The application of the methods of dynamical systems to plasma physics

Norris, J. W.

January 1987

No description available.

530.44

Plasma energy relaxation

Temperature Relaxation and Magnetically Suppressed Expansion in Strongly Coupled Ultracold Neutral Plasmas

Sprenkle, Robert Tucker

21 December 2021

Ultracold neutral plasmas provide a platform for studying transport properties in an idealized environment. In this dissertation, transport properties in a Ca$^+$/Yb$^+$ dual species ultracold neutral plasma and a Ca$^+$ magnetized ultracold neutral plasma are studied. In dual species plasmas, we study ion-ion temperature relaxation. We compare measured relaxation rates with atomistic simulations and a range of popular theories. Our work validates the assumptions and capabilities of molecular dynamic simulations and invalidates theoretical models in this regime. This work illustrates an approach for precision determinations of detailed material properties in Coulomb mixtures across a wide range of conditions. We also study plasma expansion in single species plasma in the presence of a strong uniform magnetic field. We find that the asymptotic expansion velocity falls exponentially with magnetic field strength, which disagrees with a previously published ambipolar diffusion model. In the parallel direction, plasma expansion is driven by electron pressure. However, in the perpendicular direction, no plasma expansion is observed at large magnetic field strengths.

energy transport

ultracold neutral plasma

magnetized plasma

strong coupling

energy relaxation

self-similar expansion

ambipolar diffusion

Physical Sciences and Mathematics

Vibrational relaxation and dephasing of Rb2 attached to helium nanodroplets

Grüner, Barbara, Schlesinger, Martin, Heister, Philipp, Strunz, Walter T., Stienkemeier , Frank, Mudrich, Marcel

02 April 2014

The vibrational wave-packet dynamics of diatomic rubidium molecules (Rb2) in triplet states formed on the surface of superfluid helium nanodroplets is investigated both experimentally and theoretically. Detailed comparison of experimental femtosecond pump–probe spectra with dissipative quantum dynamics simulations reveals that vibrational relaxation is the main source of dephasing. The rate constant for vibrational relaxation in the first excited triplet state 13Σ+g is found to be constant γ ≈ 0.5 ns−1 for the lowest vibrational levels v [less, similar] 15 and to increase sharply when exciting to higher energies. / Dieser Beitrag ist mit Zustimmung des Rechteinhabers aufgrund einer (DFG-geförderten) Allianz- bzw. Nationallizenz frei zugänglich.

zweiatomige Rubidiummoleküle

Spektroskopie

Pump-Probe-Technik

Raman-Streuung

Helium

Rubidium

wave-packet dynamics

resolved ionization spectroscopy

pump-probe spectroscopy

fractional revivals

ultrafast dynamics

condensed-phase

solid kr

energy relaxation

raman-scattering

he-4 clusters

ddc:540

rvk:VA 1120

Simulación mediante métodos híbridos clásico-cuánticos de la relajación vibracional de moléculas en disolución

Cruz Valcárcel, Carlos

25 November 2005

En esta tesis desarrollamos métodos híbridos clásico-cuánticos para el estudio de la relajación vibracional de moléculas en disolución. En estos tratamientos se realiza una descripción cuántica de la vibración del soluto, mientras que el resto de grado de libertad se describen clásicamente. Estos métodos superan las limitaciones inherentes a los tratamientos clásicos y permiten el análisis del flujo de energía entre el soluto y el disolvente. Hemos aplicado estas metodologías al estudio de la relajación vibracional de la molécula de yodo en xenón líquido y del ión cianuro en agua, analizando el papel del disolvente en las transiciones vibracionales del soluto. Nuestros resultados para estos sistemas, de naturaleza tan diferente, concuerdan bien con las medidas experimentales, lo que en ausencia de resultados teóricos exactos supone una valiosa prueba de la capacidad de estos métodos para el estudio de los procesos de relajación vibracional en líquidos. / In this thesis we have developed hybrid quantum-classical methods to study vibrational relaxation of molecules in solution. In these treatments a quantum description of solute vibration is done, while the other degrees of freedom are classically described. These methods overcome the inherent limitations of classical treatments and let us the analysis of energy flux between solute and solvent. We have applied these methodologies to study vibrational relaxation of iodine molecule in liquid xenon and cyanide ion in water, analyzing the role of the solvent in the vibrational transitions of the solute. Our results for these systems, of so different kind, agree well with experimental measures, what in absence of exact theoric results is a valious proof of the ability of these methods to study the vibrational relaxation processes in liquids.

HYBRID QUANTUM-CLASSICAL METHODS

VIBRATIONAL ENERGY RELAXATION

QUANTUM TRANSITIONS

MÉTODOS HÍBRIDOS CLÁSICO-CUÁNTICOS

SOLUTIONS

MOLECULAR DYNAMICS

RELAJACIÓN DE ENERGÍA VIBRACIONAL

TRANSICIONES CUÁNTICAS

DINÁMICA MOLECULAR

DISOLUCIONES

Química Física

5

54

544

Timing Jitter and Electron-Phonon Interaction in Superconducting Nanowire Single-Photon Detectors (SNSPDs)

Sidorova, Mariia

29 January 2021

Die vorliegende Doktorarbeit beschäftigt sich mit der experimentellen Studie zweier miteinander verbundener Phänomene: Dem intrinsischen Timing-Jitter in einem supraleitendenden Nanodraht-Einzelphotonen-Detektor (SNSPD) und der Relaxation der Elektronenenergie in supraleitenden Filmen. Supraleitende Nanodrähte auf einem dielektrischen Substrat als mikroskopische Grundbausteine jeglicher SNSPDs stellen sowohl für theoretische als auch für experimentelle Studien komplexe Objekte dar. Die Komplexität ergibt sich aus der Tatsache, dass SNSPDs in der Praxis stark ungeordnete und ultradünne supraleitende Filme verwenden, die eine akustische Fehlanpassung zu dem zugrundeliegenden Substrat aufweisen und einen Nichtgleichgewichts-Zustand implizieren. Die Arbeit untersucht die Komplexität des am weitesten in der SNSPD Technologie verbreiteten Materials, Niobnitrid (NbN), indem verschiedene experimentelle Methoden angewandt werden. Als eine mögliche Anwendung der SNSPD-Technologie wird ein Prototyp eines dispersiven Raman-Spektrometers mit Einzelphotonen-Sensitivität demonstriert. / This Ph.D. thesis is based on the experimental study of two mutually interconnected phenomena: intrinsic timing jitter in superconducting nanowire single-photon detectors (SNSPDs) and relaxation of the electron energy in superconducting films. Microscopically, a building element of any SNSPD device, a superconducting nanowire on top of a dielectric substrate, represents a complex object for both experimental and theoretical studies. The complexity arises because, in practice, the SNSPD utilizes strongly disordered and ultrathin superconducting films, which acoustically mismatch with the underlying substrate, and implies a non-equilibrium state. This thesis addresses the complexity of the most conventional superconducting material used in SNSPD technology, niobium nitride (NbN), by applying several distinct experimental techniques. As an emerging application of the SNSPD technology, we demonstrate a prototype of the dispersive Raman spectrometer with single-photon sensitivity.

Timing-Jitter

Elektronen-Phonon-Streuung

Relaxation der Elektronenenergie

Raman-Spektrometer

superconducting single-photon detector

timing jitter

electron-phonon scattering

electron-energy relaxation

Raman spectrometer

530 Physik

ddc:530

Vibrational relaxation and dephasing of Rb2 attached to helium nanodroplets

Grüner, Barbara, Schlesinger, Martin, Heister, Philipp, Strunz, Walter T., Stienkemeier, Frank, Mudrich, Marcel

January 2011

The vibrational wave-packet dynamics of diatomic rubidium molecules (Rb2) in triplet states formed on the surface of superfluid helium nanodroplets is investigated both experimentally and theoretically. Detailed comparison of experimental femtosecond pump–probe spectra with dissipative quantum dynamics simulations reveals that vibrational relaxation is the main source of dephasing. The rate constant for vibrational relaxation in the first excited triplet state 13Σ+g is found to be constant γ ≈ 0.5 ns−1 for the lowest vibrational levels v [less, similar] 15 and to increase sharply when exciting to higher energies. / Dieser Beitrag ist mit Zustimmung des Rechteinhabers aufgrund einer (DFG-geförderten) Allianz- bzw. Nationallizenz frei zugänglich.

info:eu-repo/classification/ddc/540

ddc:540

Theoretical investigation of α-iron chromium carbide (α-Fe/Cr7C3) interfaces / Teoretisk undersökning av gränssnittet mellan α-järn och kromkarbid (α-Fe/Cr7C3)

Al-Hussein, Hussein

January 2023

This master thesis presents a theoretical investigation of the energy and stability of interfaces in iron-carbide compounds, specifically focusing on the α-Fe/Cr7C3 system. The study aims to fill the gap in knowledge regarding the surface energetics of these interfaces using Density Functional Theory (DFT). Six different α-Fe/Cr7C3 interfaceswere constructed α-Fe(001)/Cr7C3(024), α-Fe(001)/Cr7C3(202), α-Fe(001)/Cr7C3(040),α-Fe(110)/Cr7C3(024), α-Fe(110)/Cr7C3(202) and α-Fe(110)/Cr7C3(040). Due to limited computational resources, only one of them was computationally analyzed to determine its interfacial energy value. The results revealed that the interfacial energy of the α-Fe(001)/Cr7C3(040) interface falls within the range of incoherent interfaces, indicating its stability. The computed interfacial energy values ranged from 0.94 to 3.39 J/m2, consistent with similar studies on other iron interfaces. The simulations also identified minimum and local minimum points in the interface energy curve, representing stable configurations at specific interface separation distances. The presence of a minimum point at an interface separation value of d = 1.3551 Å with an interfacial energy of 0.94 J/m2 indicates the most stable configuration, while a local minimum point at d = 2.27 Å with an interfacial energy of 2.12 J/m2 suggests another stable configuration for the interface. The conclusion that the computations were correctly performed with an interfacial energy value of 0.94 J/m2 for the most stable configuration at a supercell length (aSupercell ) of 22.23 Å is drawn. The findings of this research have significant implications for future investigations and applications. Firstly, this study fills the gap of the unresearched ferrite-carbide interfaces with theoretical data. Secondly, the knowledge gained from studying these interfaces contributes to understanding hydrogen interactions, which is fundamental for the transition towards a hydrogen economy. Additionally, the incoherent nature of the interface introduces challenges in understanding material behavior and properties, necessitating further investigations for designing efficient systems. Future work includes experimental validation of the α-Fe/Cr7C3 interface to compare the theoretical and experimental energies and stability. Investigating the remaining interfaces and examining the effects of introducing hydrogen atoms in these interfaces, along with calculating the corresponding hydrogen trapping energies, are important research areas. Further advancements in understanding these interfaces can be achieved through interface engineering, multiscale modeling, and studying other iron-carbide systems. / Detta examensarbete presenterar en teoretisk undersökning av energin och stabiliteten hos gränssnitt i järnkarbidföreningar och fokuserar specifikt på α-Fe/Cr7C3-systemet. Studien syftar till att fylla kunskaps tomrummet gällande ytegenskaperna hos dessa gränssnitt genom användning av densitetsfunktionalteori (DFT). Sex olika α-Fe/Cr7C3-gränssnitt konstruerades α-Fe(001)/Cr7C3(024), α-Fe(001)/Cr7C3(202), α-Fe(001)/Cr7C3(040), α-Fe(110)/Cr7C3(024), α-Fe(110)/Cr7C3(202) och α-Fe(110)/Cr7C3(040). På grund av begränsade beräkningsresurser analyserades endast ett av dem för att bestämma dess gränssnittsenergivärde. Resultaten visade att gränssnittsenergin för α-Fe(001)/Cr7C3(040)- gränssnittet ligger inom intervallet för inkoherenta gränssnitt, vilket indikerar dess stabilitet. De beräknade gränssnittsenergivärdena varierade mellan 0,94 och 3,39 J/m2 , vilket är i linje med liknande studier där järngränssnitt studeras. Minimi och lokala minimipunkter i gränssnittets energikurva, vilket representerar stabila konfigurationer vid specifika avstånd mellan gränssnittet. Förekomsten av en minimipunkt vid ett gränssnittsavstånd på d = 1,35 Å med en gränssnittsenergi på 0,94 J/m2 indikerar den mest stabila konfigurationen, medan en lokal minimipunkt vid d = 2,27 Å med en gränssnittsenergi på 2,12 J/m2 antyder en annan stabil konfiguration för gränssnittet. Slutsatsen dras att beräkningarna utfördes korrekt med ett gränssnittsenergivärde på 0,94 J/m2 för den mest stabila konfigurationen vid en supercellslängd (aSupercell) på 22,23 Å. Fynden från denna forskning har betydande implikationer för framtida undersökningar och tillämpningar. För det första fyller denna studie kunskapsgapet gällande de otillräckligt utforskade ferrit-karbidgränssnitten med teoretisk data. För det andra bidrar den erhållna kunskapen från studiet av dessa gränssnitt till förståelsen av väteinteraktioner, vilket är grundläggande för övergången till en väteekonomi. Dessutom innebär gränssnittets inkoherenta natur utmaningar när det gäller att förstå materialbeteende och egenskaper, vilket kräver ytterligare undersökningar för att utforma effektiva system. Framtida arbete inkluderar experimentell validering av gränssnittet mellan α-Fe/Cr7C3 för att jämföra teoretiska och experimentella energier och stabilitet. Att undersöka återstående gränssnitt och undersöka effekterna av att introducera väteatomer i dessa gränssnitt och beräkna motsvarande vätefällningsenergier är viktiga forskningsområden. Gränssnittsdesign, flerskalig modellering och studier av andra järnkarbid-system kan ytterligare främja förståelsen av dessa gränssnitt.

Alpha-iron

Chromium carbide

Cr7C3

Fe

Theoretical investigation

Orthorhombic

X-ray diffraction pattern

XRD

VASP

VESTA

Body-centered-cubic

Ferrite

Density functional theory

DFT

Surface relaxation

Simulation

Calculation

Energy relaxation

Slab models

Coherency

Surface energy

Interfacial energy

Alfa-järn

Kromkarbid

Cr7C3

Fe

Teoretisk undersökning

Ortorombisk

Röntgendiffraktion

XRD

VASP

VESTA

Ytenergi

Koherent

Simulering

Beräkning

Järnkarbid

DFT

Täthetsfunktionalanalys

Bearbetnings-, yt- och fogningsteknik

Photolytischer Käfigeffekt von Dihalomethanen in überkritischen Lösungsmitteln / Photolytic cage effect of dihalomethanes in supercritical solvents

Zerbs, Jochen

02 November 2005

No description available.

540 Chemie

Mathematics and Computer Science

photolytischer Käfigeffekt

Diiodmethan

Bromiodmethan

Pump Probe Spektroskopie

überkritische Fluide

Schwingungsenergierelaxation

Orientierungsrelaxation

molekulardynamische Simulationen

radiale Verteilungsfunktionen

lokale Dichtevergrößerung

photolytic cage effect

diiodomethane

bromoiodomethane

pump probe spectroscopy

supercritical fluids

vibrational energy relaxation

orientational relaxation

molecular dynamics simulations

radial distribution functions

local density enhancement

35.13

35.16

35.22

SD 000: Physikalische Chemie

SBC 000: Chemie bei hohen Drucken

SIL 000: Laser-Chemie {Strahlungschemie}

SIC 000: Radiolyse {Photochemie}