﻿README.txt generated on 2022-05-18 by Stefan Spence

GENERAL INFORMATION

1. Title of Dataset: data for the figures in "Preparation of $^{87}$Rb and $^{133}$Cs in the motional ground state of a single optical tweezer"

2. Author Information
	A. Principal Investigator Contact Information
		Name: Simon Cornish
		Institution: Durham University
		Address: Department of Physics, Durham University, South Road, Durham DH1 3LE, United Kingdom
		Email: s.l.cornish@durham.ac.uk

	B. Associate or Co-investigator Contact Information
		Name: Stefan Spence
		Institution: Durham University
		Address: Department of Physics, Durham University, South Road, Durham DH1 3LE, United Kingdom
		Email: s.j.spence@durham.ac.uk

	C. Alternate Contact Information
		Name: Alexander Guttridge
		Institution: Durham University
		Address: Department of Physics, Durham University, South Road, Durham DH1 3LE, United Kingdom
		Email: alexander.guttridge@durham.ac.uk

3. Date of data collection :
From 2021-05-12 to 2022-03-29

4. Geographic location of data collection:
Durham Physics Department, Durham University, UK. 
RbCs optical tweezer experiment

5. Information about funding sources that supported the collection of the data: 
This work was supported by U.K. Engineering and Physical
Sciences Research Council (EPSRC) Grant EP/P01058X/1 and Durham University.

SHARING/ACCESS INFORMATION

1. Licenses/restrictions placed on the data: 
Creative Commons Attribution (CC BY) licence.

2. Links to publications that cite or use the data: 

3. Links to other publicly accessible locations of the data: 
DOI 10.15128/r1f4752g787


DATA & FILE OVERVIEW

File List: 

Fig3a_data.csv
	Temporal profile of the square, Tukey, and Blackman-Harris pulse shapes

Fig3b_data.csv
	Fourier transform of the square, Tukey, and Blackman-Harris pulse shapes

Fig3c_data.csv
	Probability of excitation after applying a pi-pulse with a square, Tukey, or Blackman-Harris pulse profile

Fig4a_data.csv
	Population distribution of motional states before and after applying a Raman pulse on the n-1 sideband

Fig4b_data.csv
	Population distribution of motional states before and after applying a Raman pulse on the n-2 sideband

Fig4c_data.csv
	Population distribution of motional states before and after applying a Raman pulse on the n-3 sideband

Fig4d_data.csv
	Population distribution of motional states before and after applying a Raman pulse on the n-4 sideband

Fig6a_data.csv
	Radial sideband spectroscopy for Cs before and after applying the RSC protocol

Fig6b_data.csv
	Radial sideband spectroscopy for Rb before and after applying the RSC protocol

Fig6c_data.csv
	Axial sideband spectroscopy for Cs before and after applying the RSC protocol

Fig6d_data.csv
	Axial sideband spectroscopy for Rb before and after applying the RSC protocol

Fig7a_data.csv
	Rabi oscillations of Rb in an 814nm tweezer before applying the RSC protocol, fitted with Eq.2

Fig7b_data.csv
	Rabi oscillations of Rb in an 814nm tweezer after applying the RSC protocol, fitted with a damped sine

Fig7c_data.csv
	Rabi oscillations of Rb in a 938nm tweezer after applying the RSC protocol, fitted with a damped sine

Fig8a_data.csv
	Sideband spectroscopy of Rb in trap 0 of a 1D tweezer array after applying the RSC protocol

Fig8b_data.csv
	Sideband spectroscopy of Rb in trap 1 of a 1D tweezer array after applying the RSC protocol

Fig8c_data.csv
	Sideband spectroscopy of Rb in trap 2 of a 1D tweezer array after applying the RSC protocol

Fig8d_data.csv
	Sideband spectroscopy of Rb in trap 3 of a 1D tweezer array after applying the RSC protocol

Fig10a_data.csv
	Sideband spectroscopy of Cs in a 1064nm tweezer after completing the merging routine

Fig10b_data.csv
	Sideband spectroscopy of Rb in a 1064nm tweezer after completing the merging routine

METHODOLOGICAL INFORMATION

1. Description of methods used for collection/generation of data: 
Awaiting publication in New Journal of Physics
https://doi.org/10.48550/arXiv.2205.09457


2. Methods for processing the data: 
The experimental measurements of |f=3> or |f=1> population are the fraction of experimental runs that retain an atom.
The hyperfine spin state is mapped onto the retention probability using a resonant pushout pulse, as mentioned in the main body of the text.

3. Instrument- or software-specific information needed to interpret the data: 
Numerical calculations performed in Python 3.5. 
Simulations of the Raman Hamiltonian use the QuTiP module: https://qutip.org/

4. Standards and calibration information, if appropriate: 

5. Environmental/experimental conditions: 

6. Describe any quality-assurance procedures performed on the data: 

7. People involved with sample collection, processing, analysis and/or submission: 
S Spence, R V Brooks, D K Ruttley, A Guttridge.
