48 lines
1.5 KiB
Python
48 lines
1.5 KiB
Python
r"""
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Four-Point susceptibility
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=========================
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The dynamic four-point susceptibility :math:`\chi_4(t)` is a measure for heterogenous dynamics. [Berthier]_
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It can be calculated from the variance of the incoherent intermediate scattering function
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:math:`F_q(t)`.
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.. math::
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\chi_4 (t) = N\cdot\left( \left\langle F_q^2(t) \right\rangle - \left\langle F_q(t) \right\rangle^2 \right)
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This is astraight forward calculation in mdevaluate.
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First calculate the ISF without time average and then take the variance along the first axis of this data.
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Note that this quantity requires good statistics, hence it is adviced to use a small time window
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and a sufficient number of segments for the analysis.
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Another way to reduce scatter is to smooth the data with a running mean,
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calling :func:`~mdevaluate.utils.runningmean` as shown below.
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.. [Berthier] http://link.aps.org/doi/10.1103/Physics.4.42
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"""
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from functools import partial
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import matplotlib.pyplot as plt
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from src import mdevaluate as md
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import tudplot
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OW = md.open('/data/niels/sim/water/bulk/260K', trajectory='out/*.xtc').subset(atom_name='OW')
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t, Fqt = src.mdevaluate.correlation.shifted_correlation(
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partial(src.mdevaluate.correlation.isf, q=22.7),
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OW,
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average=False,
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window=0.2,
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skip=0.1,
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segments=20
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)
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chi4 = len(OW[0]) * Fqt.var(axis=0)
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tudplot.activate()
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plt.plot(t, chi4, 'h', label=r'$\chi_4$')
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plt.plot(t[2:-2], md.utils.runningmean(chi4, 5), '-', label='smoothed')
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plt.semilogx()
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plt.xlabel('time / ps')
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plt.ylabel('$\\chi_4$')
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plt.legend(loc='best')
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