READ ME

This text describes the data presented in the paper: Quantum Ferrofluid Turbulence

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Introductory information
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Files included in the data deposit (include a short description of what data are contained): 

Folder: Figure_2

1) area_prop_0_2.csv
2) area_prop_8_2.csv
3) area_prop_m4_2.csv

These data files give the ratio < A_z / A_\perp > as a function of time for the edd values 1) edd=0, 2) edd=0.8, and 3) edd=-0.4 .

Folder: Figure_5

1) LV_trim.csv

This file has 7 columns, which represent the following: 1. time, line length for 2. edd=0, 3. edd=0.8, 4. edd=-0.4, and line length per unit volume for 5. edd=0, 6. edd=0.8, and 7. edd=-0.4 .

Key words used to describe the data:

area proportion, line length

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Methodological information
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A brief method description � what the data is, how and why it was collected or created, and how it was processed:

The data is obtained after an average of five random initial condition simulations for each edd of the dipolar Gross-Pitaevskii equation. 

Instruments, hardware and software used: 

The simulations were performed on Newcastle's HPC service Topsy, using an OpenMP/MPI code written in Fortran

Date(s) of data collection: 

Jan 2017 - Oct 2018

Geographic coverage of data:

N/A

Data validation (how was the data checked, proofed and cleaned):

Comparison to known analytic results of the dipolar Gross-Pitaevskii equation

Overview of secondary data, if used:

N/A

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Data-specific information
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Definitions of names, labels, acronyms or specialist terminology uses for variables, records and their values: 

All acronyms and labels are explained in the main text.

Explanation of weighting and grossing variables: 

N/A

Outline any missing data:

N/A

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Contact
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Please contact rdm@ncl.ac.uk for further information