Your search keyword '"ÍONS"' showing total 49,931 results

1. Electron-driven processes in enantiomeric forms of glutamic acid initiated by low-energy resonance electron attachment.

Author

Pshenichnyuk, Stanislav A., Asfandiarov, Nail L., Rakhmeyev, Rustam G., Komolov, Alexei S., and Tereshchenko, Oleg E.

Subjects

*IONS, *ELECTRON paramagnetic resonance, *GLUTAMIC acid, *ANIONS, *MOLECULAR orbitals

Abstract

Low-energy (0–14 eV) resonance electron interaction and fragment species produced by dissociative electron attachment (DEA) for enantiomeric forms of glutamic acid (Glu) are studied under gas-phase conditions by means of DEA spectroscopy and density functional theory calculations. Contrary to a series of amino acids studied earlier employing the DEA technique, the most abundant species are not associated with the elimination of a hydrogen atom from the parent molecular negative ion. Besides this less intense closed-shell [Glu – H]– fragment, only two mass-selected negative ions, [Glu – 19]– and [Glu – 76]–, are detected within the same electron energy region, with the yield maximum observed at around 0.9 eV. This value matches well the energy of vertical electron attachment into the lowest normally empty π* COOH molecular orbital of Glu located at 0.88 eV according to the present B3LYP/6-31G(d) calculations. Although the detection of asymmetric DEA properties a priori is not accessible under the present experimental conditions, "chirality non-conservation" can be associated with some decay channels. Evidently, the measured spectra for the L- and D-forms are found to be identical, the results, nevertheless, being of interest for the forthcoming experiments utilizing spin-polarized electron beam as a chiral factor in the framework of conventional DEA technique. [ABSTRACT FROM AUTHOR]

Published

2024

2. Electrolytes in conducting nanopores: Revisiting constant charge and constant potential simulations.

Author

Reinauer, Alexander, Kondrat, Svyatoslav, and Holm, Christian

Subjects

*IONIC structure, *ELECTRODES, *ELECTROLYTES, *IONS, *DENSITY

Abstract

Simulating electrolyte–electrode systems poses challenges due to the need to account for the electrode's response to ion movements in order to maintain a constant electrode potential, which slows down the simulations. To circumvent this, computationally more efficient constant charge (CC) simulations are sometimes employed. However, the accuracy of CC simulations in capturing the behavior of electrolyte–electrode systems remains unclear, especially for microporous electrodes. Herein, we consider electrolyte-filled slit nanopores and systematically analyze the in-pore ion structure and diffusivity using CC and constant potential simulations. Our results indicate that CC simulations provide comparable pore occupancies at high bulk ion densities and for highly charged pores, but they fail to accurately describe the ion structure and dynamics, particularly in quasi-2D (single-layer) pores and at low ion densities. We attribute these results to the superionic state emerging in conducting nanoconfinement and its interplay with excluded volume interactions. [ABSTRACT FROM AUTHOR]

Published

2024

3. Absence of dimerization in Seff = 1/2 skew chain multiferroic Co2V2O7.

Author

Cao, J. J., Ouyang, Z. W., Li, Z. R., Wang, L., Chen, Y. J., Liu, X. C., Zhang, W. J., and Xia, Z. C.

Subjects

*CARBON dioxide, *DIMERIZATION, *MAGNETIZATION, *IONS, *MOTIVATION (Psychology)

Abstract

Motivated by the multiferroic effects and quantum magnetization plateaus in the skew chain antiferromagnets T 2 V 2 O 7 (T = Ni, Co), we have conducted a detailed density function theoretical study on Co 2 V 2 O 7. The results show that the nearest-neighbor interchain interaction (J 3 / k B = − 35.57 K) is not much greater than the intrachain interactions (J 1 / k B = − 19.54 K and J 2 / k B = 27.55 K), showing the absence of interchain dimerization of the Co ions. This indicates that the "dimer+monomer" model used for Ni 2 V 2 O 7 [Cao et al., Phys. Rev. B 106, 184409 (2022)] is no longer applicable to Co 2 V 2 O 7. Finally, the exact diagonalization of spin Hamiltonian, including anisotropic exchanges, produces the experimentally observed 1/2 and 3/4 magnetization plateaus. [ABSTRACT FROM AUTHOR]

Published

2024

4. Absence of dimerization in Seff = 1/2 skew chain multiferroic Co2V2O7.

Author

Cao, J. J., Ouyang, Z. W., Li, Z. R., Wang, L., Chen, Y. J., Liu, X. C., Zhang, W. J., and Xia, Z. C.

Subjects

CARBON dioxide, DIMERIZATION, MAGNETIZATION, IONS, MOTIVATION (Psychology)

Abstract

Motivated by the multiferroic effects and quantum magnetization plateaus in the skew chain antiferromagnets T 2 V 2 O 7 (T = Ni, Co), we have conducted a detailed density function theoretical study on Co 2 V 2 O 7. The results show that the nearest-neighbor interchain interaction (J 3 / k B = − 35.57 K) is not much greater than the intrachain interactions (J 1 / k B = − 19.54 K and J 2 / k B = 27.55 K), showing the absence of interchain dimerization of the Co ions. This indicates that the "dimer+monomer" model used for Ni 2 V 2 O 7 [Cao et al., Phys. Rev. B 106, 184409 (2022)] is no longer applicable to Co 2 V 2 O 7. Finally, the exact diagonalization of spin Hamiltonian, including anisotropic exchanges, produces the experimentally observed 1/2 and 3/4 magnetization plateaus. [ABSTRACT FROM AUTHOR]

Published

2024

5. Low-energy atomic and molecular hydrogen ion interaction with low-work function electride 12CaO · 7Al2O3.

Author

Yamaoka, Hitoshi, Tanaka, Nozomi, Nishiwaki, Mayuko, Yamada, Ippei, Sasao, Mamiko, Matsumoto, Yoshikatsu, Tsumori, Katsuyoshi, and Wada, Motoi

Subjects

*ATOMIC hydrogen, *MOLECULAR beams, *HYDROGEN ions, *CATIONS, *IONS

Abstract

To efficiently generate H − ions from positive atomic or molecular hydrogen beams injected onto a solid surface, it has been suggested to use a material with a low-work function as the target material. However, it is not clear under what conditions the most efficient H − production is realized for incident beam parameters or reflection angles. Therefore, we studied the interaction between low-energy atomic and molecular hydrogen beams (less than 1 keV/nucleon) with a low-work function electride 12CaO ⋅ 7 A l 2 O 3 (C12A7). The production ratio of H − to H + ions from the C12A7 electride was much higher than Mo targets with higher work functions, especially at smaller incident and smaller reflection angles. The H − to H + production ratio slightly increased as the incident energies were decreased, but there was no significant difference between the electride and Mo targets. These results indicate that smaller incident angles and lower beam energies of the incident hydrogen beam are favorable for the enhancement of the production ratio of H − to H + ions in C12A7. The higher production ratio appeared at the vertical beam energies less than on the order of 100 eV, where quantum mechanical processes may become important. [ABSTRACT FROM AUTHOR]

Published

2024

6. Ion association behaviors in the initial stage of calcium carbonate formation: An ab initio study.

Author

Li, Yue, Zhang, Jiarui, Zeng, Hongbo, and Zhang, Hao

Subjects

*CALCIUM carbonate, *ION pairs, *ATMOSPHERIC nucleation, *AB-initio calculations, *DENSITY functional theory, *IONS, *OCEAN acidification

Abstract

In this work, we performed static density functional theory calculations and ab initio metadynamics simulations to systematically investigate the association mechanisms and dynamic structures of four kinds of ion pairs that could be formed before the nucleation of CaCO3. For Ca2+– H C O 3 − and Ca2+– C O 3 2 − pairs, the arrangement of ligands around Ca2+ evolves between the six-coordinated octahedral structure and the seven-coordinated pentagonal bipyramidal structure. The formation of ion pairs follows an associative ligand substitution mechanism. Compared with H C O 3 − , C O 3 2 − exhibits a stronger affinity to Ca2+, leading to the formation of a more stable precursor phase in the prenucleation stage, which promotes the subsequent CaCO3 nucleation. In alkaline environments, excessive OH− ions decrease the coordination preference of Ca2+. In this case, the formation of Ca(OH)+– C O 3 2 − and Ca(OH)2– C O 3 2 − pairs favors the dissociative ligand substitution mechanism. The inhibiting effects of OH− ion on the CaCO3 association can be interpreted from two aspects, i.e., (1) OH− neutralizes positive charges on Ca2+, decreases the electrostatic interactions between Ca2+ and C O 3 2 − , and thus hinders the formation of the CaCO3 monomer, and (2) OH− decreases the capacity of Ca2+ for accommodating O, making it easier to separate Ca2+ and C O 3 2 − ions. Our findings on the ion association behaviors in the initial stage of CaCO3 formation not only help scientists evaluate the impact of ocean acidification on biomineralization but also provide theoretical support for the discovery and development of more effective approaches to manage undesirable scaling issues. [ABSTRACT FROM AUTHOR]

Published

2024

7. Insights into the structure and dynamics of K+ ions at the muscovite–water interface from machine learning potential simulations.

Author

Raman, Abhinav S. and Selloni, Annabella

Subjects

*MACHINE learning, *IONS, *ACTIVATION energy, *TRANSPORT theory, *ION exchange (Chemistry)

Abstract

The surfaces of many minerals are covered by naturally occurring cations that become partially hydrated and can be replaced by hydronium or other cations when the surface is exposed to water or an aqueous solution. These ion exchange processes are relevant to various chemical and transport phenomena, yet elucidating their microscopic details is challenging for both experiments and simulations. In this work, we make a first step in this direction by investigating the behavior of the native K+ ions at the interface between neat water and the muscovite mica (001) surface with ab-initio-based machine learning molecular dynamics and enhanced sampling simulations. Our results show that the desorption of the surface K+ ions in pure ion-free water has a significant free energy barrier irrespective of their local surface arrangement. In contrast, facile K+ diffusion between mica's ditrigonal cavities characterized by different Al/Si orderings is observed. This behavior suggests that the K+ ions may favor a dynamic disordered surface arrangement rather than complete desorption when exposed to deionized water. [ABSTRACT FROM AUTHOR]

Published

2024

8. Redox potentials in ionic liquids: Anomalous behavior?

Author

Renfro, Chloe A., Hymel, John H., and McDaniel, Jesse G.

Subjects

*SOLVATION, *REDUCTION potential, *IONIC liquids, *FUSED salts, *IONS

Abstract

Redox potentials depend on the nature of the solvent/electrolyte through the solvation energies of the ionic solute species. For concentrated electrolytes, ion solvation may deviate significantly from the Born model predictions due to ion pairing and correlation effects. Recently, Ghorai and Matyushov [J. Phys. Chem. B 124, 3754–3769 (2020)] predicted, on the basis of linear response theory, an anomalous trend in the solvation energies of room temperature ionic liquids, with deviations of hundreds of kJ/mol from the Born model for certain size solutes/ions. In this work, we computationally evaluate ionic solvation energies in the prototypical ionic liquid, 1-butyl-3-methylimidazolium tetrafluoroborate (BMIM/BF4), to further explore this behavior and benchmark several of the approximations utilized in the solvation energy predictions. For comparison, we additionally compute solvation energies within acetonitrile and molten NaCl salt to illustrate the limiting behavior of purely dipolar and ionic solvents. We find that the overscreening effect, which results from the inherent charge oscillations of the ionic liquid, is substantially reduced in magnitude due to screening from the dipoles of the molecular ions. Therefore, for the molten NaCl salt, for which the ions do not have permanent dipoles, modulation of ionic solvation energies from the overscreening effect is most significant. The conclusion is that ionic liquids do indeed exhibit unique solvation behavior due to peak(s) in the electrical susceptibility caused by the ion shell structure; redox potential shifts for BMIM/BF4 are of more modest order ∼0.1 V, but may be larger for other ionic liquids that approach molten salt behavior. [ABSTRACT FROM AUTHOR]

Published

2024

9. Two co-existing and opposing mechanisms of proton transfer in one-dimensional open-end water chains.

Author

Yang, Xinrui, Yu, Famin, Wang, Lu, Liu, Rui, Xin, Yue, Li, Rui, Shi, Yulei, and Wang, Zhigang

Subjects

*ION channels, *PROTONS, *IONS, *FUEL cells, *ELECTROSTATIC interaction

Abstract

The proton transport in one-dimensional (1D) confined water chains has been extensively studied as a model for ion channels in cell membrane and fuel cell. However, the mechanistic understanding of the proton transfer (PT) process in 1D water chains remains incomplete. In this study, we demonstrate that the two limiting structures of the hydrated excess proton, H5O2+ (Zundel) and H3O+ (linear H7O3+), undergo a change in dominance as the water chain grows, causing two co-existing and opposing PT mechanisms. Specifically, H5O2+ is stable in the middle of the chain, whereas H3O+ serves as a transition state (TS). Except for this region, H3O+ is stabilized while H5O2+ serves as a TS. The interaction analysis shows that the electrostatic interaction plays a crucial role in the difference in PT mechanisms. Our work fills a knowledge gap between the various PT mechanisms reported in bulk water and long 1D water chains, contributing to a deeper understanding of biological ion channels at the atomic level. [ABSTRACT FROM AUTHOR]

Published

2024

10. Ab initio spectroscopy and thermochemistry of the platinum hydride ions, PtH+ and PtH−.

Author

Irikura, Karl K.

Subjects

*THERMOCHEMISTRY, *DIATOMIC molecules, *ELECTRON affinity, *THERMODYNAMIC functions, *PHOTODETACHMENT threshold spectroscopy, *IONS, *SPIN-orbit interactions

Abstract

Rovibrational levels of low-lying electronic states of the gas-phase, diatomic molecules, PtH+ and PtH−, are computed on potential-energy functions obtained by using a hybrid spin–orbit configuration-interaction procedure. PtH− has a well-separated Σ 0 + + 1 ground state, while the first two electronic states of PtH+ ( Σ 0 + + 1 and 3Δ3) are nearly degenerate. Combining the experimental photoelectron (PE) spectra of PtH− with theoretical photodetachment spectroscopy leads to an improved value for the electron affinity of PtH, EA(PtH) = (1.617 ± 0.015) eV. When PtH− is a product of photodissociation of PtHCO2−, its PE spectrum is broad because of rotational excitation. Temperature-dependent thermodynamic functions and thermochemistry of dissociation are computed from the theoretical energy levels. Previously published energetic quantities for PtH+ and PtH− are revised. The ground 1Σ+ term of PtH+ is not well described using single-reference theory. [ABSTRACT FROM AUTHOR]

Published

2024

11. Absorption and fluorescence spectroscopy of cold proflavine ions isolated in the gas phase.

Author

Lindkvist, Thomas Toft, Kjær, Christina, Langeland, Jeppe, Vogt, Emil, Kjaergaard, Henrik G., and Nielsen, Steen Brøndsted

Subjects

*ION mobility spectroscopy, *FLUORESCENCE spectroscopy, *TIME-dependent density functional theory, *IONS, *ABSORPTION spectra, *ION traps

Abstract

Proflavine, a fluorescent cationic dye with strong absorption in the visible, has been proposed as a potential contributor to diffuse interstellar bands (DIBs). To investigate this hypothesis, it is essential to examine the spectra of cold and isolated ions for comparison. Here, we report absorption spectra of proflavine ions, trapped in a liquid-nitrogen-cooled ion trap filled with helium-buffer gas, as well as fluorescence spectra to provide further information on the intrinsic photophysics. We find absorption- and fluorescence-band maxima at 434.2 ± 0.1 and 434.7 ± 0.3 nm, corresponding to a Stokes shift of maximum 48 cm−1, which indicates minor differences between ground-state and excited-state geometries. Based on time-dependent density functional theory, we assign the emitting state to S2 as its geometry closely resembles that of S0, whereas the S1 geometry differs from that of S0. As a result, simulated spectra involving S1 exhibit long Franck-Condon progressions, absent in the experimental spectra. The latter displays well-resolved vibrational features, assigned to transitions involving in-plane vibrational modes where the vibrational quantum number changes by one. Dominant transitions are associated with vibrations localized on the NH2 moieties. Experiments repeated at room temperature yield broader spectra with maxima at 435.5 ± 1 nm (absorption) and 438.0 ± 1 nm (fluorescence). We again conclude that prevalent fluorescence arises from S2, i.e., anti-Kasha behavior, in agreement with previous work. Excited-state lifetimes are 5 ± 1 ns, independent of temperature. Importantly, we exclude the possibility that a narrow DIB at 436.4 nm originates from cold proflavine cations as the band is redshifted compared to our absorption spectra. [ABSTRACT FROM AUTHOR]

Published

2024

12. Ion solvation free energy calculations based on first-principles molecular dynamics thermodynamic integration.

Author

Lin, Chao, He, Xiaojun, Xi, Cong, Zhang, Qianfan, and Wang, Lin-Wang

Subjects

*MOLECULAR dynamics, *SOLVATION, *CRYSTAL defects, *ION energy, *IONS, *SMALL molecules

Abstract

Numerous electrochemistry reactions require the precise calculation of the ion solvation energy. Despite the significant progress in the first-principles calculations for crystals and defect formation energies for solids, the liquid system free energy calculations still face many challenges. Ion solvation free energies can be calculated via different semiempirical ways, e.g., using implicit solvent models or cluster of explicit molecule models; however, systematically improving these models is difficult due to their lack of a solid theoretical base. A theoretically sound approach for calculating the free energy is to use thermodynamic integration. Nevertheless, owing to the difficulties of self-consistent convergence in first-principles calculations for unphysical atomic configurations, the computational alchemy approach has not been widely used for first-principles calculations. This study proposes a general approach to use first-principles computational alchemy for calculating the ion solvation energy. This approach is also applicable for other small molecules. The calculated ion solvation free energies for Li+, Na+, K+, Be2+, Mg2+, and Ca2+ are close to the experimental results, and the standard deviation due to molecular dynamics fluctuations is within 0.06 eV. [ABSTRACT FROM AUTHOR]

Published

2024

13. Ab initio spectroscopy and thermochemistry of the platinum hydride ions, PtH+ and PtH−.

Author

Irikura, Karl K.

Subjects

THERMOCHEMISTRY, DIATOMIC molecules, ELECTRON affinity, THERMODYNAMIC functions, PHOTODETACHMENT threshold spectroscopy, IONS, SPIN-orbit interactions

Abstract

Rovibrational levels of low-lying electronic states of the gas-phase, diatomic molecules, PtH+ and PtH−, are computed on potential-energy functions obtained by using a hybrid spin–orbit configuration-interaction procedure. PtH− has a well-separated Σ 0 + + 1 ground state, while the first two electronic states of PtH+ ( Σ 0 + + 1 and 3Δ3) are nearly degenerate. Combining the experimental photoelectron (PE) spectra of PtH− with theoretical photodetachment spectroscopy leads to an improved value for the electron affinity of PtH, EA(PtH) = (1.617 ± 0.015) eV. When PtH− is a product of photodissociation of PtHCO2−, its PE spectrum is broad because of rotational excitation. Temperature-dependent thermodynamic functions and thermochemistry of dissociation are computed from the theoretical energy levels. Previously published energetic quantities for PtH+ and PtH− are revised. The ground 1Σ+ term of PtH+ is not well described using single-reference theory. [ABSTRACT FROM AUTHOR]

Published

2024

14. Ternary recombination of excited Ar+(P1/22) ions, established experimental results reinterpreted with a new extended model.

Author

Nongni, F. T., Kalus, R., Benhenni, M., Gadéa, F. X., and Yousfi, M.

Subjects

*ION recombination, *IONS, *ARGON

Abstract

For many years, the recombination of excited ions of argon, Ar + ( P 1 / 2 2 ) , has been assumed negligible under ambient conditions as compared to the recombination of ground-state ions, Ar + ( P 3 / 2 2 ). This opinion was confronted with detailed experimental results that seem to clearly support it. Here, we propose a new interpretation in light of our recent calculations, which shows that the recombination efficiency is comparable for both fine-structure states. Noteworthily, in our model leading to a picture consistent with the experiment, residual dimer ions emerge from A r + ( P 1 / 2 2 ) due to non-adiabatic dynamics effects and interplay in measured data. [ABSTRACT FROM AUTHOR]

Published

2024

15. Collapse and expansion kinetics of a single polyelectrolyte chain with hydrodynamic interactions.

Author

Yuan, Jiaxing and Curk, Tine

Subjects

*ELECTROSTATIC interaction, *PARTICLE dynamics, *ELECTROSTATICS, *POLYMERS, *IONS, *SALT

Abstract

We investigate the collapse and expansion dynamics of a linear polyelectrolyte (PE) with hydrodynamic interactions. Using dissipative particle dynamics with a bead–spring PE model, long-range electrostatics, and explicit ions, we examine how the timescales of collapse tcol and expansion texp depend on the chain length N and obtain scaling relationships tcol ∼ Nα and texp ∼ Nβ. For neutral polymers, we derive values of α = 0.94 ± 0.01 and β = 1.97 ± 0.10. Interestingly, the introduction of electrostatic interaction markedly shifts α to α ≈ 1.4 ± 0.1 for salt concentrations within c = 10−4 to 10−2 M. A reduction in the ion-to-monomer size ratio noticeably reduces α. On the other hand, the expansion scaling remains approximately constant, β ≈ 2, regardless of the salt concentration or ion size considered. We find β > α for all conditions considered, implying that expansion is always slower than collapse in the limit of long polymers. This asymmetry is explained by distinct kinetic pathways of collapse and expansion processes. [ABSTRACT FROM AUTHOR]

Published

2024

16. Loading and identifying various charged thorium ions in a linear ion trap with a time-of-flight mass spectrometer.

Author

Li, Zi, Li, Lin, Hua, Xia, and Tong, Xin

Subjects

*TIME-of-flight mass spectrometers, *ION traps, *THORIUM, *MASS spectrometers, *TIME-of-flight mass spectrometry, *QUADRUPOLE ion trap mass spectrometry, *IONS

Abstract

Various charged thorium ions such as singly charged, doubly charged, and triply charged thorium ions trapped in the ion trap can be used to excite the Th-229 first nuclear excited state via the electronic bridge process. We present an integration of a linear ion trap with a time-of-flight mass spectrometer to investigate trapped Th-232 ions. Various charged thorium ions are produced by laser ablation and dynamically loaded into the ion trap. After sufficient collisional cooling, thorium ions are extracted along one of the radial directions for time-of-flight mass spectrometry by rapidly quenching the trapping potential and applying high-voltage extracting pulses. The charge states of thorium ions are identified and the maximum mass resolutions of thorium ions reach ∼100 with initial 300 K collisional cooling. The velocity distributions of ablated various charged thorium ions are measured, and the results agree well with Monte Carlo simulation. Lifetimes of thorium ions are determined to be a few tens of seconds in the ion trap, which are helpful for further spectroscopic studies of Th-229 nuclear transition. [ABSTRACT FROM AUTHOR]

Published

2024

17. Nanopore/pillar formation induced by ion irradiation with a controlled projected range via Au deposition on Ge.

Author

Oishi, Naoto, Higashide, Natsumi, and Nitta, Noriko

Subjects

*POINT defects, *BUFFER layers, *ION beams, *IONS, *IRRADIATION

Abstract

Nanopore/pillar formation on a Ge substrate can be induced by ion irradiation, which activates the ion beam sputtering and self-organization of point defects. Considering that the size and morphology of nanostructures are dependent on damage production, the irradiation parameters significantly affect nanostructuring. Here, the projected range of incident ions was selected as a parameter to be investigated. The projected range was modified by adding an Au buffer layer on the surface of the substrate, enabling the ions to stop in a shallower layer. The experimental results showed that the deposited Au layer affected the size and morphology of the nanostructures produced by ion irradiation. As a unique morphology, network-like structures were observed on the Au-deposited substrates. These structures were larger than ordinary porous structures. [ABSTRACT FROM AUTHOR]

Published

2024

18. Master equation modeling of blackbody infrared radiative dissociation (BIRD) of hydrated peroxycarbonate radical anions.

Author

Salzburger, Magdalena, Hütter, Michael, van der Linde, Christian, Ončák, Milan, and Beyer, Martin K.

Subjects

*RADICAL anions, *IONS, *MOLECULAR clusters, *COMPLEX ions, *ULTRAHIGH vacuum

Abstract

Molecular cluster ions, which are stored in an electromagnetic trap under ultra-high vacuum conditions, undergo blackbody infrared radiative dissociation (BIRD). This process can be simulated with master equation modeling (MEM), predicting temperature-dependent dissociation rate constants, which are very sensitive to the dissociation energy. We have recently introduced a multiple-well approach for master equation modeling, where several low-lying isomers are taken into account. Here, we experimentally measure the BIRD of CO4●–(H2O)1,2 and model the results with a slightly modified multiple-well MEM. In the experiment, we exclusively observe loss of water from CO4●–(H2O), while the BIRD of CO4●–(H2O)2 leads predominantly to loss of carbon dioxide, with water loss occurring to a lesser extent. The MEM of two competing reactions requires empirical scaling factors for infrared intensities and the sum of states of the loose transition states employed in the calculation of unimolecular rate constants so that the simulated branching ratio matches the experiment. The experimentally derived binding energies are ΔH0(CO4●––H2O) = 45 ± 3 kJ/mol, ΔH0(CO4●–(H2O)–H2O) = 41 ± 3 kJ/mol, and ΔH0(CO2–O2●–(H2O)2) = 37 ± 3 kJ/mol. Quantum chemical calculations on the CCSD(T)/aug-cc-pVTZ//CCSD/aug-cc-pVDZ level, corrected for the basis set superposition error, yield binding energies that are 2–5 kJ/mol higher than experiment, within error limits of both experiment and theory. The relative activation energies for the two competing loss channels are as well fully consistent with theory. [ABSTRACT FROM AUTHOR]

Published

2024

19. Resonant electron capture by polycyclic aromatic hydrocarbon molecules: Effects of aza-substitution.

Author

Khatymov, Rustem V., Muftakhov, Mars V., Tuktarov, Renat F., Shchukin, Pavel V., Khatymova, Lyaysan Z., Pancras, Eugene, Terentyev, Andrey G., and Petrov, Nikolay I.

Subjects

*ELECTRON capture, *POLYCYCLIC aromatic hydrocarbons, *ABSTRACTION reactions, *IONS, *MOLECULES, *ACRIDINE derivatives, *ANTHRACENE derivatives

Abstract

Resonant electron capture by aza and diaza derivatives of phenanthrene (7,8-benzoquinoline and 1,10-phenanthroline) and anthracene (acridine and phenazine) at incident free electron energies (Ee) in the range of 0–15 eV was studied. All compounds except 7,8-benzoquinoline form long-lived molecular ions (M−) at thermal electron energies (Ee ∼ 0 eV). Acridine and phenazine also form such ions at epithermal electron energies up to Ee = 1.5–2.5 eV. The lifetimes (τa) of M− with respect to electron autodetachment are proportional to the extent of aza-substitution and increase on going from molecules with bent geometry of the fused rings (azaphenanthrenes) to linear isomers (azaanthracenes). These regularities are due to an increase in the adiabatic electron affinities (EAa) of the molecules. The EAa values of the molecules under study were comprehensively assessed based on a comparative analysis of the measured τa values using the Rice–Ramsperger–Kassel–Marcus theory, the electronic structure analysis using the molecular orbital approach, as well as the density functional calculations of the total energy differences between the molecules and anions. The only fragmentation channel of M− ions from the compounds studied is abstraction of hydrogen atoms. When studying [M–H]− ions, electron autodetachment processes were observed, the τa values were measured, and the appearance energies were determined. A comparative analysis of the gas-phase acidity of the molecules and the EAa values of the [M–H]· radicals revealed their proportionality to the EAa values of the parent molecules. [ABSTRACT FROM AUTHOR]

Published

2024

20. Large-pore connexin hemichannels function like molecule transporters independent of ion conduction

Author

Gaete, Pablo S, Kumar, Deepak, Fernandez, Cynthia I, Capuccino, Juan M Valdez, Bhatt, Aashish, Jiang, Wenjuan, Lin, Yi-Chun, Liu, Yu, Harris, Andrew L, Luo, Yun L, and Contreras, Jorge E

Subjects

Medical Physiology, Biomedical and Clinical Sciences, 1.1 Normal biological development and functioning, 2.1 Biological and endogenous factors, Humans, Connexins, Ion Transport, Animals, Mutation, Ions, Gap Junctions, Ion Channels, gap junction channel, molecular transport, permeation, selectivity

Abstract

Connexin hemichannels were identified as the first members of the eukaryotic large-pore channel family that mediate permeation of both atomic ions and small molecules between the intracellular and extracellular environments. The conventional view is that their pore is a large passive conduit through which both ions and molecules diffuse in a similar manner. In stark contrast to this notion, we demonstrate that the permeation of ions and of molecules in connexin hemichannels can be uncoupled and differentially regulated. We find that human connexin mutations that produce pathologies and were previously thought to be loss-of-function mutations due to the lack of ionic currents are still capable of mediating the passive transport of molecules with kinetics close to those of wild-type channels. This molecular transport displays saturability in the micromolar range, selectivity, and competitive inhibition, properties that are tuned by specific interactions between the permeating molecules and the N-terminal domain that lies within the pore-a general feature of large-pore channels. We propose that connexin hemichannels and, likely, other large-pore channels, are hybrid channel/transporter-like proteins that might switch between these two modes to promote selective ion conduction or autocrine/paracrine molecular signaling in health and disease processes.

Published

2024

21. Resonant Auger decay of dissociating CH3I near the I 4d threshold.

Author

Pratt, Stephen T., Jacovella, Ugo, Gans, Bérenger, Bozek, John D., and Holland, David M. P.

Subjects

*AUGER effect, *PHOTOELECTRONS, *FRONTIER orbitals, *RYDBERG states, *PHOTOELECTRON spectra, *AUGERS, *IONS

Abstract

Resonant Auger processes provide a unique perspective on electronic interactions and excited vibrational and electronic states of molecular ions. Here, new data are presented on the resonant Auger decay of excited CH3I in the region just below the I 4d−1 ionization threshold. The resonances include the Rydberg series converging to the five spin–orbit and ligand-field split CH3I (I 4d−1) thresholds, as well as resonances corresponding to excitation from the I 4d5/2,3/2 orbitals into the σ* lowest unoccupied molecular orbital. This study focuses on participator decay that populates the lowest lying states of CH3I+, in particular, the X ̃ 2E3/2 and 2E1/2 states, and on spectator decay that populates the lowest-lying (CH3I2+)σ* states of CH3I+. The CH3I (I 4d−1)σ* resonances are broad, and dissociation to CH3 + I competes with the autoionization of the core-excited states. Auger decay as the molecule dissociates produces a photoelectron spectrum with a long progression (up to v3+ ∼ 25) in the C–I stretching mode of the X ̃ 2E3/2 and 2E1/2 states, providing insights into the shape of the dissociative core-excited surface. The observed spectator decay processes indicate that CH3I+ is formed on the repulsive wall of the lower-lying (CH3I2+)σ* potentials, and the photon-energy dependence of the processes provides insights into the relative slopes of the (4d−1)σ* and (CH3I2+)σ* potential surfaces. Data are also presented for the spectator decay of higher lying CH3I (I 4d−1)nl Rydberg resonances. Photoelectron angular distributions for the resonant Auger processes provide additional information that helps distinguish these processes from the direct ionization signal. [ABSTRACT FROM AUTHOR]

Published

2024

22. A versatile apparatus for simultaneous trapping of multiple species of ultracold atoms and ions to enable studies of low energy collisions and cold chemistry.

Author

Rahaman, Bubai, Baidya, Satyabrata, and Dutta, Sourav

Subjects

*TIME-of-flight mass spectrometers, *ATOMIC beams, *ION traps, *SEMICONDUCTOR lasers, *ATOMS, *IONS, *ELECTRON gas

Abstract

We describe an apparatus where many species of ultracold atoms can be simultaneously trapped and overlapped with many species of ions in a Paul trap. Several design innovations are made to increase the versatility of the apparatus while keeping the size and cost reasonable. We demonstrate the operation of a three-dimensional (3D) magneto-optical trap (MOT) of 7Li using a single external cavity diode laser. The 7Li MOT is loaded from an atomic beam, with atoms slowed using a Zeeman slower designed to work simultaneously for Li and Sr. The operation of a 3D MOT of 133Cs, loaded from a 2D MOT, is demonstrated, and provisions for MOTs of Rb and K in the same vacuum manifold exist. We demonstrate the trapping of 7Li+ and 133Cs+ at different settings of the Paul trap and their detection using an integrated time-of-flight mass spectrometer. We present results on low energy neutral–neutral collisions (133Cs–133Cs, 7Li–7Li, and 133Cs–7Li collisions) and charge–neutral collisions (133Cs+–133Cs and 7Li+–7Li collisions). We show evidence of sympathetic cooling of 7Li+ (133Cs+) due to collisions with the ultracold 7Li (133Cs). [ABSTRACT FROM AUTHOR]

Published

2024

23. Device simulations of perovskite transistors containing mobile ions and their relevance to experimental data.

Author

Shamalia, Doaa and Tessler, Nir

Subjects

*PEROVSKITE, *THIN film transistors, *SOLAR cells, *IONS, *TRANSISTORS

Abstract

We present a device simulation of lead-halide perovskite-based thin film transistors (TFTs) containing mobile charged species to provide physical reasoning for the various experimental reports. We study the output characteristics for a range of scan duration (1/speed), average mobile ion densities, and N- and P-channel TFTs. We then directly compare our results to published data by Zeidell et al. [Adv. Electron. Mater. 4(12), 1800316 (2018)] and show that if the transistor's measurement procedure is such that the ions' effects are apparent, and then, our model can resolve the sign of the mobile ions in their MAPbI3−xClx TFTs (cations) and provide a good estimate of their density (∼1017 cm−3 at 200 k). Interestingly, we find that effects previously associated with channel screening are due to the ion-blocking of the charge extraction and that the incomplete saturation often reported is due to ion-induced channel shortening. Utilizing the same perovskite materials as in solar cells would allow researchers to improve their understanding of the mechanisms governing solar photovoltaics and improve their performance. [ABSTRACT FROM AUTHOR]

Published

2024

24. A Gaussian field approach to the solvation of spherical ions in electrolyte solutions.

Author

Xiao, Tiejun and Song, Xueyu

Subjects

*ELECTROLYTE solutions, *SOLVATION, *DIELECTRIC function, *IONS, *ENERGY density

Abstract

In this work, the electrostatic response of an electrolyte solution to a spherical ion is studied with a Gaussian field theory. In order to capture the ionic correlation effect in concentrated solutions, the bulk dielectric response function is described by a two-Yukawa response function. The modified response function of the solution is solved analytically in the spherical geometry, from which the induced charge density and the electrostatic energy are also derived analytically. Comparisons with results for small ions in electrolyte solutions from the hyper-netted chain theory demonstrate the validity of the Gaussian field theory. [ABSTRACT FROM AUTHOR]

Published

2024

25. Ideal conductor/dielectric model (ICDM): A generalized technique to correct for finite-size effects in molecular simulations of hindered ion transport.

Author

Shoemaker, Brian A. and Haji-Akbari, Amir

Subjects

*GIBBS' energy diagram, *IONS, *DIELECTRIC properties

Abstract

Molecular simulations serve as indispensable tools for investigating the kinetics and elucidating the mechanism of hindered ion transport across nanoporous membranes. In particular, recent advancements in advanced sampling techniques have made it possible to access translocation timescales spanning several orders of magnitude. In our prior study [Shoemaker et al., J. Chem. Theory Comput. 18, 7142 (2022)], we identified significant finite size artifacts in simulations of pressure-driven hindered ion transport through nanoporous graphitic membranes. We introduced the ideal conductor model, which effectively corrects for such artifacts by assuming the feed to be an ideal conductor. In the present work, we introduce the ideal conductor dielectric model (Icdm), a generalization of our earlier model, which accounts for the dielectric properties of both the membrane and the filtrate. Using the Icdm model substantially enhances the agreement among corrected free energy profiles obtained from systems of varying sizes, with notable improvements observed in regions proximate to the pore exit. Moreover, the model has the capability to consider secondary ion passage events, including the transport of a co-ion subsequent to the traversal of a counter-ion, a feature that is absent in our original model. We also investigate the sensitivity of the new model to various implementation details. The Icdm model offers a universally applicable framework for addressing finite size artifacts in molecular simulations of ion transport. It stands as a significant advancement in our quest to use molecular simulations to comprehensively understand and manipulate ion transport processes through nanoporous membranes. [ABSTRACT FROM AUTHOR]

Published

2024

26. Ion correlation-driven like-charge attraction in multivalent salt solutions.

Author

Agrawal, Nikhil R., Kaur, Ravtej, Carraro, Carlo, and Wang, Rui

Subjects

*SOLUTION (Chemistry), *COLLOIDAL suspensions, *IONS, *IONIC structure, *VALENCE (Chemistry), *RENORMALIZATION (Physics), *SURFACE charges

Abstract

The electrostatic double layer force is key to determining the stability and self-assembly of charged colloids and many other soft matter systems. Fully understanding the attractive force between two like-charged surfaces remains a great challenge. Here, we apply the modified Gaussian renormalized fluctuation theory to study ion correlation-driven like-charge attraction in multivalent salt solutions. The effects of spatially varying ion correlations on the structure of overlapping double layers and their free energy are self-consistently accounted for. In the presence of multivalent salts, increasing surface charge or counterion valency leads to a short-range attraction. We demonstrate that although both overcharging and like-charge attraction are outcomes of ion correlation, there is no causal relationship between them. Our theory also captures the non-monotonic dependence of like-charge attraction on multivalent salt concentration. The reduction of attraction at high salt concentrations could be a contributing factor toward the reentrant stability of charged colloidal suspensions. Our theoretical predictions are consistent with the observations reported in experiments and simulations. [ABSTRACT FROM AUTHOR]

Published

2023

27. Further extension of the Madrid-2019 force field: Parametrization of nitrate (NO3−) and ammonium (NH4+) ions.

Author

Trejos, Víctor M., de Lucas, Marcos, Vega, Carlos, Blazquez, Samuel, and Gámez, Francisco

Subjects

*AMMONIUM nitrate, *NITRATES, *AMMONIUM, *IONS, *CHEMICAL species

Abstract

The importance of nitrate and ammonium salts both in the environment and in biological processes cannot be questioned. In this work, using the TIP4P/2005 water model, aqueous solutions of nitrate and ammonium electrolytes are parametrized using scaled charges while keeping a rigid structure and nonpolarizable charge distributions. The models are optimized by systematically testing a set of properties for twelve electrolytes—eight nitrate and four ammonium salts—thus, enlarging the number of potential chemical species encompassed within the Madrid-2019 force field for ions. The capacity of the force field for predicting densities, ion–ion and ion–solvent structures, and transport properties of the solutions comprised by the trial batch of salts was tested and discussed. Both the dependence of the densities with the salt concentration and the solution structure were nicely reproduced by the models in the whole concentration range without any trace of precipitating events and with improved accuracy in comparison with recently reported models, while the agreement of the simulated transport properties with experimental data ranges from good to reasonable, depending on the ion/counterion pair. These scaled charge models might be considered as force fields embodying a reasonable compromise between exactness and general applicability and also as an important step in the development of accurate models for polyatomic ions. [ABSTRACT FROM AUTHOR]

Published

2023

28. Light antiproton one-electron quasi-molecular ions within the relativistic A-DKB method.

Author

Anikin, A., Danilov, A., Glazov, D., Kotov, A., and Solovyev, D.

Subjects

*BINDING energy, *IONS, *DIRAC equation, *ELECTRONS

Abstract

In the present work, two quasi-molecular compounds each involving one antiproton and one electron ( p ̄) , H e + − p ̄ and H − p ̄ , are investigated. Using completely relativistic calculations within the finite-basis method adapted to systems with axial symmetry, the adiabatic potential curves are constructed by numerically solving the two-center Dirac equation. The binding energies of electron are obtained as a function of the inter-nuclear distance and compared with the corresponding nonrelativistic values and relativistic leading-order corrections calculated in the framework of other approaches. A semantic analysis of antiproton quasi-molecular ions with compounds containing a proton (p) instead of an antiproton is given. The advantages of the A-DKB method are demonstrated. [ABSTRACT FROM AUTHOR]

Published

2023

29. Elementary processes triggered in curcumin molecule by gas-phase resonance electron attachment and by photoexcitation in solution.

Author

Pshenichnyuk, Stanislav A., Asfandiarov, Nail L., Markova, Angelina V., Komolov, Alexei S., Timoshnikov, Viktor A., and Polyakov, Nikolay E.

Subjects

*ELECTRON paramagnetic resonance, *POLARIZATION (Nuclear physics), *ELECTRON affinity, *IONS, *THERMAL electrons, *IRRADIATION, *ANIONS

Abstract

Electron-driven processes in isolated curcumin (CUR) molecules are studied by means of dissociative electron attachment (DEA) spectroscopy under gas-phase conditions. Elementary photostimulated reactions initiated in CUR molecules under UV irradiation are studied using the chemically induced dynamic nuclear polarization method in an acetonitrile solvent. Density functional theory is applied to elucidate the energetics of fragmentation of CUR by low-energy (0–15 eV) resonance electron attachment and to characterize various CUR radical forms. The adiabatic electron affinity of CUR molecule is experimentally estimated to be about 1 eV. An extra electron attachment to the π1* LUMO and π2* molecular orbitals is responsible for the most intense DEA signals observed at thermal electron energy. The most abundant long-lived (hundreds of micro- to milliseconds) molecular negative ions CUR– are detected not only at the thermal energy of incident electrons but also at 0.6 eV, which is due to the formation of the π3* and π4* temporary negative ion states predicted to lie around 1 eV. Proton-assisted electron transfer between CUR molecules is registered under UV irradiation. The formation of both radical-anions and radical-cations of CUR is found to be more favorable in its enol form. The present findings shed some light on the elementary processes triggered in CUR by electrons and photons and, therefore, can be useful to understand the molecular mechanisms responsible for a variety of biological effects produced by CUR. [ABSTRACT FROM AUTHOR]

Published

2023

30. Influence of salinity gradients on the diffusion of water and ionic species in dual porosity clay samples

Author

Tertre, Emmanuel, Dabat, Thomas, Wang, Jingyi, Savoye, Sébastien, Hubert, Fabien, Dazas, Baptiste, Tournassat, Christophe, Steefel, Carl I, and Ferrage, Eric

Subjects

Hydrology, Earth Sciences, Porosity, Salinity, Diffusion, Clay, Aluminum Silicates, Water, Ions, Models, Theoretical, Clayey porous media, Water diffusion, Ionic diffusion, Salinity gradient, Through -diffusion experiments, Reactive transport modeling, Through-diffusion experiments, Environmental Engineering

Abstract

Most of the available data on diffusion in natural clayey rocks consider tracer diffusion in the absence of a salinity gradient despite the fact that such gradients are frequently found in natural and engineered subsurface environments. To assess the role of such gradients on the diffusion properties of clayey materials, through-diffusion experiments were carried out in the presence and absence of a salinity gradient using salt-diffusion and radioisotope tracer techniques. The experiments were carried out with vermiculite samples that contained equal proportions of interparticle and interlayer porosities so as to assess also the role played by the two types of porosities on the diffusion of water and ions. Data were interpreted using both a classical Fickian diffusion model and with a reactive transport code, CrunchClay that can handle multi-porosity diffusion processes in the presence of charged surfaces. By combining experimental and simulated data, we demonstrated that (i) the flux of water diffusing through vermiculite interlayer porosity was minor compared to that diffusing through the interparticle porosity, and (ii) a model considering at least three types of porous volumes (interlayer, interparticle diffuse layer, and bulk interparticle) was necessary to reproduce consistently the variations of neutral and charged species diffusion as a function of salinity gradient conditions.

Published

2024

31. The Mystery of Matter.

Author

CALDWELL, LUKE

Subjects

*ELECTRIC dipole moments, *IONS, *ION traps, *RESEARCH personnel, *HAFNIUM

Abstract

This article discusses a recent experiment conducted at JILA, a research institute at the University of Colorado Boulder, to measure the electric dipole moment (EDM) of an electron. The experiment used hafnium monofluoride molecules and trapped molecular ions to observe the electrons for a longer period of time. The researchers encountered challenges such as systematic errors and experimenter bias, which they addressed through careful data analysis and blinding techniques. The results showed that the electron's EDM was consistent with zero, improving on previous measurements and placing limits on the possible size of the EDM. The article also explores future advancements and possibilities for further research in this field. [Extracted from the article]

Published

2024

32. Chlorophyll and pheophytin protonated and deprotonated ions: Observation and theory.

Author

Diop, M., El-Hayek, M., Attard, J., Muhieddine, A., Veremeienko, V., Soorkia, S., Carbonnière, Ph., de la Lande, A., Soep, B., and Shafizadeh, N.

Subjects

*CHLOROPHYLL, *ELECTROSPRAY ionization mass spectrometry, *DENSITY functional theory, *DOUBLE bonds, *IONS, *MOLECULAR dynamics

Abstract

Pheophytin a and chlorophyll a have been investigated by electrospray mass spectrometry in the positive and negative modes, in view of the importance of the knowledge of their properties in photosynthesis. Pheophytin and chlorophyll are both observed intensely in the protonated mode, and their main fragmentation route is the loss of their phytyl chain. Pheophytin is observed intact in the negative mode, while under collisions, it is primarily cleaved beyond the phytyl chain and loses the attaching propionate group. Chlorophyll is not detected in normal conditions in the negative mode, but addition of methanol solvent molecule is detected. Fragmentation of this adduct primarily forms a product (−30 amu) that dissociates into dephytyllated deprotonated chlorophyll. Semi-empirical molecular dynamics calculations show that the phytyl chain is unfolded from the chlorin cycle in pheophytin a and folded in chlorophyll a. Density functional theory calculations have been conducted to locate the charges on protonated and deprotonated pheophytin a and chlorophyll a and have found the major location sites that are notably more stable in energy by more than 0.5 eV than the others. The deprotonation site is found identical for pheophytin a and the chlorophyll a-methanol adduct. This is in line with experiment and calculation locating the addition of methanol on a double bond of deprotonated chlorophyll a. [ABSTRACT FROM AUTHOR]

Published

2023

33. Purely single-bonded spiral nitrogen chains stabilized by trivalent lanthanum ions.

Author

Ding, Chi, Yuan, Jianan, Han, Yu, Zhang, Zhongwei, Jia, Qiuhan, Wang, Junjie, and Sun, Jian

Subjects

*LANTHANUM, *PHASE diagrams, *IONS, *NITRIDES, *CRYSTAL structure, *CERIUM, *NITROGEN, *ATOMS

Abstract

Inspired by the single-bonded nitrogen chains stabilized by tetravalent cerium, pentavalent tantalum, and hexavalent tungsten atoms, we explored the possibility of single-bonded nitrogen polymorphs stabilized by trivalent lanthanum ions. To achieve this, we utilized the crystal structure search method on the phase diagram of binary La–N compounds. We identified three novel thermodynamically stable phases, the C2/c LaN3, P-1 LaN4, and P-1 LaN8. Among them, the C2/c phase with infinite helical poly-N6 chains becomes thermodynamically stable above 50 GPa. Each nitrogen atom in the poly-N6 chain acquires one extra electron, and the spiral chain is purely single-bonded. The C2/c phase has an indirect band gap of ∼1.6 eV at 60 GPa. Notably, the band gap exhibits non-monotonic behavior, decreases first and then increases with increasing pressure. This abnormal behavior is attributed to the significant bonding of two La–N bonds at around 35 GPa. Phonon spectrum calculations and AIMD simulations have confirmed that the C2/c phase can be quenched to ambient conditions with slight distortion, and it exhibits excellent detonation properties. Additionally, we also discovered armchair-like nitrogen chains in LaN4 and the armchair and zigzag-like mixed nitrogen chains in LaN8. These results provide valuable insights into the electronic and bonding properties of nitrides under high pressure and may have important implications for the design and development of novel functional materials. [ABSTRACT FROM AUTHOR]

Published

2023

34. Addressing three-body fragmentation of methane dication using "native frames": Evidence of internal excitation in fragments.

Author

Rajput, Jyoti, Garg, Diksha, Cassimi, A., Fléchard, X., Rangama, J., and Safvan, C. P.

Subjects

*COINCIDENCE, *PROJECTILES, *SPECTROMETRY, *PROBABILITY theory, *METHANE hydrates, *IONS

Abstract

The three body fragmentation of methane dication has been studied using the technique of cold target recoil ion momentum spectroscopy. The process is initiated by impact of energetic Ar9+ ions on neutral methane and the data is subsequently collected in coincidence with Ar8+ projectile. By analysing the dissociation channels leading to (H + H+ + CH 2 + ) and (H + H 2 + + CH+) fragments, it is concluded that these fragments are formed in a sequential manner via formation of molecular intermediates CH 3 + and CH 2 + respectively. It is shown that these molecular intermediates carry a few eVs as their internal energies, part of which is released when they emit an H-atom with the open possibility that the final detected fragments may still be internally excited. This was accomplished by analysing the two-steps of the sequential process in their own native frames. For a molecular system having three-dimensional structure, our results prove to be an ideal example to highlight the importance of using native frames for correct interpretation of the obtained results. Our results indicate that the dissociation of methane dication can be a major source of production of H-atoms in addition to H+ fragments with the probability of the two being of similar order. [ABSTRACT FROM AUTHOR]

Published

2023

35. Electrophoresis of ions and electrolyte conductivity: From bulk to nanochannels.

Author

Vinogradova, Olga I. and Silkina, Elena F.

Subjects

*CONDUCTIVITY of electrolytes, *ELECTROPHORESIS, *ION mobility, *IONIC mobility, *IONS, *ION mobility spectroscopy, *ELECTROLYTE solutions

Abstract

When electrolyte solutions are confined in micro- and nanochannels their conductivity is significantly different from those in a bulk phase. Here we revisit the theory of this phenomenon by focusing attention on the reduction in the ion mobility with the concentration of salt and a consequent impact to the conductivity of a monovalent solution, from bulk to confined in a narrow slit. We first give a systematic treatment of electrophoresis of ions and obtain equations for their zeta potentials and mobilities. The latter are then used to obtain a simple expression for a bulk conductivity, which is valid in a concentration range up to a few molars and more accurate than prior analytic theories. By extending the formalism to the electrolyte solution in the charged channel the equations describing the conductivity in different modes are presented. They can be regarded as a generalization of prior work on the channel conductivity to a more realistic case of a nonzero reduction of the electrophoretic mobility of ions with salt concentration. Our analysis provides a framework for interpreting measurements on the conductivity of electrolyte solutions in the bulk and in narrow channels. [ABSTRACT FROM AUTHOR]

Published

2023

36. Improvement of electrolytes for aluminum ion batteries: A molecular dynamics study.

Author

Kosar, Maryam, Taimoory, S. Maryamdokht, Diesenhaus, Owen, and Trant, John F.

Subjects

*ALUMINUM batteries, *IONS, *MOLECULAR dynamics, *ELECTROLYTES, *POLYELECTROLYTES, *SOLVENTS, *POLYMER colloids, *CHARGE carriers

Abstract

The aluminum ion battery (AIB) is a promising technology, but there is a lack of understanding of the desired nature of the batteries' electrolytes. The ionic charge carriers in these batteries are not simply Al3+ ions but the anionic AlCl4− and Al2Cl7−, which form in the electrolyte. Using computational analysis, this study illustrates the effect of mole ratios and organic solvents to improve the AIB electrolytes. To this end, molecular dynamics simulations were conducted on varying ratios forming acidic, neutral, and basic mixtures of the AlCl3 salt with 1-ethyl-3-methylimidazolium chloride (EMImCl) ionic liquid (IL) and an organic solvent electrolyte [dichloromethane (DCM) or toluene]. The data obtained from diffusion calculations indicates that the solvents could improve the transport properties. Both DCM and toluene lead to higher diffusion coefficients, and higher conductivity. Detailed calculations demonstrated solvents can effectively improve the formation of AlCl3⋯Cl (AlCl4−) and AlCl4−···AlCl4− (Al2Cl7−) especially in acidic mixtures. The densities, around 1.25 g/cm3 for electrolyte mixtures of AlCl3-EMImCl, were consistent with experiment. These results, in agreement with experimental findings, strongly suggest that DCM in acidic media with AlCl3 and EMImCl might provide a promising basis for battery development. [ABSTRACT FROM AUTHOR]

Published

2023

37. Spherical densities and potentials in exactly solvable model molecules.

Author

Nagy, Á.

Subjects

*WAVE functions, *DENSITY functional theory, *EULER equations, *IONS, *FUNCTIONALS, *PSEUDOPOTENTIAL method, *HYDROGEN ions

Abstract

A recently initiated variant of density functional theory utilizes a set of spherically symmetric densities instead of the density. The exact functionals are unknown in the new theory akin to the standard density functional theory. In order to test approximate functionals exactly solvable models are introduced. A harmonic molecular ion, the analogue to the hydrogen molecule ion and a harmonic two-electron molecule showing analogy to the hydrogen molecule are proposed. It has been found that the wave function and the density can be given analytically. The exact spherical densities and the effective potentials of the Euler equations also have analytical form. It has been shown that the models can be easily extended to several "nuclei." [ABSTRACT FROM AUTHOR]

Published

2023

38. A new generation of non-diagonal, renormalized self-energies for calculation of electron removal energies.

Author

Opoku, Ernest, Pawłowski, Filip, and Ortiz, J. V.

Subjects

*RENORMALIZATION (Physics), *IONS, *ELECTRONS, *IONIZATION energy, *QUALITY standards, *ARITHMETIC

Abstract

A new generation of diagonal self-energies for the calculation of electron removal energies of molecules and molecular ions that has superseded its predecessors with respect to accuracy, efficiency, and interpretability is extended to include non-diagonal self-energies that permit Dyson orbitals to be expressed as linear combinations of canonical Hartree–Fock orbitals. In addition, an improved algorithm for renormalized methods eliminates the convergence difficulties encountered in the first studies of the new, diagonal self-energies. A dataset of outer-valence, vertical ionization energies with almost full-configuration-interaction quality serves as a standard of comparison in numerical tests. The new non-diagonal, renormalized methods are slightly more accurate than their diagonal counterparts, with mean absolute errors between 0.10 and 0.06 eV for outer-valence final states. This advantage is procured at the cost of an increase in the scaling of arithmetic bottlenecks that accompany the inclusion of non-diagonal self-energy terms. The new, non-diagonal, renormalized self-energies are also more accurate and efficient than their non-diagonal predecessors. [ABSTRACT FROM AUTHOR]

Published

2023

39. Chiral molecule candidates for trapped ion spectroscopy by ab initio calculations: From state preparation to parity violation.

Author

Landau, Arie, Eduardus, Behar, Doron, Wallach, Eliana Ruth, Pašteka, Lukáš F., Faraji, Shirin, Borschevsky, Anastasia, and Shagam, Yuval

Subjects

*AB-initio calculations, *ION traps, *IONS, *CHIRALITY of nuclear particles, *MOLECULAR spectroscopy, *QUANTUM efficiency

Abstract

Parity non-conservation (PNC) due to the weak interaction is predicted to give rise to enantiomer dependent vibrational constants in chiral molecules, but the phenomenon has so far eluded experimental observation. The enhanced sensitivity of molecules to physics beyond the Standard Model (BSM) has led to substantial advances in molecular precision spectroscopy, and these may be applied to PNC searches as well. Specifically, trapped molecular ion experiments leverage the universality of trapping charged particles to optimize the molecular ion species studied toward BSM searches, but in searches for PNC, only a few chiral molecular ion candidates have been proposed so far. Importantly, viable candidates need to be internally cold, and their internal state populations should be detectable with high quantum efficiency. To this end, we focus on molecular ions that can be created by near threshold resonant two-photon ionization and detected via state-selective photo-dissociation. Such candidates need to be stable in both charged and neutral chiral versions to be amenable to these methods. Here, we present a collection of suitable chiral molecular ion candidates we have found, including CHDBrI+ and CHCaBrI+, that fulfill these conditions according to our ab initio calculations. We find that organo-metallic species have low ionization energy as neutrals and relatively high dissociation thresholds. Finally, we compute the magnitude of the PNC values for vibrational transitions for some of these candidates. An experimental demonstration of state preparation and readout for these candidates will be an important milestone toward measuring PNC in chiral molecules for the first time. [ABSTRACT FROM AUTHOR]

Published

2023

40. Neural network predicts ion concentration profiles under nanoconfinement.

Author

Cao, Zhonglin, Wang, Yuyang, Lorsung, Cooper, and Barati Farimani, Amir

Subjects

*DISTRIBUTION (Probability theory), *ELECTRO-osmosis, *PLASMA beam injection heating, *SURFACE interactions, *IONS, *DEEP learning

Abstract

Modeling the ion concentration profile in nanochannel plays an important role in understanding the electrical double layer and electro-osmotic flow. Due to the non-negligible surface interaction and the effect of discrete solvent molecules, molecular dynamics (MD) simulation is often used as an essential tool to study the behavior of ions under nanoconfinement. Despite the accuracy of MD simulation in modeling nanoconfinement systems, it is computationally expensive. In this work, we propose neural network to predict ion concentration profiles in nanochannels with different configurations, including channel widths, ion molarity, and ion types. By modeling the ion concentration profile as a probability distribution, our neural network can serve as a much faster surrogate model for MD simulation with high accuracy. We further demonstrate the superior prediction accuracy of neural network over XGBoost. Finally, we demonstrated that neural network is flexible in predicting ion concentration profiles with different bin sizes. Overall, our deep learning model is a fast, flexible, and accurate surrogate model to predict ion concentration profiles in nanoconfinement. [ABSTRACT FROM AUTHOR]

Published

2023

41. Probing the role of ligation and exonuclease digestion towards non-specific amplification in bioanalytical RCA assays.

Author

Nair, Vandana Kuttappan, Sharma, Chandrika, Kumar, Shrawan, Sengupta, Mrittika, and Ghosh, Souradyuti

Subjects

*CIRCULAR DNA, *COMPLEMENTARY DNA, *DIGESTION, *IONS, *ENZYMES

Abstract

Non-specific amplification (NSA, amplification in the absence of a target analyte) in bioanalytical rolling circle amplification (RCA) assays, especially those involving pre-synthesized circular DNA (cDNA), affects its analytical sensitivity. Despite extensive development of RCA-based bioanalytical methods, the NSA in RCA remains uncharacterized in terms of its magnitude or origin. NSA may originate from inefficient ligation or succeeding cDNA purification steps. This study comprehensively quantifies NSA across several ligation and digestion techniques for the first time since the innovation of RCA. To quantify the NSA in RCA, cDNAs were prepared using self-annealing, splint-padlock, or cohesive end ligations. The cDNAs were then subjected to nine different exonuclease digestion steps and quantified for NSA under linear as well as hyperbranched RCA conditions. We investigated buffer compositions, divalent ion concentrations, single or dual enzyme digestion, cohesive end lengths, and splint lengths. The optimized conditions successfully mitigated absolute NSA by 30–100-fold and relative NSA (normalized against primer-assisted RCA) to ∼5%. Besides understanding the mechanistic origin of NSA, novel aspects of enzyme–substrate selectivity, buffer composition, and the role of divalent ions were discovered. With increasing bioanalytical RCA applications, this study will help standardize NSA-free assays. [ABSTRACT FROM AUTHOR]

Published

2024

42. Aliovalent metal cation doping of La5Ti2AgO7S5 particles for improved photocatalytic and photoelectrochemical water splitting.

Author

Yosuke Kageshima, Shiino Otsuka, Ryunosuke Iwaya, Haruto Yonehara, Katsuya Teshima, Kazunari Domen, and Hiromasa Nishikiori

Subjects

*CARRIER density, *CATIONS, *METALS, *IONS, *HYDROGEN

Abstract

The doping of photocatalytic La5Ti2AgO7S5 particles with aliovalent metal cations was investigated. The incorporation of lower-valence Al3+ cations at Ti4+ sites improved the photocatalytic hydrogen evolution activity. In addition, the anodic photocurrent during oxygen evolution was increased upon adding higher-valence Ta5+ ions. The effect of doping on the carrier density in the photocatalytic particles was also examined in this work. [ABSTRACT FROM AUTHOR]

Published

2024

43. Synthesis of dispiro-orthoester via an acetal oxo-carbenium ion.

Author

Kumar, Manoj, Singh, Shubham, and Subramanian, Parthasarathi

Subjects

*ESTERS, *IONS

Abstract

The first dispiro orthoester via a spiroacetal oxo-carbenium ion is presented. Oxidative dearomatization of phloretic esters results in a bifunctional electrophilic spiroacetal oxo-carbenium ion, which undergoes a double nucleophilic addition by diol delivering a range of unusual dispiro-orthoesters with an excellent diversity. [ABSTRACT FROM AUTHOR]

Published

2024

44. Approach for quality deep-ultraviolet nonlinear optical crystals via a substitution strategy of channel species in zeolite.

Author

Liu, Mingfeng, Mi, Jin-Xiao, Zhang, Yinggan, Wang, Shuaihua, Wu, Shaofan, and Huang, Ya-Xi

Subjects

*PERMUTATION groups, *CRYSTAL structure, *ZEOLITES, *ANIONS, *IONS

Abstract

Exploring the connections between the ion substitution of a material, its crystal structure, and its performance in applications is a regular task in synthetic chemistry. However, there still remain major challenges in the substitution of polyanionic groups for single ions. Herein, a strategy of channel species substitution of single anions by polyanionic groups in a zeotype rigid framework to design a new deep-ultraviolet nonlinear zincophosphate, {[Li3Na3(SiF6)]Cs2}[(ZnPO4)6], and tune physicochemical properties was proposed. [ABSTRACT FROM AUTHOR]

Published

2024

45. Dual‐Site Bridging Mechanism for Bimetallic Electrochemical Oxygen Evolution.

Author

Cao, Hongshuai, Wen, Xue, Luo, Xianzhu, Ma, Linlin, Xu, Zhiai, Zhang, Zhonghai, and Zhang, Wen

Subjects

*OXYGEN evolution reactions, *OVERPOTENTIAL, *STATE formation, *CATALYSIS, *IONS, *ELECTROCATALYSTS

Abstract

Heterogeneous dual‐site electrocatalysts are emerging cutting‐edge materials for efficient electrochemical water splitting. However, the corresponding oxygen evolution reaction (OER) mechanism on these materials is still unclear. Herein, based on a series of in situ spectroscopy experiments and density function theory (DFT) calculations, a new heterogeneous dual‐site O−O bridging mechanism (DSBM) is proposed. This mechanism is to elucidate the sequential appearance of dual active sites through in situ construction (hybrid ions undergo reconstruction initially), determine the crucial role of hybrid dual sites in this mechanism (with Ni sites preferentially adsorbing hydroxyls for catalysis followed by proton removal at Fe sites), assess the impact of O−O bond formation on the activation state of water (inducing orderliness of activated water), and investigate the universality (with Co doping in Ni(P4O11)). Under the guidance of this mechanism, with Fe−Ni(P4O11) as pre‐catalyst, the in situ formed Fe−Ni(OH)2 electrocatalyst has reached a record‐low overpotential of 156.4 mV at current density of 18.0 mA cm−2. Successfully constructed Fe−Ni(P4O11)/Ti uplifting the overall efficacy of the phosphate from moderate to superior, positioning it as an innovative and highly proficient electrocatalyst for OER. [ABSTRACT FROM AUTHOR]

Published

2024

46. Differential electrophoretic mobility of synthetic DNA motifs and duplex DNA in various counter ions.

Author

Patel, Akul, Punnoose, Leah, and Chandrasekaran, Arun Richard

Subjects

*COUNTER-ions, *ARTIFICIAL chromosomes, *MOLECULAR weights, *IONS, *DNA

Abstract

In this work, we analyzed the electrophoretic behavior of a double crossover (DX) DNA motif in various counter ions. The influence of the type and concentration of counter ions on electrophoretic behavior is different for the DX motif compared to a duplex of the same molecular weight. Higher concentrations of divalent ions Mg2+ and Ca2+ in the gel and running buffer reduce the electrophoretic migration of the DX motif. This effect is less pronounced in the monovalent ion Na+ while K+ ion did not have any significant effect on the electrophoretic behavior. [ABSTRACT FROM AUTHOR]

Published

2024

47. Comparing Shor and Steane error correction using the Bacon-Shor code.

Author

Shilin Huang, Brown, Kenneth R., and Cetina, Marko

Subjects

*QUANTUM states, *QUANTUM measurement, *IONS, *ION traps, *QUBITS, *QUANTUM information theory

Abstract

Quantum states decohere through interaction with the environment. Quantum error correction can preserve coherence through active feedback wherein quantum information is encoded into a logical state with a high degree of symmetry. Perturbations are detected by measuring the symmetries of the state and corrected by applying gates based on these measurements. To measure the symmetries without perturbing the data, ancillary quantum states are required. Shor error correction uses a separate quantum state for the measurement of each symmetry. Steane error correction maps the perturbations onto a logical ancilla qubit, which is then measured to check several symmetries simultaneously. We experimentally compare Shor and Steane correction of bit flip errors using the Bacon-Shor code implemented in a chain of 23 trapped atomic ions. We find that the Steane method produces fewer errors after a single round of error correction and less disturbance to the data qubits without error correction. [ABSTRACT FROM AUTHOR]

Published

2024

48. Impact of the host lattice on crystallographic, Raman, optical, and luminescent properties on the terbium ion.

Author

Ansari, Anees A. and Khan, M. A. Majeed

Subjects

*IONS, *RAMAN effect, *RAMAN spectroscopy, *CRYSTAL defects, *OPTICAL properties

Abstract

A comparative study of the Gd2O3:Tb and Y2O3:Tb nanoparticles (NPs) was presented to examine the influence of the host lattices on the crystallographic phase, surface characteristics, optical properties, Raman effect, and photoluminescence properties. Cubic shapes Gd2O3:Tb and Y2O3:Tb NPs with an estimated crystalline size of 17 and 11 nm were recorded from the X‐ray diffraction pattern, respectively. Comparative absorption spectra of both oxides NPs were presented to examine the dispersibility, colloidal stability, and optical behavior of the NPs. Energy bandgap values were estimated to monitor the optical characteristics of the metal oxides in the UV/Vis region. Fourier transform infrared was recorded to confirm the surface‐attached water and organic moieties. The Raman spectra of metal oxides were recorded to examine the symmetrical dis‐order and polarizability of the vibrational bands. The ionic radius of the atoms distorts the bond structure resulting in it greatly influenced the vibrational bands of the materials. The emission spectra certified the effective doping of the luminescent Tb3+‐ion in the metal oxide host lattices. Raman spectra and emission spectra validated the crystal symmetry imperfections; subsequently, the efficiency of the Raman active modes and emission transitions was greatly influenced. In a comparative analysis, Y2O3:Tb NPs exhibited higher luminescence intensity in comparison with the Gd2O3:Tb NPs. [ABSTRACT FROM AUTHOR]

Published

2024

49. Detection of several volatile organic compounds through Ar+ induced chemical ionisation using inductively coupled plasma-tandem mass spectrometry (ICP-MS/MS).

Author

Hirata, Takafumi, Kobayashi, Kyoko, Khoo, Hui Hsin, Shikino, Osamu, and Asanuma, Hisashi

Subjects

*COFFEE beans, *ION sources, *IONS, *MASS spectrometry, *ORGANIC compounds

Abstract

A new analytical technique for detection of organic compounds using inductively coupled plasma-tandem mass spectrometry (ICP-MS/MS) is described. Volatile organic compounds (VOCs) were introduced into the collision/reaction cell (CRC), instead of through the ICP ion source, and the molecules were ionised through an ion reaction, induced by collision with the primary ions (Ar+) produced in the ICP. The ionisation characteristics of this new approach were investigated by mass spectrometric analysis of eight VOCs (i.e., benzene, toluene, ethyl acetate, methyl butyrate, ethyl butyrate, pentyl acetate, pyridine, and 2-methylfuran). These molecules were detected as molecular ions (M+), protonated ions ([M + H]+), or deprotonated ions ([M − H]+), demonstrating that soft ionisation was achieved by the present ionisation protocol using ICP-MS/MS. In addition, a volatile selenium-containing organic compound, dimethyl diselenide (Se2(CH3)2), was also analysed to investigate the feasibility of this ionisation protocol to achieve soft and hard ionisation simultaneously. Several Se-related ions such as Se+, SeH+, Se2+, [SeCH3]+, and [Se2CH3]+, together with [Se2(CH3)2]+, were observed, suggesting that while soft ionisation was possible, ion reaction-induced-fragmentation and hard ionisation also occurred. To demonstrate the analytical capability of the present technique, volatile components released from coffee beans were subjected to the present mass spectrometric analysis. Many ion peaks originating from VOCs were detected from the coffee beans. The data obtained here demonstrated that ICP-MS equipped with a CRC can become an effective tool for analyzing both elements and molecules. [ABSTRACT FROM AUTHOR]

Published

2024

50. Roadmap toward Controlled Ion Beam‐Induced Defects in 2D Materials.

Author

Telkhozhayeva, Madina and Girshevitz, Olga

Subjects

*NANOELECTROMECHANICAL systems, *BIOCHEMICAL substrates, *ION beams, *IONS, *NANOTECHNOLOGY

Abstract

Understanding the nature, density, and distribution of structural defects is crucial for tailoring the properties of atomically thin two‐dimensional (2D) materials, which is paramount for advances in nanotechnology. Ion irradiation emerges as a promising technique for defect engineering of single‐atom‐thick materials, due to its high controllability, repeatability, and accuracy. The objective is to provide a comprehensive review elucidating the impact of various irradiation parameters, such as ion mass, energy, fluence, and incident angle, on defect formation in 2D materials. However, the presence of the substrate can significantly influence defect yield and the mechanism of formation due to backscattered ions and sputtered substrate atoms. Hence, a thorough comparison of ion beam‐induced defects in both freestanding (suspended) and supported (on a substrate) 2D materials, with a focus on substrate effects is conducted. Moreover, a detailed analysis of characterization techniques suitable for each scenario will be provided. This work not only contributes to advancing the current understanding of defect formation and evolution in 2D materials during ion beam irradiation but also offers insights into selecting specific parameters for this process to create desired defects in these materials. Consequently, it has the potential to facilitate the design of nanoscale devices with tailored functionality. [ABSTRACT FROM AUTHOR]

Published

2024