Vibrational Response of Felodipine in the THz Domain: Optical and Neutron Spectroscopy Versus Plane-Wave DFT Modeling

Łuczyńska, Katarzyna; Drużbicki, Kacper; Runka, Tomasz; Pałka, Norbert; Węsicki, Jan

doi:10.1007/s10762-019-00634-9

Cited by 7 publications

(4 citation statements)

References 155 publications

(200 reference statements)

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“…To mitigate the above difficulties, as well as to avoid the arbitrariness and deficiencies of semiempirical vdW corrections, we have adopted a fixed-cell methodology, using the cell parameters measured with SXRD at 120 K. We have shown earlier a high robustness and versatility of such an approach in combination with standard (PBE) and hard-GGA (rPBE) GGA-type XC functionals for the prediction of the vibrational spectra. The adequacy of the approach has been confirmed for a number of diversely bonded, flexible, and complex molecular as well as ionic systems, studied over a broad frequency range and compared to both optical and INS data. ,− This is also corroborated by our previous experience in the modeling of solids containing nitrate ions , and nitro moieties. , The adequacy of the adopted methodology in our particular case is examined in Figures S7 and S8, showing a zone-center mechanical stability of the Pmmn model. The reliability of our computational methodology is confirmed further in Figure , presenting theoretical spectra at intermediate energies calculated for both [N 0 0 2 2 ][NO 3 ] and [N 0 0 D D ][NO 3 ] specimens.…”

Section: Resultssupporting

confidence: 69%

Spectroscopic Signatures of Hydrogen-Bonding Motifs in Protonic Ionic Liquid Systems: Insights from Diethylammonium Nitrate in the Solid State

et al. 2021

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Diethylammonium nitrate, [N 0 0 2 2 ][NO 3 ], and its perdeuterated analogue, [N D D 2 2 ] [NO 3 ], were structurally characterized and studied by infrared, Raman, and inelastic neutron scattering (INS) spectroscopy. Using these experimental data along with state-of-the-art computational materials modeling, we report unambiguous spectroscopic signatures of hydrogen-bonding interactions between the two counterions. An exhaustive assignment of the spectral features observed with each technique has been provided, and a number of distinct modes related to NH···O dynamics have been identified. We put a particular emphasis on a detailed interpretation of the high-resolution, broadband INS experiments. In particular, the INS data highlight the importance of conformational degrees of freedom within the alkyl chains, a ubiquitous feature of ionic liquid (IL) systems. These findings also enable an in-depth physicochemical understanding of protonic IL systems, a first and necessary step to the tailoring of hydrogen-bonding networks in this important class of materials.

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Section: Resultssupporting

confidence: 69%

Spectroscopic Signatures of Hydrogen-Bonding Motifs in Protonic Ionic Liquid Systems: Insights from Diethylammonium Nitrate in the Solid State

et al. 2021

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“…While the different codes might be tailored to different material types, for example, atom-centered basis sets more readily enable chemical insight and are well-suited for molecular crystals, , while plane-wave codes are usually better for inorganic solids and conductors; ultimately, all of these software packages are capable of accurately simulating the low-frequency vibrational dynamics of crystalline solids. This has resulted in users having more choice than ever in this regard, which is apparent in the current literature. − …”

Section: Methodsmentioning

confidence: 99%

Advances in Low-Frequency Vibrational Spectroscopy and Applications in Crystal Engineering

Kleist

Ruggiero

2021

Crystal Growth & Design

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The field of low-frequency vibrational spectroscopy has grown significantly over the past two decades, based on advances in both experimental lasers and optics, as well as highperformance computing and quantum mechanical simulations. The combination of these techniques has enabled unprecedented insight into the atomic-level dynamics that occur at terahertz frequencies, which usually involve large-amplitude motions of entire molecules. This has ultimately provided the community with new tools for investigating and engineering crystalline materials through an understanding of intermolecular forces, as well as dynamics. In this Perspective, an overview of the field will be provided and complemented by recent examples where lowfrequency vibrational motions are being used to understand, and drive, bulk material function.

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“…A discussion on the current trends and practical aspects of modeling the low-frequency vibrational spectra can be found in Ref. [ 152 ]. Usually, electronic-structure calculations are performed using several implementations of density functional theory (DFT), relying either on the use of plane waves (e.g., CASTEP [ 153 , 154 ], QUANTUM ESPRESSO [ 155 ], ABINIT [ 156 ]), projector augmented-waves (e.g., VASP [ 157 ], GPAW [ 158 ]), and localized numerical (FHI-aims [ 159 , 160 ], SIESTA [ 161 ]) or Gaussian (CRYSTAL [ 162 ], TURBOMOLE [ 163 ]) basis sets, a hybrid plane-wave / Gaussian approach (CP2K [ 164 ]), or imposing all-electron full-potential Linearised Augmented Plane Waves (LAPW; WIEN2K [ 165 ] and ELK [ 166 ] programs).…”

Section: Soft Media For Photovoltaics and Photonicsmentioning

confidence: 99%

Dynamics & Spectroscopy with Neutrons—Recent Developments & Emerging Opportunities

2021

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This work provides an up-to-date overview of recent developments in neutron spectroscopic techniques and associated computational tools to interrogate the structural properties and dynamical behavior of complex and disordered materials, with a focus on those of a soft and polymeric nature. These have and continue to pave the way for new scientific opportunities simply thought unthinkable not so long ago, and have particularly benefited from advances in high-resolution, broadband techniques spanning energy transfers from the meV to the eV. Topical areas include the identification and robust assignment of low-energy modes underpinning functionality in soft solids and supramolecular frameworks, or the quantification in the laboratory of hitherto unexplored nuclear quantum effects dictating thermodynamic properties. In addition to novel classes of materials, we also discuss recent discoveries around water and its phase diagram, which continue to surprise us. All throughout, emphasis is placed on linking these ongoing and exciting experimental and computational developments to specific scientific questions in the context of the discovery of new materials for sustainable technologies.

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Vibrational Response of Felodipine in the THz Domain: Optical and Neutron Spectroscopy Versus Plane-Wave DFT Modeling

Cited by 7 publications

References 155 publications

Spectroscopic Signatures of Hydrogen-Bonding Motifs in Protonic Ionic Liquid Systems: Insights from Diethylammonium Nitrate in the Solid State

Spectroscopic Signatures of Hydrogen-Bonding Motifs in Protonic Ionic Liquid Systems: Insights from Diethylammonium Nitrate in the Solid State

Advances in Low-Frequency Vibrational Spectroscopy and Applications in Crystal Engineering

Dynamics & Spectroscopy with Neutrons—Recent Developments & Emerging Opportunities

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