Neutron Spin Echo Spectroscopy (NSE) Group B Ilir Zoto Tao Hong Yanmei Lan Nikolaos Daniilidis Sonoko Kanai Mitra Yoonesi Zhaohui Sun 2003 Summer School.

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Presentation transcript:

Neutron Spin Echo Spectroscopy (NSE) Group B Ilir Zoto Tao Hong Yanmei Lan Nikolaos Daniilidis Sonoko Kanai Mitra Yoonesi Zhaohui Sun 2003 Summer School NCNR, NIST Gaithersburg, MD 20890

Dynamics of particles NMR (Pulsed Field Gradient)  s and higher Dynamic light scattering  s –ms, nm NSE Time scale ~ ns Size scale Å shape fluctuations Spontaneous curvature, bending elasticity, Diffusion (T, , R k)

Experiment Hydrophobic tail Hydrophilic head Surfactant molecule AOT Experiment I of AOT micelles in C 10 D 22 (5.4 % vol. fraction) Experiment II AOT/D 2 O/C 10 D 22 (5.4/4.6/90 % vol. fraction) Inverse microemulsion droplet D2OD2O C 10 D 22 AOT ~ 25 AOT Inverse spherical micelle C 10 D 22

Principle of NSE n BB sample elastic scattering inelastic scattering Angle 0   0±0± Neutrons posses spin and magnetic moment. They precess in magnetic fields with the Larmor frequency that depends on the strangth of the magnetic field only. (g =1.83  10 8 s -1 T -1 ) B LL S N !

Goal Experiment I AOT micelles in C 10 D 22 Experiment II AOT/D 2 O/C 10 D 22 microemulsion

Results Q

Damping frequency (Hz), a x10 7 Amplitude, D trans (Å 2 /ns)4.2 Mean Radius(Å), R Bending elastic constant, k 0.15k B T Å Å 2 /ns

Conclusion NSE is suitable for studies on: Diffusion of micelles/microemulsion Form Deformation Rg (Å) SANS R H (Å) NSE Micelles Micro Emul ~pcn/mcgraw2/mcglatex.html MicellesKBTKBT AOT (25C)0.15 SOPC (18C)0.9 DAPC (5,6,7C)0.44

Acknowledgement Dobrin P. Bossev, Steve Kline, and Nicholas Rosov NCNR, NIST