用于钛蓝宝石激光器的OPA
TOPAS是用于钛蓝宝石激光器的飞秒光参量放大器(OPA)系列产品,提供189nm到20μm的连续可调波长、高转换效率、高稳定性输出和完全计算机控制。
TOPAS已在全球范围内安装了2000多套系统,已成为众多科学应用领域的OPA市场领导者。TOPAS可由钛蓝宝石激光器泵浦,脉冲宽度为20fs到200fs,脉冲能量为15μJ到60mJ。可提供超过给定规格的定制解决方案。想了解更多产品细节,请联系 sales@lightcon.com。
| 产品 1) | 泵浦能量 | 泵浦脉宽 | 调谐范围 | 输出脉宽 | 最大重复频率 | 特有功能 |
|---|---|---|---|---|---|---|
 |
0.15 – 5 mJ 2) | 20 – 200 fs | 189 nm – 20 µm | 30 – 150 fs | 20 kHz | 高成本效益 |
 |
5 – 60 mJ 2) | 最高的能量 | ||||
 |
0.15 – 4 mJ 3) | 壳体内含两个OPA | ||||
 |
0.3 – 4 mJ | 240 nm – 10 µm | 1 – 5 ps | 从fs到ps的转换 | ||
 |
0.2 – 5 mJ | 1 – 4 ps | 189 nm – 20 µm | 0.8 – 4 ps | 皮秒级操作 |
- 可提供定制解决方案,详情咨询 sales@lightcon.com。
- 最大的泵浦脉冲能量取决于泵浦脉冲持续时间。
- 对于单个OPA,最大的泵浦脉冲能量取决于泵浦脉冲持续时间。
- 189 nm – 20 μm 可调波长
- 高达 5 mJ 的泵浦能量
- > 25% 转换效率
- 高稳定性输出
- 闲频光 CEP 稳定功能
- 189 nm – 20 μm 可调波长
- 高达 60 mJ 泵浦脉冲能量
- 高达 50% 的转换效率
- 高稳定性输出
- 闲频光 CEP 稳定功能
- 两个独立可调输出光
- 每个通道调谐范围 240 nm – 20 μm
- 转换效率 > 25%
- 高稳定性输出
- 飞秒脉冲转换至 < 20 cm-1 的光谱带宽
- 240 nm – 10 μm 可调波长范围
- 高达 4 mJ 的泵浦能量
- 高稳定性输出
- 1 – 4 ps pulse duration
- 189 nm – 20 μm tuning range
- Up to 5 mJ pump pulse energy
- > 25% conversion efficiency
In-plane oriented CH3NH3PbI3 nanowire suppress the interface electron transfer to PCBM
T. Wang, Z. Yu, H. Huang, W. Kong, W. Dang, and X. Zhao, Chinese Physics B (2021).
An Insight into the Excitation States of Small Molecular Semiconductor Y6
X. Zou, G. Wen, R. Hu, G. Dong, C. Zhang, W. Zhang, H. Huang, and W. Dang, Molecules 18 (25), 4118 (2020).
Carrier Transport Across a CdSxSe1–x Lateral Heterojunction Visualized by Ultrafast Microscopy
D. D. Blach, W. Zheng, H. Liu, A. Pan, and L. Huang, The Journal of Physical Chemistry C 21 (124), 11325-11332 (2020).
Femtosecond streaking in ambient air
A. Korobenko, K. Johnston, M. Kubullek, L. Arissian, Z. Dube, T. Wang, M. Kübel, A. Y. Naumov, D. M. Villeneuve, M. F. Kling et al., Optica 10 (7), 1372 (2020).
Hydrogen Bond Exchange and Ca2+Binding of AqueousN-Methylacetamide Revealed by 2DIR Spectroscopy
O. M. Cracchiolo, D. K. Geremia, S. A. Corcelli, and A. L. Serrano, The Journal of Physical Chemistry B 32 (124), 6947-6954 (2020).
Mechanisms of triplet energy transfer across the inorganic nanocrystal/organic molecule interface
X. Luo, Y. Han, Z. Chen, Y. Li, G. Liang, X. Liu, T. Ding, C. Nie, M. Wang, F. N. Castellano et al., Nature Communications 1 (11) (2020).
Taking a snapshot of the triplet excited state of an OLED organometallic luminophore using X-rays
G. Smolentsev, C. J. Milne, A. Guda, K. Haldrup, J. Szlachetko, N. Azzaroli, C. Cirelli, G. Knopp, R. Bohinc, S. Menzi et al., Nature Communications 1 (11) (2020).
Ultrafast structural changes within a photosynthetic reaction centre
R. Dods, P. Båth, D. Morozov, V. A. Gagnér, D. Arnlund, H. L. Luk, J. Kübel, M. Maj, A. Vallejos, C. Wickstrand et al., Nature 7841 (589), 310-314 (2020).
Efficient Photosensitizing Capabilities and Ultrafast Carrier Dynamics of Doped Carbon Dots
S. Mondal, A. Yucknovsky, K. Akulov, N. Ghorai, T. Schwartz, H. N. Ghosh, and N. Amdursky, Journal of the American Chemical Society 38 (141), 15413-15422 (2019).
High-harmonic generation from an epsilon-near-zero material
Y. Yang, J. Lu, A. Manjavacas, T. S. Luk, H. Liu, K. Kelley, J. Maria, E. L. Runnerstrom, M. B. Sinclair, S. Ghimire et al., Nature Physics 10 (15), 1022-1026 (2019).