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The high frequency dynamics of liquids and supercritical fluids. by Filippo Bencivenga. OUTLINE. Introduction Experimental description Data analysis Experimental results (Dispersions) Experimental results (Relaxations) Conclusions Outlook. Supercritical. Critical Point.
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The high frequency dynamics of liquids and supercritical fluids by Filippo Bencivenga
OUTLINE • Introduction • Experimental description • Data analysis • Experimental results (Dispersions) • Experimental results (Relaxations) • Conclusions • Outlook
Supercritical Critical Point LIQUIDS & SUPERCRITICAL FLUIDS (1) Pressure Temperature
csQ Microscopic dynamics(ps) What is missing? What is Known: LIQUIDS & SUPERCRITICAL FLUIDS (2) Qm~2p/r0 Thermodynamic properties Microscopic structure(nm) SC fluids: a few cases Systematic studies: none
Liquid phase Supercritical phase AIM OF THE THESIS Microscopic dynamics ( ps-nm) From a microscopic point of view … … what is the role of inter- and intra-molecular interactions ? … what is the difference between a liquid and a SC fluid ?
Supercritical Liquid H2O NH3 Ne N2 EXPERIMENTS (1)
Pressure connector Cell body out sample Sealing system in out in X-ray beam Scattered beam EXPERIMENTS (2) • Large Volume HP Cells • Low pressures ( Kbar) • “Large” samples ( cm3) • Versatility (High-T & Low-T) Cell body Nut Sample X-ray beam Scattered beam 10 mm
•Q = |kout – kin| 2 kin sin(q) •w=E/ ħ =(Eout– Ein) / ħ No /NiS(Q,w) INELASTIC X-RAY SCATTERING (IXS) Q nm-1 w THz lengths nm times ps Q,E No Eout, kout Sample 2 q Ni Ein, kin ħ=1
Q = 8 nm-1 N2 1.5 meV IXS SPECTRA T = 87 K N2
[ ] wm’(Q,w) 2 (cTQ)2 m’(Q,w) 1 p [ w2-(cTQ)2-wm’’(Q,w) 2 ] + S(Q,w) = S(Q) DATA ANALYSIS Free EoS Rayleigh-Brillouin Spectrum Free Fix Fix m(Q,t)=(g-1)(cTQ)2exp{-t/tT}+2Gmd(t) +(c∞2-gcT2)Q2exp{-t/ta} m(Q,t)=2nLQ2d(t)+(g-1)(cTQ)2exp{-t/tT} Low-(Q,w) limit Hydrodynamics Free Free Instantaneous relaxation (c∞2-gcT2)Q2exp{-t/ta}+2Gmd(t) Thermal relaxation Structural relaxation WL(Q) max[w2S(Q,w)] taps tT=1/DTQ2
Fully unrelaxed: elastic WL(Q)ta1 ta-1 c∞Q c0Q Fully relaxed: viscous SOUND DISPERSIONS & RELAXATIONS (1) Visco-Elasticity: 1) Low-Frequency limit:c0=cs=g1/2cT 2) High-Frequency limit:c∞ “High” and “low” frequency is with respect tota-1 Structural relaxation WL(Q) W Positive sound dispersion Q
Unrelaxed Relaxed: isothermal WL(Q) W ta-1 c0Q Relaxed Q WL(Q)tT1 c∞Q WL(Q) W Unrelaxed: adiabatic ta-1 csQ Q SOUND DISPERSIONS & RELAXATIONS (2) Isothermal transition: “High” and “low” frequency is with respect to tT-1 1) High-Frequency limit:c∞=cs=g1/2cT 2) Low-Frequency limit:c0=cT Thermal relaxation Structural and thermal relaxations: competing dispersive effects WL(Q) W csQ Structural relaxation tT-1=DTQ2 Structural relaxation Q Negative sound dispersion
RESULTS (DISPERSIONS) kBTQ2 WT2(Q)= MS(Q) Ws(Q)=√gWT(Q) WL=ta-1 W∞(Q)=c∞(Q)Q N2 @400 bar T/Tc=0.69 Good agreement with S(Q) measurements WL(Q) WT(Q)=cT(Q)Q ta-1 WL(Q) max[w2S(Q,w)]
W∞ WL=ta-1 WL~Ws WL Ws ta-1 WT WL=ta-1 WT DISPERSION RELATIONS (N2) DTQ 2 WL=DTQ2
H2O NH3 Ne W L W s WL=DTQ2 WL=DTQ2 WL=DTQ2 DISPERSION RELATIONS c∞ ta-1 WL~Ws DTQ2 W T
M(Q)=1 Elastic M(Q)=1 Elastic M(Q)=0 Viscous M(Q)=0 Viscous COMMON PHENOMENOLOGY (1)
MT(Q)=1 Adiabatic MT(Q)=0 Isothermal COMMON PHENOMENOLOGY (2) Structural relaxation Thermal relaxation W∞(Q) Ws(Q) WT(Q) Ws(Q) Vs. MT(Q)=1 Adiabatic Da2(Q)=W∞2(Q) - Ws2(Q) DT2(Q)=Ws2(Q) - WT2(Q) >> MT(Q)=0 Isothermal Dispersive effect of structural relaxation
CONCLUSIONS (SOUND DISPERSION) • Common evolution with T: • Evidence of a systematic disappearance of the positive dispersion, relatedto the structural relaxation, close to Tc • First experimental observation of an adiabatic to isothermal transition of sound propagation, associated to the thermal relaxation.
RESULTS (RELAXATIONS) Liquid Supercritical STRUCTURAL RELAXATION TIME ta(Q)=ta(0)exp{-AQ} A≈0.2 ÷ 0.05 nm ta(0)exp{E/kBT} E(KJ/mol) • H2O • NH3 • N2 • Ne
( c∞ ta(0) tc Liquid Supercritical = cs 2tc -1(Q) • H2O • NH3 • N2 • Ne W∞(Q) [ W∞(Q)=c∞Q ta(Q) tc(Q) 2 2 = ] ) Ws(Q) EoS COMPLIANCE RELAXATION TIME Q 0
Liquid Supercritical • H2O • NH3 • N2 • Ne 1 <t> √(d4/M)*(r2T) COMMON PHENOMENOLOGY <t> <l> oP. Giura et al.; Unpublished (2006)
STRUCTURAL RELAXATION STRENGTH D2a=c∞2- cs2 =Cr • H2O • NH3 • N2 • Ne Linesdensity
CONCLUSIONS • Common phenomenology: • Negative sound dispersion Thermal relaxation • Positive sound dispersionStructural relaxation • Activation behavior (≈bond’s energy) oftabelow Tc • Collision-like behaviorofta(tc)above Tc • D2a density(correlation with the parameter “a”?) • Structural relaxation related to intermolecuar interactions
OUTLOOK H2O NH3 N2Ne • Extend the Tc/T range: • high-T for H2O &NH3 • low-T for Ne & N2 Other classes of fluids !
ACKNOWLEDGEMENTS • M. Krisch, F. Sette, G. Monaco and all the ID28-ID16 staff (ESRF) • A. Cunsolo, L. Melesi (ILL) • G. Ruocco (Universitá “La Sapienza”, Roma) • L. Orsingher (Universitá di Trento) • A. Vispa (Universitá di Perugia)
DE/E ≈ 10-8 Monochromator Si (n,n,n) 6.5 m DE/E ≈ 10-4 ≈ Undulators Pre-Monochromator Si (1,1,1) qB Toroidal mirror 75 m IXS BEAMLINE (ID-28) 5 Analyzers Si (n,n,n) Analyzer Si (n,n,n) Q 2q qB 5 Detectors Detector T-scan ≈ mK sample DE/E ≈ 10-2
H2O @ 400 bar STATIC STRUCTURE FACTORS N2 @ 400 bar
( c∞ ta(0) tc = cs 2tc -1(Q) w=tc-1 M(∞) ta tc = M(0) W∞(Q) [ EoS ta(Q) tc(Q) 2 2 = ) ] Ws(Q) COMPLIANCE RELAXATION TIME M(∞) w=ta-1 M-1(0) M-1(∞) M(0) W∞(Q)=c∞Q
D2m(Q)exp{-t/tm(Q)} INSTANTANEOUS RELAXATION Gm(Q)=rg(Q) Linesdensity 2Gm(Q)d(t) g(Q)=<Gm(Q)/r> 2Gm(Q)d(t) Gm(Q)r D2m(Q)r tm(Q)const Gm(Q)D2m(Q)tm(Q) Gm(Q)Q2 tm(Q)<<ps Intramolecular degree of freedom?
VISCOSITY (Q-dependence) hL(Q)=r[D2a(Q)ta(Q)+Gm(Q)/Q2] hL(Q)=hLexp{-BQ}
VISCOSITY (T-dependence) hL/hSconstant
OUTLOOK Disappearance of the positive dispersion? O2 H2O NH3 N2Ne Supercritical Study high T/Tc and P/Pc region of the SC plane Liquid Vapor F. Gorelli et al.; Unpublished (2005)
r(Q,t)=SjeiQRj(t) t ∫ = dt 0 1 Im p MEMORY FUNCTION S(Q,w) D1 -1 [ iw+ [ = D2 S(Q) iw+ D3 iw+ iw+ … THEORETICAL FORMALISM S(Q,w) F(Q,t)=<r*(Q,0)r(Q,t)> Time Fourier Transform dm1(Q,t) dm3(Q,t) dm2(Q,t) dF(Q,t) MEMORY EQUATION m3(Q,t’) m4(Q,t’) m1(Q,t’) m2(Q,t’) m1(Q,t-t’) m3(Q,t-t’) m2(Q,t-t’) F(Q,t-t’) dt’ m2(Q,w)
RELATIVE RELAXATION STRENGTH NH3 H2O N2 Ne
RELATIVE RELAXATION AMPLITUDE H2O NH3 N2 Ne
NEGATIVE DEVIATIONS H2O NH3 N2 Ne
Thermodynamics Microscopic structure (nm) Microscopic dynamics (ps) Liquid Indium Qm r-1/3 S(0) cT Nitrogen cQ <dr2> x-1 LIQUIDS & SUPERCRITICAL FLUIDS Qm~2p/r0
elastic viscous t, relaxation time t >> 2p/w t << 2p/w A (t) A (t) t t VISCOELASTICITY 2p/w P (t) t
RELAXATION TIME (Q-dependence) ta(Q)=ta(0)exp{-AQ}
Tc Tc Tc RELAXATION TIME (T-dependence) ta(0)=t0exp{Ea/kBT} Tc
Tc Tc Tc Tc RELAXATION STRENGTHS D2a=c∞2- cs2