- #1
Dadface
- 2,489
- 105
Hello
I have been looking at the results published by Kim et Al and am a little bit baffled by one of the graphs shown in fig 4. which shows the single detector counting rate of Do. The rate is very approximately constant across the whole range and averages about 280000 counts per second. Very roughly speaking this is about 10000 bigger than the coincident count.
I'm assuming that the experiment was well shielded from external light but that light was reaching Do from the laser. If that's the case then even in low illumination I would have expected a much higher count rate when compared to the coincident counts, due to the low conversion efficiency of the BBO crystal (about one in ten to the twelve according to Wiki)
I think the biggest problem is that the exact details of the experiment were not published. Can anyone enlighten me please or show me where to look for more details?
Thank you
I have been looking at the results published by Kim et Al and am a little bit baffled by one of the graphs shown in fig 4. which shows the single detector counting rate of Do. The rate is very approximately constant across the whole range and averages about 280000 counts per second. Very roughly speaking this is about 10000 bigger than the coincident count.
I'm assuming that the experiment was well shielded from external light but that light was reaching Do from the laser. If that's the case then even in low illumination I would have expected a much higher count rate when compared to the coincident counts, due to the low conversion efficiency of the BBO crystal (about one in ten to the twelve according to Wiki)
I think the biggest problem is that the exact details of the experiment were not published. Can anyone enlighten me please or show me where to look for more details?
Thank you