產品詳情
PIXIS相機是普林斯頓科研相機的標準版本;深度半導體制冷、高信噪比,高穩定性依然在詮釋著屬于那一代的工匠精神和榮耀。雖然一直在創新,雖然培育了競爭對手,但是其依然堅守著從紫外到近紅外的定量科學成像和光譜市場。
特征
- 寬波段響應300- 1050nm的靈敏度
- -90℃深度冷卻
- 支持多種光譜和成像
- 支持靈活讀出設計
技術優勢
1. 寬范圍的靈敏度
PIXIS提供大約120 – 1100 nm的最寬波長覆蓋范圍,能夠用于各種廣泛的應用。選定CCDS的量子效率(QE)大于95%,采用紫外線增強型CCD可以在紫外線中獲得較高的量子效率,通過eXcelon?技術增強了靈敏度并減少了Etaloning效應。
2. 獨特的真空技術
PIXIS可利用空氣或液體取得-90℃的深冷溫度,為長曝光時間提供了超低暗電流。單一輸入窗口利用無需維護的操作提供了最大的靈敏度。
3. 利用eXcelon?提高靈敏度
eXcelon?技術提高了PIXIS的靈敏度,提供了更高的量子效率并減少了Etaloning效應。
4. 終極的讀出靈活性
雙放大器讀出設計優化了系統性能。高靈敏度放大器減少了弱信號的讀出噪聲,而高容量放大器則提供了更大的有效動態范圍。
產品參數
探測器型號
| 型號 | 像素尺寸 | 制冷溫度 | 芯片類型 |
| 1024 x 1024 | 13 X 13 μm | -90°C typical; -70°C guaranteed | BRX,BR,BX,B,BUV,F |
| 1340 x 13001340 x 1001340 x 400 | 20 x 20 μm | BRX,BR,BX,B,F | |
| 2048 x 20482048 x 512 | 13.5 X 13.5 μm | BRX,BR,BX,B,BUV,F | |
| 1024 x 256 | 26 x 26 μm | BR,E |
應用案例
1, Control of Ultrafast Non-Linear Interactions in Materials and Plasmonic Nanostructures
Researchers in the lab of Haim Suchowski investigate the non-linear interaction of plasmonic nanostructures with ultrashort laser pulses …Find out more
Eyal Bahar
University of Tel Aviv
2021
2,Improving the Quality of Handheld Raman Spectroscopy with Adaptive Focus Probes
Researchers from Germany have developed a novel set up that uses a liquid lens, alongside a LS-785 spectrometer and PIXIS camera, to dynamically adjust the focus on a handheld Raman spectroscopy system. The improvement of the quality of this system will allow for handheld Raman spectroscopy to be used for multiple biological and clinical applications…Find out more
Jürgen Popp and Iwan Schie
Optics Express
2020
3,Improving the Quality of Handheld Raman Spectroscopy with Adaptive Focus Probes
Researchers from Germany have developed a novel set up that uses a liquid lens, alongside a LS-785 spectrometer and PIXIS camera, to dynamically adjust the focus on a handheld Raman spectroscopy system. The improvement of the quality of this system will allow for handheld Raman spectroscopy to be used for multiple biological and clinical applications…Find out more
Jürgen Popp and Iwan Schie
Optics Express
2020
4,Characterizing Photonic Integrated Circuits with Imaging and Spectroscopy
Collaborators between University of Sydney, Jena and Braunschweig are developing complex photonic integrated circuits using modular design. They have created a plasmonic device that rotates the polarization of an IR beam via incorporated nanofocusing elements…Find out more
C. Martijn de Sterke
Nature Communications
2020
5, Using Emission Spectroscopy to Understand Laser Generated Plasma Filaments
Researchers from the State Key Laboratory of High FIeld Laser Physics investigated the interaction of laser filaments with strong electric fields and optical spectroscopy. This allows them to observe spectral features of plasma ions in high resolution…Find out more
Ruxin Li
AIP Advances
2020