die wahre treibende Kraft der Proteinadsorption zu identifizieren, die hauptsächlich elektrostatischen Ursprungs ist. Eine Errungenschaft des kooperativen Bindungsmodells ist die Vorhersage der kompetitiven Proteinadsorption und -desorption auf das Mikrogel, die auf thermodynamischen Parametern der Adsorption von Proteinen einzelner Sorten basiert. Vergleiche zwischen Experimenten mit binären Proteinmischungen und theoretischen Berechnungen zeigten sehr gute Übereinstimmungen. Der zweite Teil fokussiert auf Protein-Wechselwirkungen mit Polyelektrolyten, um Adsorptionsprozesse auf mikroskopischer Ebene zu erklären. Dafür wurden geladene fleckige Partikel konstruiert und als Proteinmodelle verwendet, während ein einfaches Kugel-Feder-Modell für das Polyelektrolyt und Polyelektrolytbürste benutzt wurde. Ein zentraler Aspekt war die Bestimmung der freien Energie, das Potential der mittleren Kraft (PMF), für die Komplexbildung der beiden Bestandteile mit Vergleichen zur Modellentwicklungen. Die Simulationsergebnisse legen ein komplexes Wechselspiel von elektrostatischen Kräften und Ionenfreisetzungsmechanismen dar, die für die starken attraktiven Wechselwirkungen in den PMFs verantwortlich sind. / Protein adsorption is ubiquitous in many biotechnological applications and has become a central research field in soft matter. Understanding the driving forces behind protein adsorption would allow a better control of the adsorption process and the development of biosystems with unprecedented functionality. In this thesis, protein adsorption onto soft polymeric biomaterials and their physical interactions is studied theoretically by using two different and newly developed approaches. In the first part, a novel multi-component cooperative binding model is developed to describe the equilibrium adsorption of proteins onto microgels. It was thus possible to correctly identify the true driving force behind the protein adsorption which was found to be mainly of electrostatic origin. A key achievement by the cooperative binding model is the prediction of competitive protein adsorption and desorption onto the microgel that is based on thermodynamic parameters related to single-type protein adsorption without any variable parameters. Comparisons between experimental data of binary protein mixtures and theoretical calculations have shown excellent agreements. The second part is focused on protein interactions with polyelectrolyte materials to elucidate adsorption processes on a microscopic level. For this purpose, charged patchy particles are constructed and used as protein models while a simple bead-spring model is employed for the polyelectrolyte and polyelectrolyte brush. A central aspect was the determination of the associated free energy, the potential of mean force (PMF), on the complex formation between the two constituents with comparisons to theoretical model developments. The simulation results evidenced a complex interplay of electrostatic forces and ion release mechanisms to be responsible for the strong attractive interactions observed in the PMFs.

Proteinadsorption

Mikrogele

kompetitive Adsorption

kooperative Effekte

Langevin Dynamik

gleich geladenen Komplexe

fleckige Partikel

Polyelektrolytbürste

protein adsorption

microgels

cooperativity effects

competitive adsorption

Langevin dynamics

like-charged complexation

patchy particles

polyelectrolyte brush

530 Physik

29 Physik, Astronomie

VE 7027

UV 9500

ddc:530

Role of adsorption in catalysis : applications of NMR relaxometry

Arias Vecino, Pablo

January 2015

The work described in this thesis focuses on the effects that adsorption processes on catalytic surfaces pose in controlling key steps that can affect and control reaction pathways. To that, the development of Nuclear Magnetic Resonance (NMR) relaxometry methods and the comparison with traditional catalytic was performed with a series of C5 and C6 unsaturated hydrocarbons on two different alumina supports, γ- and θ-Al2O3. The developed techniques were applied in the study of liquid phase selective hydrogenation of citral on 5% Pt/SiO2. Infrared (IR) spectroscopy, volumetric adsorption isotherms, dynamic isotherms via a Tapered Element Oscillating Microbalance (TEOM), temperature programmed desorption (TPD) as well as 13C T1 NMR and 1H 2D T1-T2 relaxometry methods were employed. Energies of adsorption as a function of coverage were obtained via adsorption isotherms and the particular surface adsorbate interactions were described with IR spectroscopy. For example, 1-pentyne showed the strongest interaction with the alumina (94 kJ mol-1) while 1-pentene presented a weaker interaction (46 kJ mol-1) on θ-Al2O3. Desorption energies obtained from TPD ranged 85 – 130 kJ mol-1, irrespective of the adsorbate. Reactivity of the aluminas was captured with TPD, TEOM and NMR relaxometry. Interaction of adsorbates with hydrocarbon occurred predominantly on weak adsorption sites. 13C NMR T1 relaxometry provided in addition atom-specific adsorbate-adsorbent interaction strengths, showing the molecular geometry of adsorption, and applied in co adsorption measurements. The selective hydrogenation of citral as a model α,β-unsaturated aldehyde and the effect of different solvents on the activity and product distribution was studied at 298 and 373 K. A series of polar protic, polar aprotic and non polar solvents was investigated. Results showed higher initial reaction rates in non polar solvents but higher selectivities towards desired products on polar protic solvents. Solvent used also affected by product formation. The strong variations in reaction rates and selectivities reported were related with adsorbate catalyst interactions, as well as solvent reactant interactions. For example, adsorption isotherms showed that ethanol notably reduced the adsorption capacity of citral as compared with hexane, related with the rate differences observed. ATR-IR measurements indicated solvent citral interactions were solely present in polar protic solvents in line with higher yields of geraniol and nerol. Finally, 13C T1 NMR and 1H 2D T1-T2 correlation experiments determined that the geometry of adsorption of citral, influenced by solvent, affected product selectivity, and that product adsorption affected selectivity and deactivation.

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