Your search keyword '"ELECTRONS"' showing total 239,362 results

1. Probing photochemical dynamics using electronic vs vibrational sum-frequency spectroscopy: The case of the hydrated electron at the water/air interface.

Author

Pritchard, Faith G., Jordan, Caleb J. C., and Verlet, Jan R. R.

Subjects

*PHOTOAFFINITY labeling, *SPECTROMETRY, *ELECTRONS, *SPECIES

Abstract

Photo-dynamics can proceed differently at the water/air interface compared to in the respective bulk phases. Second-order non-linear spectroscopy is capable of selectively probing the dynamics of species in such an environment. However, certain conclusions drawn from vibrational and electronic sum-frequency generation spectroscopies do not agree as is the case for the formation and structure of hydrated electrons at the interface. This Perspective aims to highlight these apparent discrepancies, how they can be reconciled, suggests how the two techniques complement one another, and outline the value of performing both techniques on the same system. [ABSTRACT FROM AUTHOR]

Published

2024

2. Accuracy bottlenecks in impedance spectroscopy due to transient effects.

Author

Lopez-Richard, Victor, Pradhan, Soumen, Castelano, Leonardo K., Wengenroth Silva, Rafael Schio, Lipan, Ovidiu, Höfling, Sven, and Hartmann, Fabian

Subjects

*MEMRISTORS, *IMPEDANCE spectroscopy, *ELECTROCHEMICAL apparatus, *ELECTRONS, *ELECTRODES

Abstract

Impedance spectroscopy is vital for material characterization and assessing electrochemical device performance. It provides real-time analysis of dynamic processes such as electrode kinetics, electrons, holes or ion transport, and interfacial or defect driven phenomena. However, the technique is sensitive to experimental conditions, introducing potential variability in results. The intricate interplay of transient effects within the realm of spectral impedance analyses introduces a layer of complexity that may impede straightforward interpretations. This demands a nuanced approach for refining analytical methodologies and ensuring the fidelity of impedance characterization once the dynamic contributions of transient ingredients cannot be disentangled from the underlying steady-state characteristics. In our study, we experimentally identify that the transient effects in a memristor device are most pronounced near an optimal frequency related to intrinsic relaxation times, with these effects diminishing as the frequency varies beyond or below this range. While inherent systematic errors impose a practical limit (accuracy floor) on achievable measurement accuracy, this paper offers qualitative and quantitative insights into how specific procedures affect this limit and how to reduce it in orders of magnitude. Only by effectively addressing these errors, we can push beyond this constraint. [ABSTRACT FROM AUTHOR]

Published

2024

3. Electric-field-induced enhancement of exciton binding energy in one-dimensional phosphorene atomic chain.

Author

Huang, Wenzhuo, Zhong, Jun, and Sheng, Weidong

Subjects

*BINDING energy, *ELECTRIC fields, *PHOSPHORENE, *EXCITON theory, *ELECTRONS

Abstract

An electric field normally increases the separation between the electron and hole in an exciton without intrinsic polarization and suppresses their Coulombic interaction, resulting in the reduction of its binding energy. Our study of one-dimensional (1D) excitons in phosphorene atomic chains, by using the exact diagonalization method, however, reveals that an electric field applied along the chain axis actually increases the exciton binding energies. Further analysis shows that the electric field tends to enhance the long-range interaction between the electron and hole while suppressing their short-range interaction by inducing an alternating charge distribution along the atomic chain. The zigzag symmetry is believed to account for this unique excitonic phenomenon in the 1D system. [ABSTRACT FROM AUTHOR]

Published

2024

4. Dynamics of hydride anion and acetyloxyl radical production by electron attachment to acetic acid.

Author

Hasan, M., Weber, Th., Centurion, M., and Slaughter, D. S.

Subjects

*KINETIC energy, *RADICAL anions, *RADICALS (Chemistry), *RESONANCE, *ELECTRONS

Abstract

We investigate the dynamics and site-selectivity in the dissociation of transient anions formed upon attachment of low energy electrons to acetic acid by anion fragment momentum imaging experiments. The resonances at 6.7 and 7.7 eV are confirmed to dissociate exclusively by the O–H bond, while a third resonance at 9.1 eV dissociates primarily by both C–H break and O–H break. A fourth resonance near 10 eV is found to dissociate by O–H break. For each resonance, the measured kinetic energy release indicates two-body dissociation produces a neutral radical in the ground electronic state, for all four resonances. The measured angular distributions are consistent with all four resonances having A′ symmetry. [ABSTRACT FROM AUTHOR]

Published

2024

5. Electron-impact ionization of water molecules at low impact energies.

Author

Tamin, A., Houamer, S., Khatir, T., Ancarani, L. U., and Dal Cappello, C.

Subjects

*IMPACT ionization, *DRUG target, *IONIZATION energy, *PROJECTILES, *ELECTRONS

Abstract

The electron-impact ionization of water molecules at low impact energies is investigated using a theoretical approach named M3CWZ. In this model, which considers exchange effects and post-collision interaction, the continuum electrons (incident, scattered, and ejected) are all described by a Coulomb wave that corresponds to distance-dependent charges generated from the molecular target properties. Triple differential cross-sections for low impact energy ionization of either the 1b1 or 3a1 orbitals are calculated for several geometrical and kinematical configurations, all in the dipole regime. The M3CWZ model is thoroughly tested with an extensive comparison with available theoretical results and COLTRIMS measurements performed at projectile energies of Ei = 81 eV [Ren et al., Phys. Rev. A 95, 022701 (2017)] and Ei = 65 eV [Zhou et al., Phys. Rev. A 104, 012817 (2021)]. Similar to other theoretical models, an overall good agreement with both sets of measured data is observed for the angular distributions. Our calculated cross-sections' magnitudes are also satisfactory when compared to the other theoretical results, as well as to the cross-normalized relative scale data at 81 eV impact energy. The 65 eV set of data, measured on an absolute scale, offers a further challenging task for theoretical descriptions, and globally the M3CWZ performs fairly well and comparably to other theories. The proposed approach with variable charges somehow allows to capture the main multicenter distortion effects while avoiding high computational costs. [ABSTRACT FROM AUTHOR]

Published

2024

6. Bridging electronic and classical density-functional theory using universal machine-learned functional approximations.

Author

Kelley, Michelle M., Quinton, Joshua, Fazel, Kamron, Karimitari, Nima, Sutton, Christopher, and Sundararaman, Ravishankar

Subjects

*ELECTRON kinetic energy, *CONVOLUTIONAL neural networks, *ISING model, *FUNCTIONALS, *ELECTRONS

Abstract

The accuracy of density-functional theory (DFT) calculations is ultimately determined by the quality of the underlying approximate functionals, namely the exchange-correlation functional in electronic DFT and the excess functional in the classical DFT formalism of fluids. For both electrons and fluids, the exact functional is highly nonlocal, yet most calculations employ approximate functionals that are semi-local or nonlocal in a limited weighted-density form. Machine-learned (ML) nonlocal density-functional approximations show promise in advancing applications of both electronic and classical DFTs, but so far these two distinct research areas have implemented disparate approaches with limited generality. Here, we formulate a universal ML framework and training protocol to learn nonlocal functionals that combine features of equivariant convolutional neural networks and the weighted-density approximation. We prototype this new approach for several 1D and quasi-1D problems and demonstrate that functionals with exactly the same hyperparameters achieve excellent accuracy for a diverse set of systems, including the hard-rod fluid, the inhomogeneous Ising model, the exact exchange energy of electrons, the electron kinetic energy for orbital-free DFT, as well as for liquid water with 1D inhomogeneities. These results lay the foundation for a universal ML approach to approximate exact 3D functionals spanning electronic and classical DFTs. [ABSTRACT FROM AUTHOR]

Published

2024

7. Dissociative electron attachment and Ar+ reaction with chromium hexacarbonyl, 296–400 K.

Author

Miller, Thomas M., Rodriguez, Virginia G., Ard, Shaun G., Viggiano, Albert A., and Shuman, Nicholas S.

Subjects

*ELECTRONS, *CHROMIUM, *CATIONS, *TEMPERATURE, *MEASUREMENT

Abstract

Dissociative electron attachment rate constants have been measured for Cr(CO)6 under thermal conditions, 296–400 K, yielding Cr(CO)5− product. At 296 K, 2.92 ± 0.70 cm3 s−1 was measured and a small decrease with temperature was observed (2.72 ± 0.70 cm3 s−1 at 400 K). We additionally determined the cation products of Ar+ reacting with Cr(CO)6. [ABSTRACT FROM AUTHOR]

Published

2024

8. Sulfur vacancy synergistically coupling grain cluster for boosting MoS2 piezoresistive properties.

Author

Pang, Xing, Zhang, Qi, Liang, Xiaoya, Qin, Weilin, Xu, Hanyang, and Zhao, Yulong

Subjects

*ELECTRON transport, *STRUCTURAL stability, *SULFUR, *NANOPARTICLES, *ELECTRONS

Abstract

MoS2 can be used for piezoresistive sensors because of its excellent mechanical and electrical properties. Herein, MoS2 nanoparticles with sulfur vacancies synergistically coupled with grain clusters to boost piezoresistive properties are fabricated. Moreover, we have demonstrated that they can be regulated efficiently for gauge factor (GF) from 2.97 to 9.99. In particular, the MoS2 nanoparticles with sulfur vacancies of 31.8% and grain cluster of 29.6 nm at the annealing temperature of 500 °C are compatible with synergistic optimization. The abundant sulfur vacancies provide many free electrons as carriers, benefiting the electron transport capability, and the conductive channels formed by the larger grain clusters endow structural stability and significant piezoresistive properties of the nanoparticles. This work demonstrates the promise of MoS2 nanoparticles as novel piezoresistive advanced materials. [ABSTRACT FROM AUTHOR]

Published

2024

9. Extended transfer matrix method for electron transmission in anisotropic 2D materials: Interplay of strain and (a)periodicity of potentials.

Author

Díaz-Bautista, Erik, Betancur-Ocampo, Yonatan, and Raya, Alfredo

Subjects

*TRANSFER matrix, *STRAIN tensors, *ELECTRIC potential, *ELECTRONS, *GRAPHENE

Abstract

We extend the conventional transfer matrix method to include anisotropic features for electron transmission in two-dimensional materials, such as breaking reflection law in pseudo-spin phases and wave vectors, which are not usually considered appropriately in the literature. This method allows us to study transmission properties of anisotropic and stratified electrostatic potential media from a wide range of tunable parameters, which include strain tensor and gating. We apply the extended matrix method to obtain the electron transmission, conductance, and Fano factor for the interplay of a uniaxially strained graphene sheet with external one-dimensional aperiodic potentials. Our results suggest the possibility of visualizing this interplay from conductance measurements. [ABSTRACT FROM AUTHOR]

Published

2024

10. Efficient random phase approximation for diradicals.

Author

Shirazi, Reza G., Rybkin, Vladimir V., Marthaler, Michael, and Golubev, Dmitry S.

Subjects

*BIRADICALS, *ELECTRONS, *MOLECULES, *FORECASTING

Abstract

We apply the analytically solvable model of two electrons in two orbitals to diradical molecules, characterized by two unpaired electrons. The effect of doubly occupied and empty orbitals is taken into account by means of random phase approximation (RPA). We show that in the static limit, the direct RPA leads to the renormalization of the parameters of the two-orbital model. We test our model by comparing its predictions for singlet–triplet splitting with the results of several multi-reference methods for a set of thirteen molecules. We find that for this set, the static RPA results are close to those of the NEVPT2 method with two orbitals and two electrons in the active space. [ABSTRACT FROM AUTHOR]

Published

2024

11. Bismuth-related defects in n-type silicon irradiated with protons: A comparison to similar defects formed under electron irradiation.

Author

Emtsev, Vadim, Abrosimov, Nikolay, Kozlovski, Vitalii, Lastovskii, Stanislav, Oganesyan, Gagik, and Poloskin, Dmitrii

Subjects

*PROTONS, *RADIATION, *SILICON, *ELECTRONS, *ATOMS

Abstract

Electrical properties of defects produced in strongly bismuth-doped silicon by 15 MeV protons are investigated in detail. Electrical measurements on irradiated samples by means of the van der Pauw technique are conducted over a wide temperature range of 20–300 K to furnish information on radiation-produced complexes. It is shown that the properties of the dominant bismuth-related defects are the same as earlier found in the electron-irradiated material. These complexes are tentatively identified as bismuth–vacancy pairs being deep donors. Their atomic configuration appears to be radically different from what is known about similar vacancy-related defects with other group-V impurities. These bismuth-related pairs are stable up to T ≈ 300 °C. Some special features of defect formation and annealing processes of radiation defects in bismuth-doped silicon subjected to electron and proton irradiation are discussed. This information may be of advantage in modeling impurity-related complexes containing oversized impurity atoms in silicon. [ABSTRACT FROM AUTHOR]

Published

2024

12. Analytical model for estimating the equilibrium plasma quantities in an electron beam–plasma system.

Author

Sun, Haomin, Chen, Jian, Sun, Guangyu, and Xu, Liang

Subjects

*ELECTRON temperature, *PLASMA equilibrium, *ENERGY density, *ELECTRON plasma, *ELECTRONS, *ELECTRON beams

Abstract

We develop an analytical model for estimating the equilibrium quantities, such as electron temperature and number density, in an electron beam–plasma interaction system. This model provides a convenient way to calculate the effective electron temperature and density by considering the energy balance of the bulk cold electrons. Six energy sources/losses terms relevant to the cold electrons are accounted for, where quasi-linear theory is applied for estimating wave heating at equilibrium. We compare this calculation with the particle-in-cell (PIC) simulation results and find good agreement. Based on these results, we then consider two situations where we can simplify our model. The first is dominated by the balance between electron–electron Coulomb collisions and loss to the anode, which is mostly relevant to the conduction phase of plasma switches. The second is dominated by wave heating balanced by the anode loss, relevant to the electron beam–plasma discharge systems. We then couple our simplified energy balance model with the ion diffusion model and solve both the number density and the electron temperature as functions of the current density, electrode distance, pressure, and applied voltage, where a nice agreement is also obtained when comparing to PIC simulations. [ABSTRACT FROM AUTHOR]

Published

2024

13. Buffer gas cooled ice chemistry. II. Ice generation and mm-wave detection of molecules desorbed from an ice.

Author

Hager, T. J., Moore, B. M., Borengasser, Q. D., Kanaherarachchi, A. C., Renshaw, K. T., Radhakrishnan, S., Hall, G. E., and Broderick, B. M.

Subjects

*PROOF of concept, *PHOTONS, *DESORPTION, *SPECTROMETRY, *ELECTRONS

Abstract

This second paper in a series of two describes the chirped-pulse ice apparatus that permits the detection of buffer gas cooled molecules desorbed from an energetically processed ice using broadband mm-wave rotational spectroscopy. Here, we detail the lower ice stage developed to generate ices at 4 K, which can then undergo energetic processing via UV/VUV photons or high-energy electrons and which ultimately enter the gas phase via temperature-programmed desorption (TPD). Over the course of TPD, the lower ice stage is interfaced with a buffer gas cooling cell that allows for sensitive detection via chirped-pulse rotational spectroscopy in the 60–90 GHz regime. In addition to a detailed description of the ice component of this apparatus, we show proof-of-principle experiments demonstrating the detection of H2CO products formed through irradiation of neat methanol ices or 1:1 CO + CH4 mixed ices. [ABSTRACT FROM AUTHOR]

Published

2024

14. Observation of a core-excited dipole-bound state ∼1 eV above the electron detachment threshold in cryogenically cooled acetylacetonate.

Author

Jara-Toro, Rafael A., Taccone, Martín I., Dezalay, Jordan, Noble, Jennifer A., von Helden, Gert, and Pino, Gustavo A.

Subjects

*PHOTODETACHMENT threshold spectroscopy, *INFRARED spectroscopy, *EXCITED states, *RADICALS (Chemistry), *ELECTRONS

Abstract

Dipole-bound states in anions exist when a polar neutral core binds an electron in a diffuse orbital through charge–dipole interaction. Electronically excited polar neutral cores can also bind an electron in a diffuse orbital to form Core-Excited Dipole-Bound States (CE-DBSs), which are difficult to observe because they usually lie above the electron detachment threshold, leading to very short lifetimes and, thus, unstructured transitions. We report here the photodetachment spectroscopy of cryogenically cooled acetylacetonate anion (C5H7O2−) recorded by detecting the neutral radical produced upon photodetachment and the infrared spectroscopy in He-nanodroplets. Two DBSs were identified in this anion. One of them lies close to the electron detachment threshold (∼2.74 eV) and is associated with the ground state of the radical (D0-DBS). Surprisingly, the other DBS appears as resonant transitions at 3.69 eV and is assigned to the CE-DBS associated with the first excited state of the radical (D1-DBS). It is proposed that the resonant transitions of the D1-DBS are observed ∼1 eV above the detachment threshold because its lifetime is determined by the internal conversion to the D0-DBS, after which the fast electron detachment takes place. [ABSTRACT FROM AUTHOR]

Published

2024

15. Exact factorization of the photon–electron–nuclear wavefunction: Formulation and coupled-trajectory dynamics.

Author

Sangiogo Gil, Eduarda, Lauvergnat, David, and Agostini, Federica

Subjects

*DEGREES of freedom, *FACTORIZATION, *PHOTONS, *ELECTRONS, *ALGORITHMS, *TRAJECTORIES (Mechanics)

Abstract

We employ the exact-factorization formalism to study the coupled dynamics of photons, electrons, and nuclei at the quantum mechanical level, proposing illustrative examples of model situations of nonadiabatic dynamics and spontaneous emission of electron–nuclear systems in the regime of strong light–matter coupling. We make a particular choice of factorization for such a multi-component system, where the full wavefunction is factored as a conditional electronic amplitude and a marginal photon–nuclear amplitude. Then, we apply the coupled-trajectory mixed quantum–classical (CTMQC) algorithm to perform trajectory-based simulations, by treating photonic and nuclear degrees of freedom on equal footing in terms of classical-like trajectories. The analysis of the time-dependent potentials of the theory along with the assessment of the performance of CTMQC allows us to point out some limitations of the current approximations used in CTMQC. Meanwhile, comparing CTMQC with other trajectory-based algorithms, namely multi-trajectory Ehrenfest and Tully surface hopping, demonstrates the better quality of CTMQC predictions. [ABSTRACT FROM AUTHOR]

Published

2024

16. A molecular ground electronic state with an occupied 5g spinor—The superheavy (E125)F molecule.

Author

Peterson, Kirk A. and Malli, Gulzari L.

Subjects

*IONIZATION energy, *SPINORS, *ELECTRONS, *ATOMS, *MOLECULES

Abstract

Fully relativistic calculations, primarily at the 4-component coupled-cluster singles and doubles with perturbative triples [CCSD(T)] level of theory with the Dirac–Coulomb (DC) Hamiltonian, have been carried out for the superheavy (E125)F molecule using large Gaussian basis sets. The electronic ground state is determined to have an [Og]8s25g16f3 configuration on E125 with an Ω = 6 ground state and an 8p electron largely donated to F. A Mulliken population analysis indicates that the ground state is mainly ionic with a partial charge of +0.79 on E125 and a single sigma bond involving the F 2p and E125 8p spinors. The occupied g spinor is not involved in the bonding. With the largest basis set used in this work, the (0 K) dissociation energy was calculated at the DC-CCSD(T) level of theory to be 7.02 eV. Analogous calculations were also carried out for the E125 atom, both the neutral and its cation. The lowest energy electron configuration of E125+, [Og] 8 s 1 / 2 2 5 g 7 / 2 1 6 f 5 / 2 3 with a J = 6 ground state, was found to be similar to that in (E125)F, while the neutral E125 atom has an [Og] 8 s 1 / 2 2 5 g 7 / 2 1 6 f 5 / 2 2 7 d 3 / 2 1 8 p 1 / 2 1 ground state electron configuration with a J = 17/2 ground state. The ionization energy (IE) of E125 is reported for the first time and is calculated to be 4.70 eV at the DC-CCSD(T) level of theory. Non-relativistic calculations were also carried out on the E125 atom and the (E125)F molecule. The non-relativistic ground state of the E125 atom was calculated to have a 5g5 ground state with an IE of just 3.4 eV. The net effect of relativity on (E125)F is to stabilize its bonding. [ABSTRACT FROM AUTHOR]

Published

2024

17. Mechanism of quantum chaos in molecular nonadiabatic electron dynamics.

Author

Takatsuka, Kazuo and Arasaki, Yasuki

Subjects

*QUANTUM chaos, *EXCITED states, *WAVE packets, *ELECTRONS, *BORON

Abstract

The quantum nuclear kinematic interactions with electrons (or nonadiabatic interactions) are the inherent driving force that possibly causes a mixture of the adiabatic electronic states in molecules. Particularly in systems whose electron wavepackets lie in a densely quasi-degenerate electronic-state manifold where many-dimensional and many-state nonadiabatic interactions last continually, we have found before that those extensive mixings can lead to a quantum electronic-state chaos [K. Takatsuka and Y. Arasaki, J. Chem. Phys. 159, 074110 (2023)]. This chaos of electron dynamics is a new kind yet generic. This Communication identifies the mathematical/physical mechanism of this class of chaos by means of the collective coordinate analysis of the nonadiabatic interactions, along with the numerical applications to excited states of boron clusters. Some physical consequences of the present chaos are also discussed. [ABSTRACT FROM AUTHOR]

Published

2024

18. Comprehensive study of interface state via the time-dependent second harmonic generation.

Author

Zhang, Libo, Ye, Li, Zhao, Weiwei, Huang, Chongji, Li, Tao, Min, Tai, Yang, Jinbo, Tian, Mingliang, and Chen, Xuegang

Subjects

*SECOND harmonic generation, *DENSITY of states, *ELECTRIC fields, *SEMICONDUCTORS, *ELECTRONS

Abstract

Electric field induced time-dependent second harmonic generation (TD-SHG) is an emerging sensitive and non-contact method for qualitatively/quantitatively probing semiconductor parameters. The TD-SHG signal is related to the evolution of the built-in electric field due to laser-induced electron generation and transportation. Here, we conducted a comprehensive study of fixed charge density (Q ox ) and interface state density (D it ) using the conventional conductance method to compare them with the SHG signal from TD-SHG. The extracted Q ox is around 2.49 × 1010 cm−2 regardless of SiO2 thickness, corresponding to the constant SHG intensity at the minimum of TD-SHG. The extracted D it linearly decreases with the SiO2 thickness, which is related to the linear change of extracted time constant from TD-SHG. Therefore, the TD-SHG, being a sensitive and non-contact method as well as simple and fast, can serve as an alternative approach to test the semiconductor parameters, which may facilitate semiconductor testing. [ABSTRACT FROM AUTHOR]

Published

2024

19. Electron scattering cross sectional data for precursors used in plasma-assisted deposition.

Author

Pandey, Meenu and Antony, Bobby

Subjects

*ELECTRON scattering, *ANAPLASTIC large-cell lymphoma, *ELECTRONS, *INTEGRALS, *ELASTIC scattering

Abstract

In this study, a comprehensive electron scattering analysis is performed on the precursors AlF 3 and AlCl 3 used in the plasma-assisted deposition technique. We used the R-matrix and spherical complex optical potential formalisms to calculate the integral elastic cross sections for electron energies between 0.1 and 5000 eV. At low energies, we computed differential and integral elastic cross sections and excitation cross sections using the R-matrix method. We have also reported the ionization cross section using the complex scattering potential-ionization contribution method and the binary-encounter-Bethe method. Our computed results show overall good agreement with the available data in the literature. [ABSTRACT FROM AUTHOR]

Published

2024

20. Glycyrrhetinic acid interaction with solvated and free electrons studied by the CIDNP and dissociative electron attachment techniques.

Author

Polyakov, Nikolay E., Mastova, Anna V., Kruppa, Alexander I., Asfandiarov, Nail L., and Pshenichnyuk, Stanislav A.

Subjects

*SOLVATED electrons, *POLARIZATION (Nuclear physics), *PHOTOINDUCED electron transfer, *OXIDATION-reduction reaction, *REACTIVE oxygen species, *ELECTRONS

Abstract

Electron transfer plays a crucial role in living systems, including the generation of reactive oxygen species (ROS). Oxygen acts as the terminal electron acceptor in the respiratory chains of aerobic organisms as well as in some photoinduced processes followed by the formation of ROS. This is why the participation of exogenous antioxidants in electron transfer processes in living systems is of particular interest. In the present study, using chemically induced dynamic nuclear polarization (CIDNP) and dissociative electron attachment (DEA) techniques, we have elucidated the affinity of solvated and free electrons to glycyrrhetinic acid (GA)—the aglicon of glycyrrhizin (the main active component of Licorice root). CIDNP is a powerful instrument to study the mechanisms of electron transfer reactions in solution, but the DEA technique shows its effectiveness in gas phase processes. For CIDNP experiments, the photoionization of the dianion of 5-sulfosalicylic acid (HSSA2−) was used as a model reaction of solvated electron generation. DEA experiments testify that GA molecules are even better electron acceptors than molecular oxygen, at least under gas-phase conditions. In addition, the effect of the solvent on the energetics of the reactants is discussed. [ABSTRACT FROM AUTHOR]

Published

2024

21. Reduction reactions at the interface between CdS quantum dot and Z-type ligands driven by electron injection in the electroluminescent processes.

Author

Huo, Xiangyu, Xie, Yujuan, Wang, Xian, Zhang, Li, and Yang, Mingli

Subjects

*QUANTUM dots, *TIME-dependent density functional theory, *ELECTRONS, *LIGANDS (Chemistry), *COORDINATION polymers

Abstract

The efficient and stable electroluminescence of quantum dots (QDs) is of great importance in their applications in new display technologies. The short service life of blue QDs, however, hinders their development and commercialization. Different mechanisms have been proposed for the destabilization of QDs in electroluminescent processes. Based on real-time time-dependent density functional theory studies on the QD models covered by Z-type ligands (XAc2, X = Cd, Zn, Mg), the structural evolution is simulated to reveal the mechanism of the reduction reactions induced by electron injection. Our simulations reproduce the experimental observations that the reduction reactions occur at the QD–ligand interface, and the reduced Cd atom is almost in a zero valence state. However, different sites are predicted for the reactions in which the surface metal atom of the QD instead of the metal atom in the ligands is reduced. As a result, one of the arms of the chelate ligand leaves the QD, which tends to cause damage to its electroluminescent performance. Our findings contribute to a mechanistic understanding of the reduction reactions that occurred at the QD–ligand interface. [ABSTRACT FROM AUTHOR]

Published

2024

22. Augmentation of the electron counting rule with Ising model.

Author

Kawka, Karol, Kempisty, Paweł, Sakowski, Konrad, Krukowski, Stanisław, Boćkowski, Michał, Bowler, David, and Kusaba, Akira

Subjects

*ISING model, *INTEGERS, *SURFACE reconstruction, *DENSITY functional theory, *ELECTRONS

Abstract

The stability of a mixture of two different surface reconstructions is investigated focusing on GaN(0001) surface mixed with Ga a d (2 × 2) and 3Ga-H(2 × 2) domains using the density functional theory calculations. Since the number of candidate structures is enormous, the structures sampled by Bayesian optimization are analyzed. As a result, the local electron counting (EC) rule alone was found to be insufficient to explain such stability. Then, augmenting the EC rule, a data-driven Ising model is proposed. The model allows the evaluation of the whole enormous number of candidate structures. The approach is expected to be useful for theoretical studies of such mixtures on various semiconductor surfaces. [ABSTRACT FROM AUTHOR]

Published

2024

23. A fast and smooth one-electron approach for investigating charge transfer states and D1–D0 crossings for systems with odd numbers of electrons.

Author

Qiu, Tian, Bian, Xuezhi, Tao, Zhen, and Subotnik, Joseph E.

Subjects

*ODD numbers, *NUMBER systems, *POTENTIAL energy surfaces, *ELECTRON configuration, *ELECTRONS, *VECTOR spaces

Abstract

We propose an efficient version of ensemble Hartree–Fock/density functional theory to calculate a set of two charge-transfer states for systems with odd-numbers of electrons. The approach does require definitions of donor/acceptor fragments; however, the approach is not very sensitive to such definitions—even in the limit of very strong electronic coupling. The key ansatz is that, by mandating that the vector space spanned by the active orbitals projects equally onto the donor and acceptor fragments, such a constraint eliminates all intra-molecular local excitations and makes it far easier to generate potential energy surfaces that are smooth over a wide region of configuration space. The method is fast, working with only two electron configurations, and should be useful for ab initio non-adiabatic dynamics in the near future. [ABSTRACT FROM AUTHOR]

Published

2024

24. Probing Bioinorganic Electron Spin Decoherence Mechanisms with an Fe2S2 Metalloprotein.

Author

Totoiu, Christian, Follmer, Alec, Oyala, Paul, and Hadt, Ryan

Subjects

Metalloproteins, Quantum Theory, Electrons, Electron Transport, Ferredoxins

Abstract

Recent efforts have sought to develop paramagnetic molecular quantum bits (qubits) as a means to store and manipulate quantum information. Emerging structure-property relationships have shed light on electron spin decoherence mechanisms. While insights within molecular quantum information science have derived from synthetic systems, biomolecular platforms would allow for the study of decoherence phenomena in more complex chemical environments and further leverage molecular biology and protein engineering approaches. Here we have employed the exchange-coupled ST = 1/2 Fe2S2 active site of putidaredoxin, an electron transfer metalloprotein, as a platform for fundamental mechanistic studies of electron spin decoherence toward spin-based biological quantum sensing. At low temperatures, decoherence rates were anisotropic, reflecting a hyperfine-dominated decoherence mechanism, standing in contrast to the anisotropy of molecular systems observed previously. This mechanism provided a pathway for probing spatial effects on decoherence, such as protein vs solvent contributions. Furthermore, we demonstrated spatial sensitivity to single point mutations via site-directed mutagenesis and temporal sensitivity for monitoring solvent isotope exchange. Thus, this study demonstrates a step toward the design and construction of biomolecular quantum sensors.

Published

2024

25. Phase shifter based on two-dimensional electron system on a dielectric substrate.

Author

Dzhikirba, K. R., Khudaiberdiev, D. A., Shuvaev, A., Astrakhantseva, A. S., Kukushkin, I. V., and Muravev, V. M.

Subjects

*PHASE shifters, *DIELECTRICS, *ELECTRON density, *ELECTRONS, *TERAHERTZ spectroscopy, *ELECTROMAGNETIC radiation, *PHASE shift (Nuclear physics), *RADIATION

Abstract

We experimentally investigate phase shift gained by electromagnetic radiation transmitted through a two-dimensional electron system (2DES) on a dielectric substrate. We systematically examined the dependence of the phase shift on the radiation frequency and 2DES electron density for the GaAs semiconductor substrate. A theoretical approach was developed that found good agreement with experimental results. We demonstrate a practically achievable phase shift of 105 °. Obtained findings pave the way for the design of terahertz devices that can manipulate the radiation phase in a controlled and precise manner. [ABSTRACT FROM AUTHOR]

Published

2024

26. Electron irradiation effects on the optical properties of Hf- and Zn-doped β-Ga2O3.

Author

Remple, Cassandra, Huso, Jesse, Weber, Marc H., McCloy, John S., and McCluskey, Matthew D.

Subjects

*OPTICAL properties, *IRRADIATION, *ELECTRONS, *GALLIUM

Abstract

Optical and electrical properties of Hf- and Zn-doped β-Ga2O3 samples, which are n-type and insulating, respectively, were altered via high-energy electron irradiation at 2.5 or 0.5 MeV. The β-Ga2O3:Hf samples irradiated with 2.5 MeV electrons experienced a color change from blue to yellow and a large drop in conductivity, attributed to the creation of gallium vacancies, which compensate donors. This irradiation resulted in the absence of free carrier absorption and the presence of Cr3+ photoluminescence (PL). PL mapping prior to irradiation revealed optically active ZnO precipitates that formed during the growth of β-Ga2O3:Zn. These precipitates have a 384 nm (3.23 eV) stacking fault emission in the core; in the outer shell of the precipitate, the PL blue-shifts to 377 nm (3.29 eV) and a broad defect band is observed. After 0.5 MeV electron irradiation, the defect band broadened and increased in intensity. The blue PL band (435 nm) of β-Ga2O3 was enhanced for both Hf- and Zn-doped samples irradiated with 0.5 MeV. This enhancement is correlated with an increase in oxygen vacancies. [ABSTRACT FROM AUTHOR]

Published

2024

27. Electron irradiation effects on the optical properties of Hf- and Zn-doped β-Ga2O3.

Author

Remple, Cassandra, Huso, Jesse, Weber, Marc H., McCloy, John S., and McCluskey, Matthew D.

Subjects

OPTICAL properties, IRRADIATION, ELECTRONS, GALLIUM

Abstract

Optical and electrical properties of Hf- and Zn-doped β-Ga2O3 samples, which are n-type and insulating, respectively, were altered via high-energy electron irradiation at 2.5 or 0.5 MeV. The β-Ga2O3:Hf samples irradiated with 2.5 MeV electrons experienced a color change from blue to yellow and a large drop in conductivity, attributed to the creation of gallium vacancies, which compensate donors. This irradiation resulted in the absence of free carrier absorption and the presence of Cr3+ photoluminescence (PL). PL mapping prior to irradiation revealed optically active ZnO precipitates that formed during the growth of β-Ga2O3:Zn. These precipitates have a 384 nm (3.23 eV) stacking fault emission in the core; in the outer shell of the precipitate, the PL blue-shifts to 377 nm (3.29 eV) and a broad defect band is observed. After 0.5 MeV electron irradiation, the defect band broadened and increased in intensity. The blue PL band (435 nm) of β-Ga2O3 was enhanced for both Hf- and Zn-doped samples irradiated with 0.5 MeV. This enhancement is correlated with an increase in oxygen vacancies. [ABSTRACT FROM AUTHOR]

Published

2024

28. State-selective dissociative double ionization of CH3I and CH2I2 via I 4d core-hole states studied by multi-electron–ion coincidence spectroscopy.

Author

Fushitani, Mizuho, Hikosaka, Yasumasa, Tashiro, Motomichi, and Hishikawa, Akiyoshi

Subjects

*COINCIDENCE, *SPECTROMETRY, *ULTRAVIOLET radiation, *ELECTRON impact ionization, *ELECTRON energy loss spectroscopy, *AUGERS, *ELECTRONS

Abstract

The dissociative double ionization of CH3I and CH2I2 irradiated with extreme ultraviolet light at hv = 100 eV is investigated by multi-electron–ion coincidence spectroscopy using a magnetic bottle type electron spectrometer. The spin–orbit state-resolved Auger electron spectra for the I 4d core-hole states, (I 4d3/2)−1 and (I 4d5/2)−1, provide clear identifications of electronic states of CH3I2+ and CH2I22+. The dominant ion species produced after the double ionization correlate with the Auger electron energy, showing that different fragmentation pathways are open depending on the electronic states populated by the Auger decay. Theoretical calculations are performed to understand the fragmentation from the doubly charged states and the observed spin–orbit specificity in the Auger decay. [ABSTRACT FROM AUTHOR]

Published

2024

29. A bivariational, stable, and convergent hierarchy for time-dependent coupled cluster with adaptive basis sets.

Author

Højlund, Mads Greisen and Christiansen, Ove

Subjects

*UNITARY transformations, *ELECTRONS

Abstract

We propose a new formulation of time-dependent coupled cluster with adaptive basis functions and division of the one-particle space into active and secondary subspaces. The formalism is fully bivariational in the sense of a real-valued time-dependent bivariational principle and converges to the complete-active-space solution, a property that is obtained by the use of biorthogonal basis functions. A key and distinguishing feature of the theory is that the active bra and ket functions span the same space by construction. This ensures numerical stability and is achieved by employing a split unitary/non-unitary basis set transformation: the unitary part changes the active space itself, while the non-unitary part transforms the active basis. The formulation covers vibrational as well as electron dynamics. Detailed equations of motion are derived and implemented in the context of vibrational dynamics, and the numerical behavior is studied and compared to related methods. [ABSTRACT FROM AUTHOR]

Published

2024

30. MesoHOPS: Size-invariant scaling calculations of multi-excitation open quantum systems.

Author

Citty, Brian, Lynd, Jacob K., Gera, Tarun, Varvelo, Leonel, and Raccah, Doran I. G. B.

Subjects

*ELECTRONIC excitation, *MOLECULAR dynamics, *PHOTOEXCITATION, *HETEROJUNCTIONS, *ELECTRONS

Abstract

The photoexcitation dynamics of molecular materials on the 10–100 nm length scale depend on complex interactions between electronic and vibrational degrees of freedom, rendering exact calculations difficult or intractable. The adaptive Hierarchy of Pure States (adHOPS) is a formally exact method that leverages the locality imposed by interactions between thermal environments and electronic excitations to achieve size-invariant scaling calculations for single-excitation processes in systems described by a Frenkel–Holstein Hamiltonian. Here, we extend adHOPS to account for arbitrary couplings between thermal environments and vertical excitation energies, enabling formally exact, size-invariant calculations that involve multiple excitations or states with shared thermal environments. In addition, we introduce a low-temperature correction and an effective integration of the noise to reduce the computational expense of including ultrafast vibrational relaxation in Hierarchy of Pure States (HOPS) simulations. We present these advances in the latest version of the open-source MesoHOPS library and use MesoHOPS to characterize charge separation at a one-dimensional organic heterojunction when both the electron and hole are mobile. [ABSTRACT FROM AUTHOR]

Published

2024

31. How electrons still guard the space: Electron number distribution functions based on QTAIM∩ELF intersections.

Author

Barrena-Espés, Daniel, Munárriz, Julen, and Martín Pendás, Ángel

Subjects

*ELECTRON distribution, *ATOMS in molecules theory, *DISTRIBUTION (Probability theory), *ELECTRON density, *ELECTRONS

Abstract

Despite the importance of the one-particle picture provided by the orbital paradigm, a rigorous understanding of the spatial distribution of electrons in molecules is still of paramount importance to chemistry. Considerable progress has been made following the introduction of topological approaches, capable of partitioning space into chemically meaningful regions. They usually provide atomic partitions, for example, through the attraction basins of the electron density in the quantum theory of atoms in molecules (QTAIM) or electron-pair decompositions, as in the case of the electron localization function (ELF). In both cases, the so-called electron distribution functions (EDFs) provide a rich statistical description of the electron distribution in these spatial domains. Here, we take the EDF concept to a new fine-grained limit by calculating EDFs in the QTAIM ∩ ELF intersection domains. As shown in AHn systems based on main group elements, as well as in the CO, NO, and BeO molecules, this approach provides an exquisitely detailed picture of the electron distribution in molecules, allowing for an insightful combination of the distribution of electrons between Lewis entities (such as bonds and lone pairs) and atoms at the same time. Besides mean-field calculations, we also explore the impact of electron correlation through Hartree–Fock (HF), density functional theory (DFT) (B3LYP), and CASSCF calculations. [ABSTRACT FROM AUTHOR]

Published

2024

32. Spatiotemporal evolution of ultrafast photocarrier dynamics across WS2–ReS2 lateral interface.

Author

Cui, Qiannan, Li, Yuanyuan, Zhang, He, Chang, Jianhua, Xu, Hua, and Xu, Chunxiang

Subjects

*HETEROSTRUCTURES, *PHYSICS, *FEMTOSECOND lasers, *ELECTRONS

Abstract

2D lateral heterostructures possess atomically sharp lateral interfaces, while understanding of their ultrafast photocarrier dynamics from a spatiotemporal viewpoint is rather elusive. In this study, we have investigated the spatiotemporal evolution of photocarrier dynamics across the 1D lateral interface of a WS2–ReS2 2D lateral heterostructure utilizing femtosecond laser pump–probe. The nontrivial band offset across the 1D lateral interface markedly mediates the spatiotemporal photocarrier transfer and transport processes. Subsequently, a hole accumulation region on the WS2 side and an electron accumulation region (1DEG) on the ReS2 side have been spatially identified by correlating ultrafast photocarrier signals. The measured width of the unilateral depletion region is 1360 ± 160 nm. Our work has provided substantial insights into mediated photocarrier dynamics in the 2D lateral heterostructure, which will benefit explorations in 2D interfacial physics and 2D lateral optoelectronic devices. [ABSTRACT FROM AUTHOR]

Published

2024

33. A simple one-electron expression for electron rotational factors.

Author

Qiu, Tian, Bhati, Mansi, Tao, Zhen, Bian, Xuezhi, Rawlinson, Jonathan, Littlejohn, Robert G., and Subotnik, Joseph E.

Subjects

*ELECTRONS, *ALGORITHMS, *WISHES, *MATRICES (Mathematics)

Abstract

Within the context of fewest-switch surface hopping (FSSH) dynamics, one often wishes to remove the angular component of the derivative coupling between states J and K . In a previous set of papers, Shu et al. [J. Phys. Chem. Lett. 11, 1135–1140 (2020)] posited one approach for such a removal based on direct projection, while we isolated a second approach by constructing and differentiating a rotationally invariant basis. Unfortunately, neither approach was able to demonstrate a one-electron operator O ̂ whose matrix element J O ̂ K was the angular component of the derivative coupling. Here, we show that a one-electron operator can, in fact, be constructed efficiently in a semi-local fashion. The present results yield physical insight into designing new surface hopping algorithms and are of immediate use for FSSH calculations. [ABSTRACT FROM AUTHOR]

Published

2024

34. Driven electron g-factor anisotropy in layered III–V semiconductors: Interfacing, tunnel coupling, and structure inversion asymmetry effects.

Author

Toloza Sandoval, M. A., Leon Padilla, J. E., Wanderley, A. B., Sipahi, G. M., Diniz Chubaci, J. F., and Ferreira da Silva, A.

Subjects

*SEMICONDUCTOR junctions, *ELECTRONS, *ANISOTROPY, *PERTURBATION theory, *MAGNETIC fields

Abstract

A key piece for spintronic applications, the so-called electron g -factor engineering is still predominantly based on the semiconductor bulk g factor and its dependence on the bandgap energy. In nanostructures, however, the mesoscopic confinement introduces exclusive anisotropies, transforming scalar g factors into tensors, enabling different renormalization mechanisms as routes for fine-tuning the electron g factor. These questions we address in this comparative theoretical analysis between the obtained electron g -factor (tensor) anisotropies for realistic InAs | AlSb - and In 0.53 Ga 0.47 As | InP -based multilayers. The electron g -factor anisotropy, i.e., the difference between g factors for magnetic fields parallel and perpendicular to the interfaces, is analytically calculated via perturbation theory using the envelope-function approach based on the eight-band Kane model. Effects from bulk, interfacing, tunnel coupling, and structure inversion asymmetry are systematically introduced within a transparent comparative view; differences between obtained anisotropies, such as in the magnitude, sign, and other fine details, are analyzed in terms of the heterostructure parameters, mapped over different confining and tunnel-coupling regimes without requiring elaborated numerical computations. [ABSTRACT FROM AUTHOR]

Published

2024

35. The Hull Cutoff condition for magnetic insulation in crossed-field electron devices in the presence of a slow-wave structure.

Author

Wong, Patrick Y., Kuskov, Artem, Tobias, Benjamin, and Heinrich, Jonathon

Subjects

*LAMINAR flow, *ELECTRONS, *PHASE velocity, *MAGNETIC fields

Abstract

Crossed-Field Vacuum Electron Devices are ubiquitous in the High-Power Microwave field in either an oscillator/source or amplifier variant. A typical configuration consists of a magnetically insulated laminar electron flow in an anode–cathode gap with crossed electric (∝ V , voltage) and magnetic (B-) fields and a series of open resonant cavities/vanes located on the anode block that serve as a slow-wave structure (SWS). The SWS slows the phase velocity of the electromagnetic signal down so that the wave becomes synchronous with a layer of the electron flow but is often neglected when calculating the Hull magnetic field necessary to insulate the electrons. In particular, the guiding design equation for the critical cutoff B-field assumes a smooth anode wall. In this paper, we show that such an assumption severely narrows the operating regime in B–V space and that upon inclusion of a revised Hull Cutoff condition taking into account the SWS, operation at lower B and higher V is possible. This revised Hull Cutoff criterion for magnetic insulation in crossed-field devices is corroborated by Particle-in-Cell simulations using CST Particle Studio. [ABSTRACT FROM AUTHOR]

Published

2024

36. Electron bifurcation and fluoride efflux systems implicated in defluorination of perfluorinated unsaturated carboxylic acids by Acetobacterium spp.

Author

Yu, Yaochun, Xu, Fengjun, Zhao, Weiyang, Thoma, Calvin, Che, Shun, Richman, Jack, Jin, Bosen, Zhu, Yiwen, Xing, Yue, Wackett, Lawrence, and Men, Yujie

Subjects

Fluorides, Acetobacterium, Carboxylic Acids, Electrons, Biodegradation, Environmental, Halogenation, Bacterial Proteins, Fluorocarbons

Abstract

Enzymatic cleavage of C─F bonds in per- and polyfluoroalkyl substances (PFAS) is largely unknown but avidly sought to promote systems biology for PFAS bioremediation. Here, we report the reductive defluorination of α, β-unsaturated per- and polyfluorocarboxylic acids by Acetobacterium spp. The microbial defluorination products were structurally confirmed and showed regiospecificity and stereospecificity, consistent with their formation by enzymatic reactions. A comparison of defluorination activities among several Acetobacterium species indicated that a functional fluoride exporter was required for the detoxification of the released fluoride. Results from both in vivo inhibition tests and in silico enzyme modeling suggested the involvement of enzymes of the flavin-based electron-bifurcating caffeate reduction pathway [caffeoyl-CoA reductase (CarABCDE)] in the reductive defluorination. This is a report on specific microorganisms carrying out enzymatic reductive defluorination of PFAS, which could be linked to electron-bifurcating reductases that are environmentally widespread.

Published

2024

37. Structure Function Studies of Photosystem II Using X-Ray Free Electron Lasers

Author

Yano, Junko, Kern, Jan, and Yachandra, Vittal K

Subjects

Inorganic Chemistry, Chemical Sciences, Photosystem II Protein Complex, Lasers, Electrons, Water, X-Rays, Oxidation-Reduction, Models, Molecular, manganese, oxygen-evolving complex, photosystem II, photosynthetic water oxidation, X-ray crystallography, X-ray free electron laser, Medicinal and Biomolecular Chemistry, Biochemistry and Cell Biology, Chemical Engineering, Biophysics, Biochemistry and cell biology, Medicinal and biomolecular chemistry

Abstract

The structure and mechanism of the water-oxidation chemistry that occurs in photosystem II have been subjects of great interest. The advent of X-ray free electron lasers allowed the determination of structures of the stable intermediate states and of steps in the transitions between these intermediate states, bringing a new perspective to this field. The room-temperature structures collected as the photosynthetic water oxidation reaction proceeds in real time have provided important novel insights into the structural changes and the mechanism of the water oxidation reaction. The time-resolved measurements have also given us a view of how this reaction-which involves multielectron, multiproton processes-is facilitated by the interaction of the ligands and the protein residues in the oxygen-evolving complex. These structures have also provided a picture of the dynamics occurring in the channels within photosystem II that are involved in the transport of the substrate water to the catalytic center and protons to the bulk.

Published

2024

38. How well do one-electron self-interaction-correction methods perform for systems with fractional electrons?

Author

Zope, Rajendra R., Yamamoto, Yoh, and Baruah, Tunna

Subjects

*IONIZATION energy, *ELECTRONS, *KINETIC energy, *ENERGY density

Abstract

Recently developed locally scaled self-interaction correction (LSIC) is a one-electron SIC method that, when used with a ratio of kinetic energy densities (zσ) as iso-orbital indicator, performs remarkably well for both thermochemical properties as well as for barrier heights overcoming the paradoxical behavior of the well-known Perdew–Zunger self-interaction correction (PZSIC) method. In this work, we examine how well the LSIC method performs for the delocalization error. Our results show that both LSIC and PZSIC methods correctly describe the dissociation of H 2 + and He 2 + but LSIC is overall more accurate than the PZSIC method. Likewise, in the case of the vertical ionization energy of an ensemble of isolated He atoms, the LSIC and PZSIC methods do not exhibit delocalization errors. For the fractional charges, both LSIC and PZSIC significantly reduce the deviation from linearity in the energy vs number of electrons curve, with PZSIC performing superior for C, Ne, and Ar atoms while for Kr they perform similarly. The LSIC performs well at the endpoints (integer occupations) while substantially reducing the deviation. The dissociation of LiF shows both LSIC and PZSIC dissociate into neutral Li and F but only LSIC exhibits charge transfer from Li+ to F− at the expected distance from the experimental data and accurate ab initio data. Overall, both the PZSIC and LSIC methods reduce the delocalization errors substantially. [ABSTRACT FROM AUTHOR]

Published

2024

39. Hot luminescence of two-dimensional electron hole systems in modulation-doped silicon.

Author

Heinz, Friedemann D., Kwapil, Wolfram, and Glunz, Stefan W.

Subjects

*HOT carriers, *SURFACE passivation, *LUMINESCENCE, *SILICON surfaces, *ELECTRONS, *SILICON

Abstract

Modulation doping of silicon has great potential for miniaturization, surface passivation, and third generation photovoltaics (PV). At a modulation-doped silicon surface, we observe the formation of a 2D hole layer at the silicon surface at low temperatures by means of photoluminescence (PL) measurements. A line shape analysis of band–band and hot luminescence reveals the hole density (which is equal to the modulation-doped acceptor density). A high excitation intensity leads to a Fermi edge singularity of the band–band and hot PL emission. While the 2D layer can be characterized by the observed luminescence, the spectral region of twice the bandgap is fully dominated by emission from this surface layer, impeding the measurement of bulk hot luminescence, e.g., from Auger electrons or from nonthermalized carriers in a hot carrier PV device. [ABSTRACT FROM AUTHOR]

Published

2024

40. Combining extrapolated electron localization functions and Berlin's binding functions for the prediction of dissociative electron attachment.

Author

Titeca, Charlotte, Jagau, Thomas-C., and De Proft, Frank

Subjects

*ELECTRONS, *EXTRAPOLATION, *METASTABLE states, *DENSITY functional theory

Abstract

Computational study of electronic resonances is still a very challenging topic, with the phenomenon of dissociative electron attachment (DEA) being one of the multiple features worth investigating. Recently, we extended the charge stabilization method from energies to properties of conceptual density functional theory and applied this to metastable anionic states of ethene and chlorinated ethene derivatives to study the DEA mechanism present in these compounds. We now present an extension to spatial functions, namely, the electronic Fukui function and the electron localization function. The results of our analysis show that extrapolated spatial functions are relevant and useful for more precise localization of the unbound electron. Furthermore, we report for the first time the combination of the electron localization function with Berlin's binding function for these challenging electronic states. This promising methodology allows for accurate predictions of when and where DEA will happen in the molecules studied and provides more insight into the process. [ABSTRACT FROM AUTHOR]

Published

2024

41. Optimizing electron injection barriers and hole-trapping ability for high-performance photomultiplication-type ternary organic photodetectors.

Author

Huang, Jiang, Fan, Qingshan, Jin, Ziheng, Zhang, Hanqing, Dou, Zifan, Wang, Meiling, Li, Jian, Xu, Lin, Zhou, Guanrui, Zhang, Ting, and Chen, Shi

Subjects

*PHOTODETECTORS, *SPECTRAL sensitivity, *QUANTUM efficiency, *ELECTRONS, *FULLERENES, *RESEARCH personnel, *ELECTRON traps

Abstract

Photomultiplication-type organic photodetectors (PM-OPDs) have been stimulating more and more researchers' interest owing to their extremely high external quantum efficiency (EQE). To prepare high-performance PM-OPDs with a broadband spectral response range from visible to near-infrared and investigate the role of energy levels of the donor and acceptor on its responsiveness, the non-fullerene acceptor Y6 was added into the P3HT:PC71BM system in this work. The photomultiplication phenomenon with the highest EQE has been achieved under both forward and reverse bias when the ratio of Y6 in two acceptors approaches 80 wt. %. The introduction of Y6 not only promotes the formation of moderate hole traps in the active layer but also results in an appropriate amount of low injection barriers to allow more electron injection from the external circuit. Therefore, the spectral response of the device with 80 wt. % Y6 has been broadened from 750 to 950 nm, and the champion EQE of 15 691% at 10 V and 7639% at −20 V at 850 nm was achieved. This work reveals the importance of hole-trapping ability determined by the energy level difference between the donor and the acceptor for the selection of the multiplication system and provides a scheme for the design of high-performance broadband PM-OPDs. [ABSTRACT FROM AUTHOR]

Published

2024

42. Time-resolved photoelectron spectroscopy of iodide–4-thiouracil cluster: The ππ* state as a doorway for electron attachment.

Author

Asplund, Megan, Koga, Masafumi, Wu, Ying Jung, and Neumark, Daniel M.

Subjects

*PHOTOELECTRON spectroscopy, *ELECTRONIC excitation, *ELECTRONS, *EXCESS electrons, *ENTRANCES & exits, *CHARGE transfer, *ATOMS, *TIME-resolved spectroscopy

Abstract

The photophysics of thiobases—nucleobases in which one or more oxygen atoms are replaced with sulfur atoms— vary greatly depending on the location of sulfonation. Not only are direct dynamics of a neutral thiobase impacted, but also the dynamics of excess electron accommodation. In this work, time-resolved photoelectron spectroscopy is used to measure binary anionic clusters of iodide and 4-thiouracil, I− · 4TU. We investigate charge transfer dynamics driven by excitation at 3.88 eV, corresponding to the lowest ππ* transition of the thiouracil, and at 4.16 eV, near the cluster vertical detachment energy. The photoexcited state dynamics are probed by photodetachment with 1.55 and 3.14 eV pulses. Excitation at 3.88 eV leads to a signal from a valence-bound ion only, indicating a charge accommodation mechanism that does not involve a dipole-bound anion as an intermediate. Excitation at 4.16 eV rapidly gives rise to dipole-bound and valence-bound ion signals, with a second rise in the valence-bound signal corresponding to the decay of the dipole-bound signal. The dynamics associated with the low energy ππ* excitation of 4-thiouracil provide a clear experimental proof for the importance of localized excitation and electron backfilling in halide–nucleobase clusters. [ABSTRACT FROM AUTHOR]

Published

2024

43. The energies and charge and spin distributions in the low-lying levels of singlet and triplet N2V defects in diamond from direct variational calculations of the excited states.

Author

Mackrodt, William C., Platonenko, Alexander, Pascale, Fabien, and Dovesi, Roberto

Subjects

*EXCITED states, *ELECTRONIC excitation, *DIAMONDS, *PLANE wavefronts, *ELECTRONS, *CHARGE transfer

Abstract

This paper reports the energies and charge and spin distributions of the low-lying excited states in singlet and triplet N2V defects in diamond from direct Δ-SCF calculations based on Gaussian orbitals within the B3LYP, PBE0, and HSE06 functionals. They assign the observed absorption at 2.463 eV, first reported by Davies et al. [Proc. R. Soc. London 351, 245 (1976)], to the excitation of a N(sp3) lone-pair electron in the singlet and triplet states, respectively, with estimates of ∼1.1 eV for that of the unpaired electrons, C(sp3). In both cases, the excited states are predicted to be highly local and strongly excitonic with 81% of the C(sp3) and 87% of the N(sp3) excited charges localized at the three C atoms nearest neighbor (nn) to the excitation sites. Also reported are the higher excited gap states of both the N lone pair and C unpaired electron. Calculated excitation energies of the bonding sp3 hybrids of the C atoms nn to the four inner atoms are close to that of the bulk, which indicates that the N2V defect is largely a local defect. The present results are in broad agreement with those reported by Udvarhelyi et al. [Phys. Rev. B 96, 155211 (2017)] from plane wave HSE06 calculations, notably for the N lone pair excitation energy, for which both predict an energy of ∼2.7 eV but with a difference of ∼0.5 eV for the excitation of the unpaired electron. [ABSTRACT FROM AUTHOR]

Published

2024

44. Spin–orbit coupling of electrons on separate lanthanide atoms of Pr2O2 and its singly charged cation.

Author

Nakamura, Taiji, Dangi, Beni B., Wu, Lu, Zhang, Yuchen, Schoendorff, George, Gordon, Mark S., and Yang, Dong-Sheng

Subjects

*SPIN-orbit interactions, *ELECTRONS, *ELECTRON configuration, *ATOMS, *IONIZATION energy, *ELECTRON spin states, *RARE earth metals, *PRASEODYMIUM

Abstract

Although it plays a critical role in the photophysics and catalysis of lanthanides, spin–orbit coupling of electrons on individual lanthanide atoms in small clusters is not well understood. The major objective of this work is to probe such coupling of the praseodymium (Pr) 4f and 6s electrons in Pr2O2 and Pr2O2+. The approach combines mass-analyzed threshold ionization spectroscopy and spin–orbit multiconfiguration second-order quasi-degenerate perturbation theory. The energies of six ionization transitions are precisely measured; the adiabatic ionization energy of the neutral cluster is 38 045 (5) cm−1. Most of the electronic states involved in these transitions are identified as spin–orbit coupled states consisting of two or more electron spins. The electron configurations of these states are 4f46s2 for the neutral cluster and 4f46s for the singly charged cation, both in planar rhombus-type structures. The spin–orbit splitting due to the coupling of the electrons on the separate Pr atoms is on the order of hundreds of wavenumbers. [ABSTRACT FROM AUTHOR]

Published

2023

45. Adiabatic connection interaction strength interpolation method made accurate for the uniform electron gas.

Author

Constantin, Lucian A., Jana, Subrata, Śmiga, Szymon, and Della Sala, Fabio

Subjects

*ELECTRON gas, *INTERPOLATION, *SOLID state physics, *FUNCTIONALS, *ELECTRONS

Abstract

The adiabatic connection interaction strength interpolation (ISI)-like method provides a high-level expression for the correlation energy, being, in principle, exact not only in the weak-interaction limit, where it recovers the second-order Görling–Levy perturbation term, but also in the strong-interaction limit that is described by the strictly correlated electron approach. In this work, we construct a genISI functional made accurate for the uniform electron gas, a solid-state physics paradigm that is a very difficult test for ISI-like correlation functionals. We assess the genISI functional for various jellium spheres with the number of electrons Z ≤ 912 and for the non-relativistic noble atoms with Z ≤ 290. For the jellium clusters, the genISI is remarkably accurate, while for the noble atoms, it shows a good performance, similar to other ISI-like methods. Then, the genISI functional can open the path using the ISI-like method in solid-state calculations. [ABSTRACT FROM AUTHOR]

Published

2023

46. Orbital dependent complications for close vs well-separated electrons in diradicals.

Author

Hooshmand, Zahra, Bravo Flores, Jose Gustavo, and Pederson, Mark R.

Subjects

*BIRADICALS, *HARTREE-Fock approximation, *ELECTRON configuration, *ELECTRONS, *ENERGY function

Abstract

We investigate two limits in open-shell diradical systems: O3, in which the interesting orbitals are in close proximity to one another, and (C21H13)2, where there is a significant spatial separation between the two orbitals. In accord with earlier calculations, we find that standard density-functional approximations do not predict the open-shell character for the former case but uniformly predict the open-shell character for the latter case. We trace the qualitatively incorrect behavior in O3 predicted by these standard density functional approximations to self-interaction error and use the Fermi–Löwdin-orbital-self-interaction-corrected formalism to determine accurate triplet, closed-shell singlet, and open-shell broken-spin-symmetry electronic configurations. Analysis of the resulting many-electron overlap matrices allows us to unambiguously show that the broken-spin-symmetry configurations do not participate in the representation of the Ms = 0 triplet states and allows us to reliably extract the singlet–triplet splitting in O3 by analyzing the energy as a function of Fermi-orbital-descriptor permutations. The results of these analyses predict the percentage of open-shell character in O3, which agrees well with conventional wavefunction-based methods. While these techniques are expected to be required in cases near the Coulson–Fischer point, we find that they will be less necessary in diradical systems with well-separated electrons, such as (C21H13)2. Results based on energies from self-interaction-corrected generalized gradient, local density, and Hartree–Fock approximations and experimental results are in generally good agreement for O3. These results help form the basis for deriving extended Heisenberg-like Hamiltonians that are needed for descriptions of molecular magnets when there are competing low-energy electronic configurations. [ABSTRACT FROM AUTHOR]

Published

2023

47. Electron binding energies of SO2 at the surface of a water cluster.

Author

Martins, João B. L. and Cabral, Benedito J. C.

Subjects

*ELECTRON affinity, *AIR-water interfaces, *ELECTRONS, *WATER clusters, *BINDING energy, *MOLECULAR dynamics, *ATHLETIC fields

Abstract

The electronic properties of SO2 at the surface of a water cluster were investigated by employing a combination of Born–Oppenheimer molecular dynamics and electron propagator theory (EPT). In our work, we utilized a revised version of the Perdew–Burke–Ernzerhof (PBE) exchange-correlation functional, which incorporates empirical corrections for dispersion interactions in line with a recent study of the air–water interface conducted by Ohto et al. [J. Phys. Chem. Lett. 10(17), 4914–4919 (2019)]. Polarization effects induce a significant broadening of the electron binding energy distribution, as predicted by EPT. This broadening can result in a substantial increase in electron affinity, impacting the chemical reactivity of SO2 at the air–water interface, a topic of significant and recent research interest. We discuss the relationship between electron binding energies (EBEs) and the specific connections of SO2 to water. The results indicate that configurations involving an OS⋯H bond tend to yield higher electron affinities compared to complex formation through S⋯OW bonds. Surprisingly, SO2 molecules not bound to water molecules according to a specific criterion may also exhibit higher electron affinities. This feature can be explained by the role played by the polarization field from water molecules. Our best estimate for the HOMO–LUMO (H–L) gap of SO2 at the surface of a water cluster is 11.6 eV. Very similar H–L gaps are predicted for isolated and micro-solvated SO2. Fukui functions for the gas phase, and the micro-solvated SO2–H2O complex supports the view that the LUMO is predominantly localized on the SO2 moiety. [ABSTRACT FROM AUTHOR]

Published

2023

48. Large-Z atoms in the strong-interaction limit of DFT: Implications for gradient expansions and for the Lieb–Oxford bound.

Author

Daas, Kimberly J., Kooi, Derk P., Benyahia, Tarik, Seidl, Michael, and Gori-Giorgi, Paola

Subjects

*ATOMS, *ELECTRONS, *ELECTRON configuration

Abstract

We numerically study the strong-interaction limit of the exchange–correlation functional for neutral atoms and Bohr atoms as the number of electrons increases. Using a compact representation, we analyze the second-order gradient expansion, comparing it with the one for exchange (weak interaction limit). The two gradient expansions, at strong and weak interaction, turn out to be very similar in magnitude but with opposite signs. We find that the point-charge plus continuum model is surprisingly accurate for the gradient expansion coefficient at strong coupling, while generalized gradient approximations, such as Perdew–Burke–Ernzerhof (PBE) and PBEsol, severely underestimate it. We then use our results to analyze the Lieb–Oxford bound from the point of view of slowly varying densities, clarifying some aspects on the bound at a fixed number of electrons. [ABSTRACT FROM AUTHOR]

Published

2023

49. A novel coupled-cluster singles and doubles implementation that combines the exploitation of point-group symmetry and Cholesky decomposition of the two-electron integrals.

Author

Nottoli, Tommaso, Gauss, Jürgen, and Lipparini, Filippo

Subjects

*SYMMETRY, *INTEGRALS, *BUCKMINSTERFULLERENE, *ELECTRONS, *ALGORITHMS

Abstract

A novel implementation of the coupled-cluster singles and doubles (CCSD) approach is presented that is specifically tailored for the treatment of large symmetric systems. It fully exploits Abelian point-group symmetry and the use of the Cholesky decomposition of the two-electron repulsion integrals. In accordance with modern CCSD algorithms, we propose two alternative strategies for the computation of the so-called particle–particle ladder term. The code is driven toward the optimal choice depending on the available hardware resources. As a large-scale application, we computed the frozen-core correlation energy of buckminsterfullerene (C60) with a polarized valence triple-zeta basis set (240 correlated electrons in 1740 orbitals). [ABSTRACT FROM AUTHOR]

Published

2023

50. High-temperature efficient luminescence of dilute-nitride InGaAsN quantum dots with deep electron potential.

Author

Morita, Ayano, Hiura, Satoshi, Takayama, Junichi, and Murayama, Akihiro

Subjects

*ELECTRONIC excitation, *LUMINESCENCE, *QUANTUM dots, *CONDUCTION bands, *EXCITED states, *ELECTRONS

Abstract

The temperature dependence of the optical properties of In0.4Ga0.6As0.98N0.02 quantum dots (QDs) was investigated using continuous-wave and time-resolved photoluminescence (PL). Significant increases in the PL peak energy and the PL linewidth were observed at temperatures above 200 K, which reflected the high luminescence efficiency of ground and excited states at high temperatures. The PL decay times of the ground state were almost constant between 200 and 300 K at 200–220 ps, which were significantly longer than that of 38 ps for the In0.4Ga0.6As QDs at 300 K. The temperature independence of the PL decay time represents significant suppression of the thermal escape and the thermal excitation of electrons because the electron ground-state localization energy is much larger than the thermal energy. The PL intensity of the In0.4Ga0.6As0.98N0.02 QDs was seven times stronger than that of the In0.4Ga0.6As QDs at 300 K, and this tendency was maintained up to 400 K with a PL intensity one order of magnitude stronger. These findings demonstrate that lowering the QD conduction band by nitrogen incorporation is an effective approach for achieving strong QD luminescence above room temperature. [ABSTRACT FROM AUTHOR]

Published

2023