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Quantum Rotational Dynamics of CH 3 I Group D Y Liu, S Jonas, V Atakan, H Wu, S Omar-Diallo, I-K. Jeong D. Phelan.

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Presentation on theme: "Quantum Rotational Dynamics of CH 3 I Group D Y Liu, S Jonas, V Atakan, H Wu, S Omar-Diallo, I-K. Jeong D. Phelan."— Presentation transcript:

1 Quantum Rotational Dynamics of CH 3 I Group D Y Liu, S Jonas, V Atakan, H Wu, S Omar-Diallo, I-K. Jeong D. Phelan

2 System description Methyl IodideThree fold potential model V3

3 Numerical Values of Energy Level

4 Experimental Goals What we are looking for: 1. The “height”of the V3 well 2. The librational energy 3. The projected radius of Hydrogen from Carbon

5 Why HFBS and FANS? The tunneling energy is quite small Tunneling process have energies on order of ~  eV The HFBS has high resolution. ~1  eV, well below the conventional triple-axis and neutron TOF spectrometers. The FANS has high energy transfer (~100meV)

6 HFBS and FANS diagram:

7 How HFBS works The HFBS varies incident energy by using a cam-based Doppler-driven monochromator. Phase Space Transformer increase flux 4x. Very large analyzer array, 20% of 4  The scattering chamber is operated under vacuum instead of Ar or He improving the signal-to- background ratio.

8 Tunneling Energy: ~2.3  eV V3 ~ 42meV Inelastic Scattering (T = 8K)

9 R exp =1.03A R cal =1.027A Elastic and Quasielastic PeakEISF Fitting Quasielastic Analysis (T = 38K) Jump Diffusion Model:

10 Librational Energy Study by FANS 1 st libration energy: ~14meV

11 Acknowledgement NIST Zema Chowdhuri, Robert Dimeo (HFBS) Craig Brown (FANS) Members of Group D, summer school 2003

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