Your search keyword '"Saak, Clara-Magdalena"' showing total 10 results

1. Biological lipid hydration: distinct mechanisms of interfacial water alignment and charge screening for model lipid membranes.

Author

Saak, Clara-Magdalena, Dreier, Lisa B., Machel, Kevin, Bonn, Mischa, and Backus, Ellen H. G.

Abstract

Studying lipid monolayers as model biological membranes, we demonstrate that water molecules interfacing with different model membranes can display preferential orientation for two distinct reasons: due to charges on the membrane, and due to large dipole fields resulting from zwitterionic headgroups. This preferential water orientation caused by the charge or the dipolar field can be effectively neutralized to net-zero water orientation by introducing monolayer counter-charges (i.e. lipids with oppositely charged headgroups). Following the Gouy–Chapman model, the effect of monolayer surface charge on water orientation is furthermore strongly dependent on the electrolyte concentration and thus on the counterions in solution. In contrast, the effect of ions in the subphase on the dipolar alignment of water is zero. As a result, the capability of monolayer counter-charges to null the effect of dipolar orientation is strongly electrolyte-dependent. Notably, the different effects are additive for mixed charged/zwitterionic lipid systems occurring in nature. Specifically, for an E. coli lipid membrane extract consisting of both zwitterionic and negatively charged lipids, the water orientation can be explained by the sum of the constituents. Our results can be quantitatively reproduced using Gouy–Chapman theory, revealing the relatively straightforward electrostatic effects on the hydration of complex membrane interfaces. [ABSTRACT FROM AUTHOR]

Published

2024

2. Solvent and cosolute dependence of Mg surface enrichment in submicron aerosol particles.

Author

Pelimanni, Eetu, Saak, Clara-Magdalena, Michailoudi, Georgia, Prisle, Nønne, Huttula, Marko, and Patanen, Minna

Abstract

The formation of multicomponent aerosol particles from precursor solution droplets often involves segregation and surface enrichment of the different solutes, resulting in non-homogeneous particle structures and diverse morphologies. In particular, these effects can have a significant influence on the chemical composition of the particle–vapor interface. In this work, we investigate the bulk/surface partitioning of inorganic ions, Na+, Mg2 +, Ca2 +, Cl− and Br−, in atomiser-generated submicron aerosols using synchrotron radiation based X-ray photoelectron spectroscopy (XPS). Specifically, the chemical compositions of the outermost few nm thick surface layers of non-supported MgCl2/CaCl2 and NaBr/MgBr2 particles are determined. It is found that in MgCl2/CaCl2 particles, the relative abundance of the two species in the particle surface correlates well with their mixing ratio in the parent aqueous solution. In stark contrast, extreme surface enrichment of Mg2 + is observed in NaBr/MgBr2 particles formed from both aqueous and organic solution droplets, indicative of core–shell structures. Structural properties and hydration state of the particles are discussed. [ABSTRACT FROM AUTHOR]

Published

2022

3. Low-energy constraints on photoelectron spectra measured from liquid water and aqueous solutions.

Author

Malerz, Sebastian, Trinter, Florian, Hergenhahn, Uwe, Ghrist, Aaron, Ali, Hebatallah, Nicolas, Christophe, Saak, Clara-Magdalena, Richter, Clemens, Hartweg, Sebastian, Nahon, Laurent, Lee, Chin, Goy, Claudia, Neumark, Daniel M., Meijer, Gerard, Wilkinson, Iain, Winter, Bernd, and Thürmer, Stephan

Abstract

We report on the effects of electron collision and indirect ionization processes, occurring at photoexcitation and electron kinetic energies well below 30 eV, on the photoemission spectra of liquid water. We show that the nascent photoelectron spectrum and, hence, the inferred electron binding energy can only be accurately determined if electron energies are large enough that cross sections for quasi-elastic scattering processes, such as vibrational excitation, are negligible. Otherwise, quasi-elastic scattering leads to strong, down-to-few-meV kinetic energy scattering losses from the direct photoelectron features, which manifest in severely distorted intrinsic photoelectron peak shapes. The associated cross-over point from predominant (known) electronically inelastic to quasi-elastic scattering seems to arise at surprisingly large electron kinetic energies, of approximately 10–14 eV. Concomitantly, we present evidence for the onset of indirect, autoionization phenomena (occurring via superexcited states) within a few eV of the primary and secondary ionization thresholds. These processes are inferred to compete with the direct ionization channels and primarily produce low-energy photoelectrons at photon and electron impact excitation energies below ∼15 eV. Our results highlight that vibrational inelastic electron scattering processes and neutral photoexcitation and autoionization channels become increasingly important when photon and electron kinetic energies are decreased towards the ionization threshold. Correspondingly, we show that for neat water and aqueous solutions, great care must be taken when quantitatively analyzing photoelectron spectra measured too close to the ionization threshold. Such care is essential for the accurate determination of solvent and solute ionization energies as well as photoelectron branching ratios and peak magnitudes. [ABSTRACT FROM AUTHOR]

Published

2021

4. The effect of relative humidity on CaCl2 nanoparticles studied by soft X-ray absorption spectroscopy.

Author

Abid, Abdul Rahman, Reinhardt, Maximilian, Boudjemia, Nacer, Pelimanni, Eetu, Milosavljević, Aleksandar R., Saak, Clara-Magdalena, Huttula, Marko, Björneholm, Olle, and Patanen, Minna

Published

2021

5. Proton dynamics in molecular solvent clusters as an indicator for hydrogen bond network strength in confined geometries.

Author

Saak, Clara-Magdalena, Richter, Clemens, Unger, Isaak, Mucke, Melanie, Nicolas, Christophe, Hergenhahn, Uwe, Caleman, Carl, Huttula, Marko, Patanen, Minna, and Björneholm, Olle

Abstract

Hydrogen bonding leads to the formation of strong, extended intermolecular networks in molecular liquids such as water. However, it is less well-known how robust the network is to environments in which surface formation or confinement effects become prominent, such as in clusters or droplets. Such systems provide a useful way to probe the robustness of the network, since the degree of confinement can be tuned by altering the cluster size, changing both the surface-to-volume ratio and the radius of curvature. To explore the formation of hydrogen bond networks in confined geometries, here we present O 1s Auger spectra of small and large clusters of water, methanol, and dimethyl ether, as well as their deuterated equivalents. The Auger spectra of the clusters and the corresponding macroscopic liquids are compared and evaluated for an isotope effect, which is due to proton dynamics within the lifetime of the core hole (proton-transfer-mediated charge-separation, PTM-CS), and can be linked to the formation of a hydrogen bond network in the system. An isotope effect is observed in water and methanol but not for dimethyl ether, which cannot donate a hydrogen bond at its oxygen site. The isotope effect, and therefore the strength of the hydrogen bond network, is more pronounced in water than in methanol. Its value depends on the average size of the cluster, indicating that confinement effects change proton dynamics in the core ionised excited state. [ABSTRACT FROM AUTHOR]

Published

2020

6. Site-specific X-ray induced dynamics in liquid methanol.

Author

Saak, Clara-Magdalena, Unger, Isaak, Brena, Barbara, Caleman, Carl, and Björneholm, Olle

Abstract

Complex chemical and biochemical systems are susceptible to damage from ionising radiation. However, questions remain over the extent to which such damage is influenced by the nature of the surrounding chemical environment, which can consist of both hydrophobic and hydrophilic domains. To gain fundamental insight into the first crucial mechanistic steps of radiation damage in such systems, we need to understand the initial radiation response, i.e. dynamics occurring on the same timescale as electronic relaxation, which occur in these different environments. Amphiphilic molecules contain both hydrophobic and hydrophilic domains, but the propensity for charge delocalisation and proton dynamics to occur in these different domains has been largely unexplored so far. Here, we present carbon and oxygen 1s Auger spectra for liquid methanol, one of the simplest amphiphilic molecules, as well as its fully deuterated equivalent d4-methanol, in order to explore X-ray induced charge delocalisation and proton dynamics occurring on the few femtosecond timescale. Unexpectedly, we find a similar propensity for proton dynamics to occur at both the carbon and oxygen site within the lifetime of the core hole. Our results could serve as a model for decay processes that are likely to occur in other more complex amphiphilic systems. [ABSTRACT FROM AUTHOR]

Published

2019

7. Shifted equilibria of organic acids and bases in the aqueous surface region.

Author

Werner, Josephina, Persson, Ingmar, Björneholm, Olle, Kawecki, Delphine, Saak, Clara-Magdalena, Walz, Marie-Madeleine, Ekholm, Victor, Unger, Isaak, Valtl, Corina, Caleman, Carl, Öhrwall, Gunnar, and Prisle, Nønne L.

Abstract

Acid–base equilibria of carboxylic acids and alkyl amines in the aqueous surface region were studied using surface-sensitive X-ray photoelectron spectroscopy and molecular dynamics simulations. Solutions of these organic compounds were examined as a function of pH, concentration and chain length to investigate the distribution of acid and base form in the surface region as compared to the aqueous bulk. Results from these experiments show that the neutral forms of the studied acid–base pairs are strongly enriched in the aqueous surface region. Moreover, we show that for species with at least four carbon atoms in their alkyl-chain, their charged forms are also found to be abundant in the surface region. Using a combination of XPS and MD results, a model is proposed that effectively describes the surface composition. Resulting absolute surface concentration estimations show clearly that the total organic mole fractions in the surface region change drastically as a function of solution pH. The origin of the observed surface phenomena, hydronium/hydroxide concentrations in the aqueous surface region and why standard chemical equations, used to describe equilibria in dilute bulk solution are not valid in the aqueous surface region, are discussed in detail. The reported results are of considerable importance especially for the detailed understanding of properties of small aqueous droplets that can be found in the atmosphere. [ABSTRACT FROM AUTHOR]

Published

2018

8. Angle-resolved valence shell photoelectron spectroscopy of neutral nanosized molecular aggregates.

Author

Signorell, Ruth, Yoder, Bruce L., West, Adam H. C., Ferreiro, Jorge J., and Saak, Clara-Magdalena

Published

2014

9. Competition between proton transfer and intermolecular Coulombic decay in water.

Author

Richter, Clemens, Hollas, Daniel, Saak, Clara-Magdalena, Förstel, Marko, Miteva, Tsveta, Mucke, Melanie, Björneholm, Olle, Sisourat, Nicolas, Slavíček, Petr, and Hergenhahn, Uwe

Abstract

Intermolecular Coulombic decay (ICD) is a ubiquitous relaxation channel of electronically excited states in weakly bound systems, ranging from dimers to liquids. As it is driven by electron correlation, it was assumed that it will dominate over more established energy loss mechanisms, for example fluorescence. Here, we use electron-electron coincidence spectroscopy to determine the efficiency of the ICD process after 2a1 ionization in water clusters. We show that this efficiency is surprisingly low for small water clusters and that it gradually increases to 40-50% for clusters with hundreds of water units. Ab initio molecular dynamics simulations reveal that proton transfer between neighboring water molecules proceeds on the same timescale as ICD and leads to a configuration in which the ICD channel is closed. This conclusion is further supported by experimental results from deuterated water. Combining experiment and theory, we infer an intrinsic ICD lifetime of 12-52 fs for small water clusters. Interatomic or intermolecular Coulombic decay is responsible for the generation of slow electrons in clusters and biological samples. Here the authors use electron-electron coincidence detection to find the competitive roles of proton transfer and ICD that occur on similar time scales in water clusters. [ABSTRACT FROM AUTHOR]

Published

2018

10. ChemInform Abstract: Angle-Resolved Valence Shell Photoelectron Spectroscopy of Neutral Nanosized Molecular Aggregates.

Author

Signorell, Ruth, Yoder, Bruce L., West, Adam H. C., Ferreiro, Jorge J., and Saak, Clara‐Magdalena

Published

2014