Spectral precision just got a whole lot easier. The pulseSlicer revolutionizes the way you work with ultra-short laser pulses. Say goodbye to limited spectral options and hello to the freedom to cut out the exact spectral range you need. Unlock new possibilities in applications like time-resolved spectroscopy, nonlinear optics, and material processing.
Get ready to slice into the spectral world with unparalleled precision. The pulseSlicer's advanced design allows for spectral cutting of ultra-short laser pulses, narrowing the spectral width from 7 nm to a minuscule 0.35 nm – that's a whopping 20 times reduction! But what does this mean for you? Longer pulses, of course – up to 2700 fs, to be exact. And don't worry about sacrificing power – the transmitted power remains proportional to the available laser input power. By dispersing the pulses spatially and then using a mask to control the spectrum, the pulseSlicer offers an economic and flexible solution for narrowing broadband laser pulses. It's time to take your research to the next level.
Principle of a spectrum slicer: Pulse spectrum of the incident pulses (blue) and pulse spectrum (red) shaped by the spectrum slicer
| pulseSlicer NIR | F25 | F50 | F100 |
| Wavelength range | 650 nm … 1080 nm | ||
| Minimal bandwidth at 1000 nm | 0.11 nm | 0.06 nm | 0.03 nm |
| Static transmission | 50% … 70% between 700 nm … 1050 nm | ||
| Total transmission | Depends on slicing ratio | ||
| pulseSlicer IR | F25 | F50 | F100 |
| Wavelength range | 1000 nm … 1600 nm | ||
| Minimal bandwidth at 1550 nm | 0.17 nm | 0.08 nm | 0.04 nm |
| Static transmission | 50% … 70% between 1050 nm … 1600 nm | ||
| Total transmission | Depends on slicing ratio | ||
| Features for all pulseSlicer models : | |||
| Input beam polarization | Linear, horizontal, polarization rotator optional | ||
| Software and automation | Included | ||
| Remote control | Possible via TCP/IP interface | ||
pulseSlicer Datasheet (pdf / English)
