Your search keyword '"Grüneis, A."' showing total 2,203 results

1. Coupled-cluster theory for the ground state and for excitations

Author

Grüneis, Andreas, Moerman, Evgeny, Scheffler, Matthias, Shen, Tonghao, and Zhang, Igor Ying

Subjects

Physics - Chemical Physics, Condensed Matter - Materials Science

Abstract

In the molecular quantum chemistry community, coupled-cluster (CC) methods are well-recognized for their systematic convergence and reliability. The extension of the theory to extended systems has been comparably recent, so that developments and studies of periodic CC methods for both the ground-state and for excited states are still active fields of research and provide valuable benchmark data when the reliability of density functional approximations is questionable. In this contribution we describe the CC-aims interface between the FHI-aims and the Cc4s software packages. This linkage makes a variety of correlated wave function-based ground-state methods including M\o ller-Plesset perturbation theory (MP2), the random-phase approximation (RPA) and the gold-standard of quantum chemistry CCSD(T) method for both molecular and periodic applications accessible. This contribution discusses these ground-state methods for clusters and molecules, as well as for periodic systems. In particular, we discuss recent advancements and the implementation of the equation-of-motion CC method for the calculation of ionization (IP-EOM-CCSD) and electron attachment (EA-EOM-CCSD) processes. Open questions and routes to solutions are discussed as well., Comment: 7 pages, 5 figures. This is a contribution/chapter to the upcoming "Roadmap on Advancements of the FHI-aims Software Package"

Published

2024

2. Combined Raman spectroscopy and electrical transport measurements in ultra-high vacuum down to 3.7 K

Author

Shchukin, Konstantin P., Hell, Martin, and Grüneis, Alexander

Subjects

Physics - Instrumentation and Detectors

Abstract

An instrument for the simultaneous characterization of thin films by Raman spectroscopy and electronic transport down to 3.7 K has been designed and built. This setup allows for the in-situ preparation of air-sensitive samples, their spectroscopic characterization by Raman spectroscopy with different laser lines and five-probe electronic transport measurements using sample plates with prefabricated contacts. The lowest temperatures that can be achieved on the sample are directly proven by measuring the superconducting transition of a Niobium film. The temperature-dependent Raman shift and narrowing of the Silicon F_{2g} Raman line are shown. This experimental system is specially designed for in-situ functionalization, optical spectroscopic and electron transport investigation of thin films. It allows for easy on-the-fly change of samples without the need to warm up the cryomanipulator.

Published

2024

3. Finite-size Effects in periodic EOM-CCSD for Ionization Energies and Electron Affinities: Convergence Rate and Extrapolation to the Thermodynamic Limit

Author

Moerman, Evgeny, Gallo, Alejandro, Irmler, Andreas, Schäfer, Tobias, Hummel, Felix, Grüneis, Andreas, and Scheffler, Matthias

Subjects

Condensed Matter - Materials Science

Abstract

We investigate the convergence of quasi-particle energies for periodic systems to the thermodynamic limit using increasingly large simulation cells corresponding to increasingly dense integration meshes in reciprocal space. The quasi-particle energies are computed at the level of equation-of-motion coupled-cluster theory for ionization (IP-EOM-CC) and electron attachment processes (EA-EOM-CC). By introducing an electronic correlation structure factor, the expected asymptotic convergence rates for systems with different dimensionality are formally derived. We rigorously test these derivations through numerical simulations for trans-Polyacetylene using IP/EA-EOM-CCSD and the G0W0@HF approximation, which confirm the predicted convergence behavior. Our findings provide a solid foundation for efficient schemes to correct finite-size errors in IP/EA-EOM-CCSD calculations., Comment: 16 pages, 9 figures

Published

2024

4. Engineering two-dimensional materials from single-layer NbS$_2$

Author

Knispel, Timo, Mohrenstecher, Daniela, Speckmann, Carsten, Safeer, Affan, van Efferen, Camiel, Boix, Virgínia, Grüneis, Alexander, Jolie, Wouter, Preobrajenski, Alexei, Knudsen, Jan, Atodiresei, Nicolae, Michely, Thomas, and Fischer, Jeison

Subjects

Condensed Matter - Materials Science, Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

Starting from a single layer of NbS$_2$ grown on graphene by molecular beam epitaxy, the single unit cell thick 2D materials Nb$_{5/3}$S$_3$-2D and Nb$_2$S$_3$-2D are created using two different pathways. Either annealing under sulfur-deficient conditions at progressively higher temperatures or deposition of increasing amounts of Nb at elevated temperature result in phase-pure Nb$_{5/3}$S$_3$-2D followed by Nb$_2$S$_3$-2D. The materials are characterized by scanning tunneling microscopy, scanning tunneling spectroscopy and X-ray photoemission spectroscopy. The experimental assessment combined with systematic density functional theory calculations reveals their structure. The 2D materials are covalently bound without any van der Waals gap. Their stacking sequence and structure are at variance with expectations based on corresponding bulk materials highlighting the importance of surface and interface effects in structure formation.

Published

2024

5. Understanding Discrepancies of Wavefunction Theories for Large Molecules

Author

Schäfer, Tobias, Irmler, Andreas, Gallo, Alejandro, and Grüneis, Andreas

Subjects

Physics - Chemical Physics

Abstract

Quantum mechanical many-electron calculations can predict properties of atoms, molecules and even complex materials. The employed computational methods play a quintessential role in many scientifically and technologically relevant research fields. However, a question of paramount importance is whether approximations aimed at reducing the computational complexity for solving the many-electron Schr\"odinger equation, are accurate enough. Here, we investigate recently reported discrepancies of noncovalent interaction energies for large molecules predicted by two of the most widely-trusted many-electron theories: diffusion quantum Monte Carlo and coupled-cluster theory. We are able to unequivocally pin down the source of the puzzling discrepancies and present modifications to widely-used coupled-cluster methods needed for more accurate noncovalent interaction energies of large molecules on the hundred-atom scale. This enhances the reliability of predictions from quantum mechanical many-electron theories across a wide range of critical applications, including drug design, catalysis, and the innovation of new functional materials, such as those for renewable energy technologies., Comment: 14 pages, 3 figures, 2 tables

Published

2024

6. Molecular order induced charge transfer in a C$_{60}$-topological insulator moir\'e heterostructure

Author

Pandeya, Ram Prakash, Shchukin, Konstantin P., Falke, Yannic, Mussler, Gregor, Rehman, Jalil Abdur, Atodiresei, Nicolae, Fedorov, Alexander V., Senkovskiy, Boris V., Jansen, Daniel, Di Santo, Giovanni, Petaccia, Luca, and Grüneis, Alexander

Subjects

Condensed Matter - Materials Science

Abstract

We synthesize and spectroscopically investigate monolayer C$_{60}$ on the topological insulator (TI) Bi$_4$Te$_3$. This C$_{60}$/Bi$_4$Te$_3$ heterostructure is characterized by excellent translational order in a novel (4 x 4) C$_{60}$ superstructure on a (9 x 9) unit of Bi$_4$Te$_3$. We measure the full two-dimensional energy band structure of C$_{60}$/Bi$_4$Te$_3$ using angle-resolved photoemission spectroscopy (ARPES). We find that C$_{60}$ accepts electrons from the TI at room temperature but no charge transfer occurs at low temperatures. We unravel this peculiar behaviour by Raman spectroscopy of C$_{60}$/Bi$_4$Te$_3$ and density functional theory (DFT) calculations of the electronegativity of C$_{60}$. Both methods are sensitive to orientational order of C$_{60}$. At low temperatures, Raman spectroscopy shows a dramatic intensity increase of the C$_{60}$ Raman signal, evidencing a transition to a rotationally ordered state. DFT reveals that the orientational order of C$_{60}$ at low temperatures has a higher electron affinity than at high temperatures. These results neatly explain the temperature-dependent charge transfer observed in ARPES. Our conclusions are supported by the appearance of a strong photoluminescence from C$_{60}$/Bi$_4$Te$_3$ at low temperatures.

Published

2024

7. Investigating the basis set convergence of diagrammatically decomposed coupled-cluster correlation energy contributions for the uniform electron gas

Author

Masios, Nikolaos, Hummel, Felix, Grüneis, Andreas, and Irmler, Andreas

Subjects

Condensed Matter - Materials Science

Abstract

We investigate the convergence of coupled-cluster correlation energies and related quantities with respect to the employed basis set size for the uniform electron gas to gain a better understanding of the basis set incompleteness error. To this end, coupled-cluster doubles (CCD) theory is applied to the three dimensional uniform electron gas for a range of densities, basis set sizes and electron numbers. We present a detailed analysis of individual, diagrammatically decomposed contributions to the amplitudes at the level of CCD theory. In particular, we show that only two terms from the amplitude equations contribute to the asymptotic large-momentum behavior of the transition structure factor, corresponding to the cusp region at short interelectronic distances. However, due to the coupling present in the amplitude equations, all decomposed correlation energy contributions show the same asymptotic convergence behavior to the complete basis set limit. These findings provide an additional rationale for the success of a recently proposed correction to the basis set incompleteness error (BSIE) of coupled-cluster theory. Lastly, we examine the BSIE in the coupled-cluster doubles plus perturbative triples [CCD(T)] method, as well as in the newly proposed coupled-cluster doubles plus complete perturbative triples [CCD(cT)] method., Comment: 16 pages, 7 figures, 1 table

Published

2024

8. Mass inversion at the Lifshitz transition in monolayer graphene by diffusive, high-density, on-chip, doping

Author

Aygar, Ayse Melis, Durnan, Oliver, Molavi, Bahar, Bovey, Sam N. R., Grüneis, Alexander, and Szkopek, Thomas

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

Experimental setups for charge transport measurements are typically not compatible with the ultra-high vacuum conditions for chemical doping, limiting the charge carrier density that can be investigated by transport methods. Field-effect methods, including dielectric gating and ionic liquid gating, achieve too low a carrier density to induce electronic phase transitions. To bridge this gap, we developed an integrated flip-chip method to dope graphene by alkali vapour in the diffusive regime, suitable for charge transport measurements at ultra-high charge carrier density. We introduce a cesium droplet into a sealed cavity filled with inert gas to dope a monolayer graphene sample by the process of cesium atom diffusion, adsorption and ionization at the graphene surface, with doping beyond an electron density of $4.7\times10^{14}~\mathrm{cm}^{-2}$ monitored by operando Hall measurement. The sealed assembly is stable against oxidation, enabling measurement of charge transport versus temperature and magnetic field. Cyclotron mass inversion is observed via the Hall effect, indicative of the change of Fermi surface geometry associated with the Liftshitz transition at the hyperbolic $M$ point of monolayer graphene. The transparent quartz substrate also functions as an optical window, enabling non-resonant Raman scattering. Our findings show that chemical doping, hitherto restricted to ultra-high vacuum, can be applied in a diffusive regime at ambient pressure in an inert gas environment and thus enable charge transport studies in standard cryogenic environments

Published

2024

9. Sampling the reciprocal Coulomb potential in finite and anisotropic cells

Author

Schäfer, Tobias, Van Benschoten, William Z., Shepherd, James J., and Grüneis, Andreas

Subjects

Physics - Computational Physics, Physics - Chemical Physics

Abstract

We present a robust strategy to numerically sample the Coulomb potential in reciprocal space for periodic Born-von Karman cells of general shape. Our approach tackles two common issues of plane-wave based implementations of Coulomb integrals under periodic boundary conditions, the treatment of the singularity at the Brillouin-zone center, as well as quadrature errors, which can cause severe convergence problems in anisotropic cells, necessary for the calculation of low-dimensional systems. We apply our strategy to the Hartree-Fock (HF) and coupled cluster (CC) theory and discuss the consequences of different sampling strategies on the different theories. We show that sampling the Coulomb potential via the widely used probe-charge Ewald method is unsuitable for CC calculations in anisotropic cells. To demonstrate the applicability of our developed approach, we study two representative, low-dimensional use cases: the infinite carbon chain, for which we report the first periodic CCSD(T) potential energy surface, as well as a surface slab of lithium hydride, for which we demonstrate the impact of different sampling strategies for calculating surface energies. We find that our Coulomb sampling strategy serves as a vital solution, addressing the critical need for improved accuracy in plane-wave based CC calculations for low-dimensional systems., Comment: 7 pages, 3 figures

Published

2023

10. Optimizing Distributed Tensor Contractions using Node-Aware Processor Grids

Author

Irmler, Andreas, Kanakagiri, Raghavendra, Ohlmann, Sebastian T., Solomonik, Edgar, and Grüneis, Andreas

Subjects

Computer Science - Distributed, Parallel, and Cluster Computing, Condensed Matter - Materials Science

Abstract

We propose an algorithm that aims at minimizing the inter-node communication volume for distributed and memory-efficient tensor contraction schemes on modern multi-core compute nodes. The key idea is to define processor grids that optimize intra-/inter-node communication volume in the employed contraction algorithms. We present an implementation of the proposed node-aware communication algorithm into the Cyclops Tensor Framework (CTF). We demonstrate that this implementation achieves a significantly improved performance for matrix-matrix-multiplication and tensor-contractions on up to several hundreds modern compute nodes compared to conventional implementations without using node-aware processor grids. Our implementation shows good performance when compared with existing state-of-the-art parallel matrix multiplication libraries (COSMA and ScaLAPACK). In addition to the discussion of the performance for matrix-matrix-multiplication, we also investigate the performance of our node-aware communication algorithm for tensor contractions as they occur in quantum chemical coupled-cluster methods. To this end we employ a modified version of CTF in combination with a coupled-cluster code (Cc4s). Our findings show that the node-aware communication algorithm is also able to improve the performance of coupled-cluster theory calculations for real-world problems running on tens to hundreds of compute nodes., Comment: 15 pages, 4 figures

Published

2023

11. Formation energies of silicon self-interstitials using periodic coupled cluster theory

Author

Salihbegović, Faruk, Gallo, Alejandro, and Grüneis, Andreas

Subjects

Condensed Matter - Materials Science

Abstract

We present a study of the self-interstitial point defect formation energies in silicon using a range of quantum chemical theories including the coupled cluster (CC) method within a periodic supercell approach. We study the formation energies of the X, T, H and C3V self-interstitials and the vacancy V. Our results are compared to findings obtained using different ab initio methods published in the literature and partly to experimental data. In order to achieve computational results that are converged with respect to system size and basis set, we employ the recently proposed finite size error corrections and basis set incompleteness error corrections. Our CCSD(T) calculations yield an order of stability of the X, H and T self-interstitials, which agrees both with quantum Monte Carlo results and with predictions obtained using the random-phase approximation as well as using screened hybrid functionals. Compared to quantum Monte Carlo results with backflow corrections, the CCSD(T) formation energies of X and H are only slightly larger by about 100 meV. However, in the case of the T self-interstitial, we find significant disagreement with all other theoretical predictions. Compared to quantum Monte Carlo calculations, CCSD(T) overestimates the formation energy of the T self-interstitial by 1.2 eV. Although this can partly be attributed to strong correlation effects, more accurate electronic structure theories are needed to understand these findings.

Published

2023

12. Phaseless auxiliary field quantum Monte Carlo with projector-augmented wave method for solids

Author

Taheridehkordi, Amir, Schlipf, Martin, Sukurma, Zoran, Humer, Moritz, Grüneis, Andreas, and Kresse, Georg

Subjects

Physics - Chemical Physics, Physics - Computational Physics

Abstract

We implement the phaseless auxiliary field quantum Monte Carlo method using the plane-wave based projector augmented wave method and explore the accuracy and the feasibility of applying our implementation to solids. We use a singular value decomposition to compress the two-body Hamiltonian and thus reduce the computational cost. Consistent correlation energies from the primitive-cell sampling and the corresponding supercell calculations numerically verify our implementation. We calculate the equation of state for diamond and the correlation energies for a range of prototypical solid materials. A down-sampling technique along with natural orbitals accelerates the convergence with respect to the number of orbitals and crystal momentum points. We illustrate the competitiveness of our implementation in accuracy and computational cost for dense crystal momentum point meshes comparing to a well-established quantum-chemistry approach, the coupled-cluster ansatz including singles, doubles and perturbative triple particle-hole excitation operators., Comment: 13 pages, 7 figures

Published

2023

13. Averting the infrared catastrophe in the gold standard of quantum chemistry

Author

Masios, Nikolaos, Irmler, Andreas, Schäfer, Tobias, and Grüneis, Andreas

Subjects

Condensed Matter - Materials Science

Abstract

Coupled-cluster theories can be used to compute ab initio electronic correlation energies of real materials with systematically improvable accuracy. However, the widely-used coupled cluster singles and doubles plus perturbative triples (CCSD(T)) method is only applicable to insulating materials. For zero-gap materials the truncation of the underlying many-body perturbation expansion leads to an infrared catastrophe. Here, we present a novel perturbative triples formalism that yields convergent correlation energies in metallic systems. Furthermore, the computed correlation energies for the three dimensional uniform electron gas at metallic densities are in good agreement with quantum Monte Carlo results. At the same time the newly proposed method retains all desirable properties of CCSD(T) such as its accuracy for insulating systems as well as its low computational cost compared to a full inclusion of the triples. This paves the way for ab initio calculations of real metals with chemical accuracy., Comment: 6 pages, 1 figure, 1 table plus a supplemental material of 14 pages, 4 figures and 1 table

Published

2023

14. Kapitel 4. Anpassungsoptionen in der Landnutzung an den Klimawandel

Author

Baumgarten, Andreas, Freudenschuss, Alexandra, Grüneis, Heidi, Konrad, Heino, Lapin, Katharina, Lexer, Manfred J., Miloczki, Julia, Sandén, Taru, Schauberger, Günther, Mag. Dr. MSc. Schaumberger, Andreas, Schüler, Silvio, Stumpp, Christine, Zoboli, Ottavia, Jandl, Robert, editor, Tappeiner, Ulrike, editor, Foldal, Cecilie Birgitte, editor, and Erb, Karlheinz, editor

Published

2024

15. Coupled cluster finite temperature simulations of periodic materials via machine learning

Author

Basile Herzog, Alejandro Gallo, Felix Hummel, Michael Badawi, Tomáš Bučko, Sébastien Lebègue, Andreas Grüneis, and Dario Rocca

Subjects

Materials of engineering and construction. Mechanics of materials, TA401-492, Computer software, QA76.75-76.765

Abstract

Abstract Density functional theory is the workhorse of materials simulations. Unfortunately, the quality of results often varies depending on the specific choice of the exchange-correlation functional, which significantly limits the predictive power of this approach. Coupled cluster theory, including single, double, and perturbative triple particle-hole excitation operators, is widely considered the ‘gold standard' of quantum chemistry as it can achieve chemical accuracy for non-strongly correlated applications. Because of the high computational cost, the application of coupled cluster theory in materials simulations is rare, and this is particularly true if finite-temperature properties are of interest for which molecular dynamics simulations have to be performed. By combining recent progress in machine learning models with low data requirements for energy surfaces and in the implementation of coupled cluster theory for periodic materials, we show that chemically accurate simulations of materials are practical and could soon become significantly widespread. As an example of this numerical approach, we consider the calculation of the enthalpy of adsorption of CO2 in a porous material.

Published

2024

16. Interface to high-performance periodic coupled-cluster theory calculations with atom-centered, localized basis functions

Author

Moerman, Evgeny, Hummel, Felix, Grüneis, Andreas, Irmler, Andreas, and Scheffler, Matthias

Subjects

Condensed Matter - Materials Science

Abstract

Coupled cluster (CC) theory is often considered the gold standard of quantum-chemistry. For solids, however, the available software is scarce. We present CC-aims, which can interface ab initio codes with localized atomic orbitals and the CC for solids (CC4S) code by the group of A. Gr\"uneis. CC4S features a continuously growing selection of wave function-based methods including perturbation and CC theory. The CC-aims interface was developed for the FHI-aims code (https://fhi-aims.org) but is implemented such that other codes may use it as a starting point for corresponding interfaces. As CC4S offers treatment of both molecular and periodic systems, the CC-aims interface is a valuable tool, where DFT is either too inaccurate or too unreliable, in theoretical chemistry and materials science alike., Comment: Currently reviewed for publication in the JOSS journal (review process: https://github.com/openjournals/joss-reviews/issues/4040 ). The conciseness of the paper is due to the required word count of less than 1000 words by the journal (see https://joss.readthedocs.io/en/latest/submitting.html#what-should-my-paper-contain ). This manuscript is complete and introduces a new piece of software

Published

2022

17. 1/f Noise Under Drift And Thermal Agitation In Semiconductor Materials

Author

Grueneis, Ferdinand

Subjects

Condensed Matter - Statistical Mechanics

Abstract

Voss and Clarke observed 1/f noise in the square of Johnson noise across samples in thermal equilibrium without applying a current. We refer to this phenomenon as thermal 1/f noise. Voss and Clarke suggested spatially correlated temperature fluctuations as an origin of thermal 1/f noise; they also showed that thermal 1/f noise closely matches the 1/f spectrum obtained by passing a current through the sample. An intermittent generation-recombination (g-r) process has recently been introduced to interpret 1/f noise in semiconductors. The square of this intermittent g-r process generates a 1/f noise component which correlates with Voss and Clarke's empirical findings. Traps which intermittently rather than continuously generate g-r pulses are suggested as the origin of 1/f noise under drift and thermal agitation. We see no need to introduce correlated temperature fluctuations or oxide traps with a large distribution of time constants to explain 1/f noise., Comment: 9 pages, 6 figures

Published

2022

18. Conflicting and complementary policy goals as sectoral integration challenge: an analysis of sectoral interplay in flood risk management

Author

Nordbeck, Ralf, Seher, Walter, Grüneis, Heidelinde, Herrnegger, Mathew, and Junger, Lena

Published

2023

19. Coupled cluster theory for the ground and excited states of two dimensional quantum dots

Author

Salihbegović, Faruk, Gallo, Alejandro, and Grüneis, Andreas

Subjects

Physics - Chemical Physics

Abstract

We present a study of the two dimensional circular quantum dot model Hamiltonian using a range of quantum chemical ab initio methods. Ground and excited state energies are computed on different levels of perturbation theories including the coupled cluster method. We outline a scheme to compute the required Coulomb integrals in real space and utilize a semi-analytic solution to the integral over the Coulomb kernel in the vicinity of the singularity. Furthermore, we show that the remaining basis set incompleteness error for two dimensional quantum dots scales with the inverse number of virtual orbitals, allowing us to extrapolate to the complete basis set limit energy. By varying the harmonic potential parameter we tune the correlation strength and investigate the predicted ground and excited state energies.

Published

2021

20. Real-space visualization of quasiparticle dephasing near the Planckian limit in the Dirac line node material ZrSiS

Author

He, Qingyu, Zhou, Lihui, Rost, Andreas W., Huang, Dennis, Grüneis, Andreas, Schoop, Leslie M., and Takagi, Hidenori

Subjects

Condensed Matter - Strongly Correlated Electrons, Condensed Matter - Materials Science

Abstract

Dirac line node (DLN) materials are topological semimetals wherein a set of symmetry protected crossing points forms a one-dimensional (1D) line in reciprocal space. Not only are the linearly dispersing bands expected to give rise to exceptional electronic properties, but the weak screening of the Coulomb interaction near the line node may enhance electronic correlations, produce new many-body ground states, or influence the quasiparticle lifetime. We investigate the quasiparticle dynamics in the DLN material ZrSiS via spectroscopic imaging scanning tunneling microscopy (SI-STM). By studying the spatial decay of quasiparticle interference patterns (QPI) from point scatterers, we were able to directly and selectively extract the phase coherence length $l_{\textrm{QPI}}$ and lifetime $\tau_{\textrm{QPI}}$ for the bulk DLN excitations, which are dominated by inelastic electron-electron scattering. We find that the experimental $\tau_{\textrm{QPI}}(E)$ values below $-$40 meV are very short, likely due to the stronger Coulomb interactions, and lie at the Planckian limit $\hbar/|E|$. Our results corroborate a growing body of experimental reports demonstrating unusual electronic correlation effects near a DLN.

Published

2021

21. Surface science using coupled cluster theory via local Wannier functions and in-RPA-embedding: the case of water on graphitic carbon nitride

Author

Schäfer, Tobias, Gallo, Alejandro, Irmler, Andreas, Hummel, Felix, and Grüneis, Andreas

Subjects

Physics - Chemical Physics, Condensed Matter - Materials Science, Physics - Computational Physics

Abstract

A first-principles study of the adsorption of a single water molecule on a layer of graphitic carbon nitride employing an embedding approach is presented. The embedding approach involves an algorithm to obtain localized Wannier orbitals of various types expanded in a plane-wave basis and intrinsic atomic orbital projectors. The localized occupied orbitals are employed in combination with unoccupied natural orbitals to perform many-electron perturbation theory calculations of local fragments. The fragments are comprised of a set of localized orbitals close to the adsorbed water molecule. Although the surface model contains more than 100 atoms in the simulation cell, the employed fragments are small enough to allow for calculations using high-level theories up to the coupled cluster ansatz with single, double and perturbative triple particle-hole excitation operators (CCSD(T)). To correct for the missing long-range correlation energy contributions to the adsorption energy, we embed CCSD(T) theory into the direct random phase approximation, yielding rapidly convergent adsorption energies with respect to the fragment size. Convergence of computed binding energies with respect to the virtual orbital basis set is achieved employing a number of recently developed techniques. Moreover, we discuss fragment size convergence for a range of approximate many-electron perturbation theories. The obtained benchmark results are compared to a number of density functional calculations., Comment: 12 pages, 7 figures

Published

2021

22. CO adsorption on Pt(111) studied by periodic coupled cluster theory.

Author

Carbone, Johanna P., Irmler, Andreas, Gallo, Alejandro, Schäfer, Tobias, Van Benschoten, William Z., Shepherd, James J., and Grüneis, Andreas

Abstract

We present an application of periodic coupled-cluster theory to the calculation of CO adsorption energies on the Pt(111) surface for different adsorption sites. The calculations employ a range of recently developed theoretical and computational methods. In particular, we use a recently introduced coupled-cluster ansatz, denoted as CCSD(cT), to compute correlation energies of the metallic Pt surface with and without adsorbed CO molecules. The convergence of Hartree–Fock adsorption energy contributions with respect to randomly shifted k-meshes is discussed. Recently introduced basis set incompleteness error corrections make it possible to achieve well-converged correlation energy contributions to the adsorption energies. We show that CCSD(cT) theory predicts the correct order of adsorption energies for the considered adsorption sites. Furthermore, we find that binding of the CO molecule to the top and fcc site is dominated by Hartree–Fock and correlation energy contributions, respectively. [ABSTRACT FROM AUTHOR]

Published

2024

23. Estimation of the lowest limit of 1/f noise in semiconductor materials

Author

Grueneis, Ferdinand

Subjects

Physics - General Physics

Abstract

A lowest limit of 1/f noise in semiconductor materials has not yet been reported; we do not even know if such a lowest limit exists. 1/f noise in semiconductors has recently been brought into relation with 1/f noise in quantum dots and other materials. These materials exhibit on-off states which are power-law distributed over a wide range of timescales. We transfer such findings to semiconductors, assuming that the g-r process is also controlled by such on-off states. As a result, we obtain 1/f noise which can be expressed in the form of the Hooge relation. Based on the intermittent g-r process, we estimate the lowest limit of 1/f noise in semiconductor materials. We show that this limit is inversely proportional to the dopant concentration; to detect the lowest limit of 1/f noise, the number of centers should be as small as possible. We also find a smooth dependence of 1/f noise and g-r noise on time., Comment: 10 pages, 9 figures. arXiv admin note: substantial text overlap with arXiv:2108.07155

Published

2021

24. An alternative form of Hooge's relation for 1/f noise in semiconductor materials

Author

Grueneis, Ferdinand

Subjects

Physics - General Physics

Abstract

Single quantum dots and other materials exhibit irregular switching between on and off states; these on-off states follow power-law statistics giving rise to 1/f noise. We transfer this phenomenon (also referred to as on-off intermittency) to the generation and recombination (g-r) process in semiconductor materials. In addition to g-r noise we obtain 1/f noise that can be provided in the form of the Hooge relation. The predicted Hooge coefficient depends on the parameters of the g-r noise and on the parameters of the intermittency. Due to the power-law distribution of the on-times, the coefficient for intermittency shows a smooth dependence on time t. We also suggest an alternative form of the 1/f noise formula by Hooge relating the 1/f noise to the number of centers (such as donor or trap atoms) rather than to the number of charge carriers as defined by Hooge., Comment: 17 pages, 9 figures

Published

2021

25. Unraveling the Excitonic Transition and Associated Dynamics in Confined Long Linear Carbon-chains with Time-Resolved Resonance Raman Scattering

Author

Zhu, Jingyi, Bernhardt, Robin, Cui, Weili, German, Raphael, Wagner, Julian, Senkovskiy, Boris V., Grüneis, Alexander, Pichler, Thomas, Liu, Rulin, Zhu, Xi, Van Loosdrecht, Paul H. M., and Shi, Lei

Subjects

Condensed Matter - Materials Science

Abstract

Long linear carbon-chains have been attracting intense interest arising from the remarkable properties predicted and their potential applications in future nanotechnology. Here we comprehensively interrogate the excitonic transitions and the associated relaxation dynamics of nanotube confined long linear carbon-chains by using steady state and time-resolved Raman spectroscopies. The exciton relaxation dynamics on the confined carbon-chains occurs on a hundreds of picoseconds timescale, in strong contrast to the host dynamics that occurs on a few picosecond timescale. A prominent time-resolved Raman response is observed over a broad energy range extending from 1.2 to 2.8 eV, which includes the strong Raman resonance region around 2.2 eV. Evidence for a strong coupling between the chain and the nanotube host is found from the dynamics at high excitation energies which provides a clear evidence for an efficient energy transfer from the host carbon nanotube to the chain. Our experimental study presents the first unique characterization of the long linear carbon-chain exciton dynamics, providing indispensable knowledge for the understanding of the interactions between different carbon allotropes., Comment: 21 pages

Published

2021

26. The Transition from Generation-Recombination Noise in Bulk Semiconductors to Discrete Switching in Small-Area Semiconductors

Author

Grueneis, F.

Subjects

Physics - General Physics

Abstract

The master-equation approach provides generation-recombination (g-r) noise in bulk semiconductors in terms of parameters of conduction electrons. It is shown that the g-r bulk noise can also be described by the random succession of elementary g-r pulses. This enables g-r bulk noise to be interpreted in terms of the numbers of traps. The transition from g-r bulk noise to discrete switching in small-area semiconductors is found by reducing the number of traps to just one single active trap. The resulting g-r noise spectrum is shown to be equivalent to Machlups noise spectrum. The probability of an overlap of succeeding g-r pulses is calculated. Such an overlap is attributed to the occupation of an empty single trap by an electron transferred from a neighboring trap. Simulating a g-r pulse train we find a large variety of patterns similar to those observed in MOSFETs. Excluding overlapping g-r pulses, the up and down distribution of succeeding g-r pulses is estimated., Comment: 13 pages, 9 figures and addendum

Published

2021

27. Focal-point approach with pair-specific cusp correction for coupled-cluster theory

Author

Irmler, Andreas, Gallo, Alejandro, and Grüneis, Andreas

Subjects

Condensed Matter - Materials Science, Physics - Chemical Physics, Physics - Computational Physics

Abstract

We present a basis set correction scheme for the coupled-cluster singles and doubles (CCSD) method. The scheme is based on employing frozen natural orbitals (FNOs) and diagrammatically decomposed contributions to the electronic correlation energy that dominate the basis set incompleteness error (BSIE). As recently discussed in [https://doi.org/10.1103/PhysRevLett.123.156401], the BSIE of the CCSD correlation energy is dominated by the second-order M{\o}ller-Plesset (MP2) perturbation energy and the particle-particle ladder term. Here, we derive a simple approximation to the BSIE of the particle-particle ladder term that effectively corresponds to a rescaled pair-specific MP2 BSIE, where the scaling factor depends on the spatially averaged correlation hole depth of the coupled-cluster and first-order pair wavefunctions. The evaluation of the derived expressions is simple to implement in any existing code. We demonstrate the effectiveness of the method for the uniform electron gas. Furthermore, we apply the method to coupled-cluster theory calculations of atoms and molecules using FNOs. Employing the proposed correction and an increasing number of FNOs per occupied orbital, we demonstrate for a test set that rapidly convergent closed and open-shell reaction energies, atomization energies, electron affinities, and ionization potentials can be obtained. Moreover, we show that a similarly excellent trade-off between required virtual orbital basis set size and remaining BSIEs can be achieved for the perturbative triples contribution to the CCSD(T) energy employing FNOs and the (T*) approximation.

Published

2021

28. Effective Hamiltonians for the study of real metals using quantum chemical theories

Author

Mihm, Tina N., Schäfer, Tobias, Ramadugu, Sai Kumar, Grüneis, Andreas, and Shepherd, James J.

Subjects

Condensed Matter - Materials Science, Physics - Computational Physics

Abstract

Computationally efficient and accurate quantum mechanical approximations to solve the many-electron Schr\"odinger equation are at the heart of computational materials science. In that respect the coupled cluster hierarchy of methods plays a central role in molecular quantum chemistry because of its systematic improvability and computational efficiency. In this hierarchy, coupled cluster singles and doubles (CCSD) is one of the most important steps in moving towards chemical accuracy and, in recent years, its scope has successfully been expanded to the study of insulating surfaces and solids. Here, we show that CCSD theory can also be applied to real metals. In so doing, we overcome the limitation of needing extremely large supercells to capture long range electronic correlation effects. An effective Hamiltonian can be found using the transition structure factor--a map of electronic excitations from the Hartree--Fock wavefunction--which has fewer finite size effects than conventional periodic boundary conditions. This not only paves the way of applying coupled cluster methods to real metals but also reduces the computational cost by two orders of magnitude compared to previous methods. Our applications to phases of lithium and silicon show a resounding success in reaching the thermodynamic limit, taking the first step towards a truly universal quantum chemical treatment of solids., Comment: 8 pages, 4 figures, 1 table

Published

2021

29. Local embedding of Coupled Cluster theory into the Random Phase Approximation using plane-waves

Author

Schäfer, Tobias, Libisch, Florian, Kresse, Georg, and Grüneis, Andreas

Subjects

Physics - Chemical Physics, Condensed Matter - Materials Science

Abstract

We present an embedding approach to treat local electron correlation effects in periodic environments. In a single, consistent framework, our plane-wave based scheme embeds a local high-level correlation calculation (here Coupled Cluster Theory, CC), employing localized orbitals, into a low-level correlation calculation (here the direct Random Phase Approximation, RPA). This choice allows for an accurate and effcient treatment of long-range dispersion effects. Accelerated convergence with respect to the local fragment size can be observed if the low-level and high-level long-range dispersion are quantitatively similar, as is the case for CC in RPA. To demonstrate the capabilities of the introduced embedding approach, we calculate adsorption energies of molecules on a surface and in a chabazite crystal cage, as well as the formation energy of a lattice impurity in a solid at the level of highly accurate many-electron perturbation theories. The absorption energy of a methane molecule in a zeolite chabazite, for instance, is converged with an error well below 20 meV at the CC level. As our largest periodic benchmark system, we apply our scheme to the adsorption of a water molecule on titania in a supercell containing more than 1000 electrons., Comment: 6 pages, 2 figures

Published

2020

30. Optimizing Distributed Tensor Contractions Using Node-Aware Processor Grids.

Author

Andreas Irmler, Raghavendra Kanakagiri, Sebastian T. Ohlmann, Edgar Solomonik, and Andreas Grüneis

Published

2023

31. Von der Netzführung zur Systemführung in Verteilernetzen

Author

Schmaranz, Robert, Fiedler, Leopold, Bergmayer, Roland, Ammer, Christian, Buzanich, Hannes, Frittum, Björn, Brüggl, Manuel, Schuster, Thomas, Zachs, Christian, and Grüneis, Helmut

Published

2023

32. Structural and electronic properties of solid molecular hydrogen from many-electron theories

Author

Liao, Ke, Shen, Tong, Li, Xin-Zheng, Alavi, Ali, and Grüneis, Andreas

Subjects

Condensed Matter - Materials Science, Physics - Computational Physics

Abstract

We study the structural and electronic properties of phase III of solid hydrogen using accurate many-electron theories and compare to state-of-the-art experimental findings. The atomic structures of phase III modelled by C2/c-24 crystals are fully optimized on the level of second-order perturbation theory, demonstrating that previously employed structures optimized on the level of approximate density functionals exhibit errors in the H$_2$ bond lengths that cause significant discrepancies in the computed quasi particle band gaps and vibrational frequencies compared to experiment. Using the newly optimized atomic structures, we study the band gap closure and change in vibrational frequencies as a function of pressure. Our findings are in good agreement with recent experimental observations and may prove useful in resolving long-standing discrepancies between experimental estimates of metallization pressures possibly caused by disagreeing pressure calibrations., Comment: MP2 forces' implementation and zero point renormalization on the bandgaps details are in supp.pdf

Published

2020

33. A periodic equation-of-motion coupled-cluster implementation applied to $F$-centers in alkaline earth oxides

Author

Gallo, Alejandro, Hummel, Felix, Irmler, Andreas, and Grüneis, Andreas

Subjects

Condensed Matter - Materials Science, Physics - Chemical Physics, Physics - Computational Physics

Abstract

We present an implementation of equation of motion coupled-cluster singles and doubles (EOM-CCSD) theory using periodic boundary conditions and a plane wave basis set. Our implementation of EOM-CCSD theory is applied to study $F$-centers in alkaline earth oxides employing a periodic supercell approach. The convergence of calculated electronic excitation energies for neutral color centers in MgO, CaO and SrO crystals with respect to orbital basis set and system size is explored. We discuss extrapolation techniques that approximate excitation energies in the complete basis set limit and reduce finite size errors. Our findings demonstrate that EOM-CCSD theory can predict optical absorption energies of $F$-centers in good agreement with experiment. Furthermore, we discuss calculated emission energies corresponding to the decay from triplet to singlet states, responsible for the photoluminescence properties. Our findings are compared to experimental and theoretical results available in literature.

Published

2020

34. A comparative study using state-of-the-art electronic structure theories on solid hydrogen phases under high pressures

Author

Liao, Ke, Li, Xin-Zheng, Alavi, Ali, and Grüneis, Andreas

Subjects

Condensed Matter - Materials Science

Abstract

Identifying the atomic structure and properties of solid hydrogen under high pressures is a long-standing problem of high-pressure physics with far-reaching significance in planetary and materials science. Determining the pressure-temperature phase diagram of hydrogen is challenging for experiment and theory due to the extreme conditions and the required accuracy in the quantum mechanical treatment of the constituent electrons and nuclei, respectively. Here, we demonstrate explicitly that coupled cluster theory can serve as a computationally efficient theoretical tool to predict solid hydrogen phases with high accuracy. We present a first principles study of solid hydrogen phases at pressures ranging from 100 to 450 GPa. The computed static lattice enthalpies are compared to state-of-the-art diffusion Monte Carlo results and density functional theory calculations. Our coupled cluster theory results for the most stable phases including C2/c-24 and P21/c-24 are in good agreement with those obtained using diffusion Monte Carlo, with the exception of Cmca-4, which is predicted to be significantly less stable. We discuss the scope of the employed methods and how they can contribute as efficient and complementary theoretical tools to solve the long-standing puzzle of understanding solid hydrogen phases at high pressures., Comment: 6 pages, 3 figures

Published

2020

35. Applying the Coupled-Cluster Ansatz to Solids and Surfaces in the Thermodynamic Limit

Author

Gruber, Thomas, Liao, Ke, Tsatsoulis, Theodoros, Hummel, Felix, and Grüneis, Andreas

Subjects

Condensed Matter - Materials Science, Physics - Computational Physics

Abstract

Modern electronic structure theories can predict and simulate a wealth of phenomena in surface science and solid-state physics. In order to allow for a direct comparison with experiment, such ab initio predictions have to be made in the thermodynamic limit, substantially increasing the computational cost of many-electron wave-function theories. Here, we present a method that achieves thermodynamic limit results for solids and surfaces using the "gold standard" coupled cluster ansatz of quantum chemistry with unprecedented efficiency. We study the energy difference between carbon diamond and graphite crystals, adsorption energies of water on h-BN, as well as the cohesive energy of the Ne solid, demonstrating the increased efficiency and accuracy of coupled cluster theory for solids and surfaces., Comment: 4 figures

Published

2020

36. Coupled cluster theory in materials science

Author

Zhang, Igor Ying and Grüneis, Andreas

Subjects

Condensed Matter - Materials Science, Physics - Chemical Physics

Abstract

In this tutorial-style review we discuss basic concepts of coupled cluster theory and recent developments that increase its computational efficiency for calculations of molecules, solids and materials in general. We will touch upon the connection between coupled cluster theory and the random-phase approximation that is widely used in the field of solid-state physics. We will discuss various approaches to improve the computational performance without compromising on accuracy. These approaches include large-scale parallel design as well as techniques that reduce the pre-factor of the computational complexity. A central part of this article discusses the convergence of calculated properties to the thermodynamic limit, which is of significant importance for reliable predictions of materials properties and constitutes an additional challenge compared to calculations of large molecules. We mention technical aspects of computer code implementations of periodic coupled cluster theories in different numerical frameworks of the one-electron orbital basis; the projector-augmented-wave formalism using a plane wave basis set and the numeric atom-centered-orbital (NAO) with resolution-of-identity. We will discuss results and the possible scope of these implementations and how they can help advance the current state of the art in electronic structure theory calculations of materials., Comment: 2 figures

Published

2020

37. Correlation in extended systems: general discussion.

Author

Alavi, Ali, Atalar, Kemal, Berkelbach, Timothy C., Booth, George H., Chan, Garnet Kin-Lic, Evangelista, Francesco A., Goldzak, Tamar, Grüneis, Andreas, Harsha, Gaurav, Kapil, Venkat, Knowles, Peter, Lepetit, Marie-Bernadette, Liebert, Julia, Nejad, Arman, Neufeld, Verena A., Novoa, Trinidad, Pernal, Katarzyna, Plasser, Felix, Rehman, Umatur, and Shi, Benjamin X.

Published

2024

38. Tunneling current modulation in atomically precise graphene nanoribbon heterojunctions.

Author

Senkovskiy, Boris V, Nenashev, Alexey V, Alavi, Seyed K, Falke, Yannic, Hell, Martin, Bampoulis, Pantelis, Rybkovskiy, Dmitry V, Usachov, Dmitry Yu, Fedorov, Alexander V, Chernov, Alexander I, Gebhard, Florian, Meerholz, Klaus, Hertel, Dirk, Arita, Masashi, Okuda, Taichi, Miyamoto, Koji, Shimada, Kenya, Fischer, Felix R, Michely, Thomas, Baranovskii, Sergei D, Lindfors, Klas, Szkopek, Thomas, and Grüneis, Alexander

Abstract

Lateral heterojunctions of atomically precise graphene nanoribbons (GNRs) hold promise for applications in nanotechnology, yet their charge transport and most of the spectroscopic properties have not been investigated. Here, we synthesize a monolayer of multiple aligned heterojunctions consisting of quasi-metallic and wide-bandgap GNRs, and report characterization by scanning tunneling microscopy, angle-resolved photoemission, Raman spectroscopy, and charge transport. Comprehensive transport measurements as a function of bias and gate voltages, channel length, and temperature reveal that charge transport is dictated by tunneling through the potential barriers formed by wide-bandgap GNR segments. The current-voltage characteristics are in agreement with calculations of tunneling conductance through asymmetric barriers. We fabricate a GNR heterojunctions based sensor and demonstrate greatly improved sensitivity to adsorbates compared to graphene based sensors. This is achieved via modulation of the GNR heterojunction tunneling barriers by adsorbates.

Published

2021

39. Origin of the flat band in heavily Cs doped graphene

Author

Ehlen, N., Hell, M., Marini, G., Hasdeo, E. H., Saito, R., Di Santo, G., Petaccia, L., Profeta, G., and Grüneis, A.

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

A flat energy dispersion of electrons at the Fermi level of a material leads to instabilities in the electronic system and can drive phase transitions. Here we introduce a method to induce a flat band in two-dimensional (2D) materials. We show that the flat band can be achieved by sandwiching the 2D material by two cesium (Cs) layers. We apply this method to monolayer graphene and investigate the flat band by a combination of angle-resolved photoemission spectroscopy experiment and the calculation. Our work highlights that charge transfer, zone folding of graphene bands and the covalent bonding between C and Cs atoms are at the origin of the flat energy band formation. The presented approach is an alternative route for obtaining flat band materials to twisting bilayer graphene which yields thermodynamically stable flat band materials in large areas., Comment: 22 pages, 4 Figures

Published

2019

40. Comprehensive tunneling spectroscopy of quasi-freestanding MoS$_2$ on graphene on Ir(111)

Author

Murray, Clifford, Jolie, Wouter, Fischer, Jeison A., Hall, Joshua, van Efferen, Camiel, Ehlen, Niels, Grüneis, Alexander, Busse, Carsten, and Michely, Thomas

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

We apply scanning tunneling spectroscopy to determine the bandgaps of mono-, bi- and trilayer MoS$_2$ grown on a graphene single crystal on Ir(111). Besides the typical scanning tunneling spectroscopy at constant height, we employ two additional spectroscopic methods giving extra sensitivity and qualitative insight into the $k$-vector of the tunneling electrons. Employing this comprehensive set of spectroscopic methods in tandem, we deduce a bandgap of $2.53\pm0.08$ eV for the monolayer. This is close to the predicted values for freestanding MoS$_2$ and larger than is measured for MoS$_2$ on other substrates. Through precise analysis of the `comprehensive' tunneling spectroscopy we also identify critical point energies in the mono- and bilayer MoS$_2$ band structures. These compare well with their calculated freestanding equivalents, evidencing the graphene/Ir(111) substrate as an excellent environment upon which to study the many feted electronic phenomena of monolayer MoS$_2$ and similar materials. Additionally, this investigation serves to expand the fledgling field of the comprehensive tunneling spectroscopy technique itself., Comment: 8 pages, 5 figures, accepted

Published

2019

41. On the duality of ring and ladder diagrams and its importance for many-electron perturbation theories

Author

Irmler, Andreas, Hummel, Felix, and Grüneis, Andreas

Subjects

Condensed Matter - Materials Science, Physics - Chemical Physics

Abstract

We present a diagrammatic decomposition of the transition pair correlation function for the uniform electron gas. We demonstrate explicitly that ring and ladder diagrams are dual counterparts that capture significant long- and short-ranged interelectronic correlation effects, respectively. Our findings help to guide the further development of approximate many-electron theories and reveal that the contribution of the ladder diagrams to the electronic correlation energy can be approximated in an effective manner using second-order perturbation theory. We employ the latter approximation to reduce the computational cost of coupled cluster theory calculations for insulators and semiconductors by two orders of magnitude without compromising accuracy., Comment: 6 pages, 2 figures, 1 table

Published

2019

42. Particle-particle ladder based basis-set corrections applied to atoms and molecules using coupled-cluster theory

Author

Irmler, Andreas and Grüneis, Andreas

Subjects

Physics - Chemical Physics, Condensed Matter - Materials Science, Physics - Atomic Physics, Physics - Computational Physics

Abstract

We investigate the basis-set convergence of electronic correlation energies calculated using coupled cluster theory and a recently proposed finite basis-set correction technique. The correction is applied to atomic and molecular systems and is based on a diagrammatically decomposed coupled cluster singles and doubles correlation energy. Only the second-order energy and the particle-particle ladder term are corrected for their basis-set incompleteness error. We present absolute correlation energies and results for a large benchmark set. Our findings indicate that basis set reductions by two cardinal numbers are possible for atomization energies, ionization potentials and electron affinities without compromising accuracy when compared to conventional CCSD calculations. In the case of reaction energies we find that reductions by one cardinal number are possible compared to conventional CCSD calculations. The employed technique can readily be applied to other many-electron theories without the need for three- or four-electron integrals., Comment: 9 pages, 3 figures, 6 tables

Published

2019

43. Ab-initio calculations of carbon and boron nitride allotropes and their structural phase transitions using periodic coupled cluster theory

Author

Gruber, Thomas and Grüneis, Andreas

Subjects

Condensed Matter - Materials Science

Abstract

We present an ab-initio study of boron nitride as well as carbon allotropes. Their relative thermodynamic stabilities and structural phase transitions from low- to high-density phases are investigated. Pressure-temperature phase diagrams are calculated and compared to experimental findings. The calculations are performed using quantum chemical wavefunction based as well as density functional theories. Our findings reveal that predicted energy differences often depend significantly on the choice of the employed method. Comparison between calculated and experimental results allows for benchmarking the accuracy of various levels of theory. The produced results show that quantum chemical wavefunction based theories allow for achieving systematically improvable estimates. We find that on the level of coupled cluster theories the low- and high-density phases of boron nitride become thermodynamically degenerate at 0 K. This is in agreement with recent experimental findings, indicating that cubic boron nitride is not the thermodynamically stable allotrope at ambient conditions. Furthermore we employ the calculated results to assess transition probabilities from graphitic low-density to diamond-like high-density phases in an approximate manner. We conclude that the stacking order of the parent graphitic material is crucial for the possible formation of meta-stable wurtzite boron nitride and hexagonal carbon diamond also known as lonsdaleite.

Published

2019

44. Sampling the reciprocal Coulomb potential in finite anisotropic cells.

Author

Schäfer, Tobias, Van Benschoten, William Z., Shepherd, James J., and Grüneis, Andreas

Subjects

COULOMB potential, POTENTIAL energy surfaces, LITHIUM hydride, SURFACE energy, CELL morphology, VON Neumann algebras

Abstract

We present a robust strategy to numerically sample the Coulomb potential in reciprocal space for periodic Born–von Karman cells of general shape. Our approach tackles two common issues of plane-wave based implementations of Coulomb integrals under periodic boundary conditions: the treatment of the singularity at the Brillouin-zone center and discretization errors, which can cause severe convergence problems in anisotropic cells, necessary for the calculation of low-dimensional systems. We apply our strategy to the Hartree–Fock and coupled cluster (CC) theories and discuss the consequences of different sampling strategies on different theories. We show that sampling the Coulomb potential via the widely used probe-charge Ewald method is unsuitable for CC calculations in anisotropic cells. To demonstrate the applicability of our developed approach, we study two representative, low-dimensional use cases: the infinite carbon chain, for which we report the first periodic CCSD(T) potential energy surface, and a surface slab of lithium hydride, for which we demonstrate the impact of different sampling strategies for calculating surface energies. We find that our Coulomb sampling strategy serves as a vital solution, addressing the critical need for improved accuracy in plane-wave based CC calculations for low-dimensional systems. [ABSTRACT FROM AUTHOR]

Published

2024

45. Optimizing Distributed Tensor Contractions Using Node-Aware Processor Grids

Author

Irmler, Andreas, primary, Kanakagiri, Raghavendra, additional, Ohlmann, Sebastian T., additional, Solomonik, Edgar, additional, and Grüneis, Andreas, additional

Published

2023

46. Coupled cluster finite temperature simulations of periodic materials via machine learning.

Author

Herzog, Basile, Gallo, Alejandro, Hummel, Felix, Badawi, Michael, Bučko, Tomáš, Lebègue, Sébastien, Grüneis, Andreas, and Rocca, Dario

Subjects

MACHINE learning, MACHINING, QUANTUM chemistry, MOLECULAR dynamics, DENSITY functional theory

Abstract

Density functional theory is the workhorse of materials simulations. Unfortunately, the quality of results often varies depending on the specific choice of the exchange-correlation functional, which significantly limits the predictive power of this approach. Coupled cluster theory, including single, double, and perturbative triple particle-hole excitation operators, is widely considered the 'gold standard' of quantum chemistry as it can achieve chemical accuracy for non-strongly correlated applications. Because of the high computational cost, the application of coupled cluster theory in materials simulations is rare, and this is particularly true if finite-temperature properties are of interest for which molecular dynamics simulations have to be performed. By combining recent progress in machine learning models with low data requirements for energy surfaces and in the implementation of coupled cluster theory for periodic materials, we show that chemically accurate simulations of materials are practical and could soon become significantly widespread. As an example of this numerical approach, we consider the calculation of the enthalpy of adsorption of CO2 in a porous material. [ABSTRACT FROM AUTHOR]

Published

2024

47. On the physisorption of water on graphene: Sub-chemical accuracy from many-body electronic structure methods

Author

Brandenburg, Jan Gerit, Zen, Andrea, Fitzner, Martin, Ramberger, Benjamin, Kresse, Georg, Tsatsoulis, Theodoros, Grüneis, Andreas, Michaelides, Angelos, and Alfè, Dario

Subjects

Condensed Matter - Materials Science, Physics - Chemical Physics, Physics - Computational Physics

Abstract

Molecular adsorption on surfaces plays a central role in catalysis, corrosion, desalination, and many other processes of relevance to industry and the natural world. Few adsorption systems are more ubiquitous or of more widespread importance than those involving water and carbon, and for a molecular level understanding of such interfaces water monomer adsorption on graphene is a fundamental and representative system. This system is particularly interesting as it calls for an accurate treatment of electron correlation effects, as well as posing a practical challenge to experiments. Here, we employ many-body electronic structure methodologies that can be rigorously converged and thus provide faithful references for the molecule-surface interaction. In particular, we use diffusion Monte-Carlo (DMC), coupled cluster (CCSD(T)), as well as the random phase approximation (RPA) to calculate the strength of the interaction between water and an extended graphene surface. We establish excellent, sub-chemical, agreement between the complementary high-level methodologies, and an adsorption energy estimate in the most stable configuration of approximately -100\,meV is obtained. We also find that the adsorption energy is rather insensitive to the orientation of the water molecule on the surface, despite different binding motifs involving qualitatively different interfacial charge reorganisation. In producing the first demonstrably accurate adsorption energies for water on graphene this work also resolves discrepancies amongst previously reported values for this widely studied system. It also paves the way for more accurate and reliable studies of liquid water at carbon interfaces with cheaper computational methods, such as density functional theory and classical potentials.

Published

2018

48. Narrow photoluminescence peak of epitaxial MoS$_2$ on graphene/Ir(111)

Author

Ehlen, Niels, Hall, Joshua, Senkovskiy, Boris V., Hell, Martin, Li, Jun, Herman, d Alexander, Smirnov, Dmitry, Fedorov, Alexander, Voroshnin, Vladimir Yu., di Santo, Giovanni, Petaccia, Luca, Michely, Thomas, and Grüneis, Alexander

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics, Condensed Matter - Materials Science

Abstract

We report on the observation of photoluminescence (PL) with a narrow 18 meV peak width from molecular beam epitaxy grown MoS$_2$ on graphene/Ir(111). This observation is explained in terms of a weak graphene-MoS$_2$ interaction that prevents PL quenching expected for a metallic substrate. The weak interaction of MoS$_2$ with the graphene is highlighted by angle-resolved photoemission spectroscopy and temperature dependent Raman spectroscopy. These methods reveal that there is no hybridization between electronic states of graphene and MoS$_2$ and a different thermal expansion of graphene and MoS$_2$. Molecular beam epitaxy grown MoS2 on graphene is therefore an important platform for optoelectronics which allows for large area growth with controlled properties., Comment: 18 pages, 5 figures, submitted for review

Published

2018

49. Reaction energetics of Hydrogen on the Si(100) surface: A periodic many-electron theory study

Author

Tsatsoulis, Theodoros, Sakong, Sung, Groß, Axel, and Grüneis, Andreas

Subjects

Condensed Matter - Materials Science, Physics - Chemical Physics

Abstract

We report on a many-electron wavefunction theory study for the reaction energetics of hydrogen dissociation on the Si(100) surface. We demonstrate that quantum chemical wavefunction based methods using periodic boundary conditions can predict chemically accurate results for the activation barrier and the chemisorption energy in agreement with experimental findings. These highly accurate results for the reaction energetics enable a deeper understanding of the underlying physical mechanism and make it possible to benchmark widely used density functional theory methods.

Published

2018

50. Emergent Dirac carriers across a pressure-induced Lifshitz transition in black phosphorus

Author

Di Pietro, P., Mitrano, M., Caramazza, S., Capitani, F., Lupi, S., Postorino, P., Ripanti, F., Joseph, B., Ehlen, N., Grüneis, A., Sanna, A., Profeta, G., Dore, P., and Perucchi, A.

Subjects

Condensed Matter - Materials Science, Condensed Matter - Other Condensed Matter

Abstract

The phase diagrams of correlated systems like cuprates or pnictides high-temperature superconductors are characterized by a topological change of the Fermi surface under continuous variation of an external parameter, the so-called Lifshitz transition. However, the large number of low-temperature instabilities and the interplay of multiple energy scales complicate the study of this phenomenon. Here we first identify the optical signatures of a pressure-induced Lifshitz transition in a clean elemental system, black phosphorus. By applying external pressures above 1.5 GPa, we observe a change in the pressure dependence of the Drude plasma frequency due to the appearance of massless Dirac fermions. At higher pressures, optical signatures of two structural phase transitions are also identified. Our findings suggest that a key fingerprint of the Lifshitz transition in solid state systems, and in absence of structural phase transitions, is a discontinuity of the Drude plasma frequency due to the change of Fermi surface topology.

Published

2018