**********FIGURE 2**********

Fig2_a_60nm_backgroundcount.csv			col1: Detuning (MHz)
(grey area)					col2: Background counts L = 60 nm

Fig2_a_60nm_rawcount.csv			col1: Detuning (MHz)
(red area)					col2: Background counts + atomic signal L = 60 nm

Fig2_b_250nm_backgroundcount.csv		col1: Detuning (MHz)
(grey area)					col2: Background counts L = 250 nm

Fig2_b_250nm_rawcount.csv			col1: Detuning (MHz)
(blue area)					col2: Background counts + atomic signal L = 250 nm

Fig2_c_60nm_data.csv				col1: Detuning (MHz)
(black points)					col2: Background subtracted counts L = 60 nm

Fig2_c_60nm_fit.csv				col1: Detuning (MHz)
(red line)					col2: Fitted Spectrum L = 60 nm

Fig2_d_250nm_data.csv				col1: Detuning (MHz)
(black points)					col2: Background subtracted counts L = 250 nm

Fig2_d_25nm_fit.csv				col1: Detuning (MHz)
(blue line)					col2: Fitted Spectrum L = 250 nm

**********FIGURE 6**********

Fig_6_a_weighting_AS_on.csv 			col1: cell position (in m)
(Red Dashed line)				col2: relative weighting with AS force present (un-normalised)

Fig_6_a_weighting_AS_off.csv			col1: cell position (in m)
(blue line)					col2: relative weighting without AS force (not normalised)

Fig_6_b_veldist_AS_on.csv			col1: Velocity (m/s)
(Red Dashed line)				col2: Velocity distribution with AS force (not normalised)

Fig_6_b_veldist_AS_off.csv			col1: Velocity (m/s)
(blue line)					col2: Velocity distribution without AS force (not normalised)

Fig_6_b_veldist_bimodal.csv			col1: Velocity (m/s)
(black line)					col2: Bimodal gaussian distribution used by model

Fig_6_b_veldist_MaxBoltz.csv			col1: Velocity (m/s)
(dotted black line)				col2: Maxwell-Boltzmann distribution for a normal (7 cm long) cell



**********FIGURE 7***********

Fig_7_L<insert length here>.csv			col1: Detuning (MHz)
						col2: Normalised Fluorescence

NOTE: length values range from 40 - 250 nm



**********FIGURE 8***********

Fig8_a_Calphacost.csv				col1: Attempted fit values for C_alpha (KHz micrometer^3)
(black points)					col2: Calculated cost value

Fig8_b_alphacost.csv				col1: Attempted fit values for alpha
(black points)					col2: Calculated cost value

Fig8_c_axes.csv					col1: Attempted values of alpha
(black line)					col2: Attempted values of C_alpha (KHz micrometer^3)

Fig8_c_costarray				2d array containing cost values, 
										C_alpha increases from left to right, 
										alpha increases from bottom to top

Fig8_d_alpha_cost.csv				col1: Attempted values of alpha
(black line)					col2: Calculated cost values taken from cost array
										along axis defined by best fit value for alpha 
										highlighted on Fig 8c as vertical blue dashed line
										
Fig8_e_Calpha_cost.csv				col1: Attempted values of C3 (KHz micrometer^3)
(black line)					col2: Calculated cost values taken from cost array
										along axis defined by best fit value for C_alpha 
										highlighted on Fig 8c as horizontal blue dashed line

**********FIGURE 9**********

Fig9_a_Upsilon_Ldep.csv				col1: Length (nm)
						col2: Calculated best fit values (denoted with Upsilon in manuscript)

Fig_9_b_alpha_Ldep.csv				col1: Length (nm)
						col2: Fitted values of alpha


**********FIGURE 10**********

Fig10_a_AS_fit.csv				col1: Detuning (GHz)
(red dashed line)				col2: Fit including AS shift

Fig10_a_data.csv				col1: Detuning (GHz)
(black points)					col2: Normalised Fluorescence counts

Fig10_a_lorentzian.csv			col1: Detuning (GHz)
(blue line)						col2: Lorentzian fitted to blue wing without AS present

Fig10_b_AS_fit.csv				col1: Detuning (GHz)
(red dashed line)				col2: Fit including AS shift, red wing reflected across detuning = 0

Fig10_b_data.csv				col1: Detuning (GHz)
(black points)					col2: Normalised Fluorescence counts

Fig10_b_lorentzian.csv			col1: Detuning (GHz)
(blue line)						col2: Lorentzian fitted to blue wing without AS present