Replication Data for "Dynamics of purification in Cu2O"

Replication Data for: "Dynamics of purification in Cu2O"<br> <br> Raw and processed data as well as fit results shown in "Dynamics of purification in Cu2O". <br> Rydberg excitons in the semiconductor Cu2O were shown to be highly efficient in neutralizing and screening charged impurities, which is referred to as purification. We investigate the dynamics of this process, using a pump - probe experiment with improved temporal resolution of 15 ns. We analyze the transient absorption of Rydberg excitons and uncover five different physical mechanism that influence it. Further, we compare the impact of excitons and an electron-hole plasma on the purification process. <br> A thorough discussion of the analysis is given in the related publication.<br> <br> Files contain the data shown in figures 2-6 of the publication in ASCII format. No special software needed.<br> The following files include time-resolved transients for a probe laser resonant with the 10P exciton and a pump laser at 16P exciton at varying probe laser powers. <br> <br> Fig 2a<br> The first column contains the time-axis in microseconds. <br> 2nd and 3rd columns contain the amplitude of the change in absorption of 10P (2nd column) and 12P (3rd column) as a function of time (1st column). <br> <br> Fig 2b<br> 1st and 4th columns contain the time-axis in microseconds. <br> 2nd column: Total Amplitude of transients at end of pump pulse in 1/mm:<br> 5th column: Total fit<br> Columns 6 to 10: Amplitude of single relaxation channels as a function of time (4th column). <br> <br> Fig 3a/b<br> The first column contains the time-axis in microseconds. <br> The following columns contain the amplitude of the change in absorption of the probe laser, measured as - \Delta \alpha, in 1/mm for different probe intensities in an increasing order. The probe intensity for each column is given in the third row.<br> <br> Fig 4 a/b<br> The first column contains the time-axis in microseconds. <br> The following columns contain the amplitude of the change in absorption of the probe laser, measured as - \Delta \alpha, in 1/mm for different green laser intensities (above band gap excitation) in an increasing order. The green laser intensity for each column is given in the third row.<br> <br> Fig 3c:<br> First column: Probe laser intensity in mW/cm^2<br> Following columns: Amplitudes of transients at end of pump pulse in 1/mm:<br> 2nd column: Total Amplitude, <br> 3rd and 4th column: A2 and Fit Error, <br> 5th and 6th column: A3 and Fit Error, <br> 7th and 8th column: A4 and Fit Error, <br> 9th and 10th column: A5 and Fit Error, <br> 11th and 12th column: A1 and Fit Error<br> <br> Fig 3d :<br> First column: Probe laser intensity in mW/cm^2<br> Following columns: Decay rates of transients at end of pump pulse in 1/us:<br> 2nd and 3rd column: Rate R2 and Fit Error, <br> 4th and 5th column: R3 and Fit Error, <br> 6th and 7th column: R4 and Fit Error, <br> 8th and 9th column: R5 and Fit Error.<br> <br> Fig 4c:<br> First column: Green intensity in mW/cm^2<br> Following columns: Amplitudes of transients at end of pump pulse in 1/mm:<br> First column: Total amplitude, <br> 2nd and 3rd column: A2 and Fit Error,<br> 4th and 5th column: A3 and Fit Error,<br> 6th and 7th column: A4 and Fit Error, <br> 8th and 9th column: A1<br> <br> Fig 4d:<br> First column: Green intensity in mW/cm^2<br> Following columns: Decay rates of transients at end of pump pulse in 1/us:<br> 2nd column and 3rd: R2 and Fit Error,<br> 4th and 5th column: R3 and Fit Error, <br> 6th and 7th column: R4 and Fit Error<br> <br> Fig 5a<br> 1st column: Sum of absorbed green laser intensity and constant probe laser intensity in mW/cm^2<br> 2nd column: Total amplitude of transients at end of pump pulse in 1/mm as a function of increasing green laser intensity with constant probe laser intensity (1st column). <br> 3rd column: Absorbed probe laser intensity in mW/cm^2<br> 4th column: Total amplitude of transients at end of pump pulse in 1/mm as a function of absorbed probe laser intensity (3rd column). <br> <br> Fig 5b<br> Same as 5a but with A1<br> Fig 5c<br> Same as 5b, but with A2<br> Fig 5d<br> Same as 5c, but with A3<br> Fig 5e<br> Same as 5d, but with A4<br> <br> Fig 6a<br> 1st column: Sum of absorbed green laser intensity and constant probe laser intensity in mW/cm^2<br> 2nd column: Decay rate R2 of transients in 1/us as a function of increasing green laser intensity with constant probe laser intensity (1st column). <br> 4th column: Absorbed probe laser intensity in mW/cm^2<br> 5th column: Decay rate R2 of transients in 1/us as a function of absorbed probe laser intensity (4th column). <br> <br> Fig 6b<br> Same as 6a, but with R3<br> Fig 6c<br> Same as 6a, but with R4<br>