UniKLasers的工程平台利用迈克尔逊干涉仪在VBG预先选择的光谱范围内设置的光谱鉴别功能。这抑制了激光腔内除了一个激光纵向模式之外的所有模式。由于功耗显著降低和热管理简化,基于BRaMMS的激光器以非常小的占地面积提供了改进的输出功率可扩展性。
UniKLasers一直在与量子技术中的那些人密切合作,以提供特定波长的定制激光,这些激光与他们希望瞄准的原子跃迁有关,包括UniKLasers的铷的Solo 780.24系列和锶的Solo 698.4系列。UniKLasers的技术确保了在长时间运行或8小时运行期间具有出色的输出功率和波长稳定性。
型号:
698.4 QT Series Laser
320 NX Laser
349 NX Laser
532 Series Laser
640 Series Laser
813.42 QT Series Laser
780.24 QT Series Laser
689.4 QT Series Laser
特征:
Narrow linewidths < 0.5 MHz, with our Quantum Range lasers < 0.3 MHz
Output power stability within 2 % over 8 hours, ± 1.5 °C
Virtually imperceptible power noise below 0.1 % RMS (10 Hz - 10 MHz)
Less than 1 pm of spectral drift over 8 hours, ± 1.5 °C
QT Assemble: Integrated Quantum Technology Programme (QT Assemble)
The QT Assemble project joins 14 UK organisations in their aim to develop faster, more reliable, miniaturised quantum technologies.
The QT Assemble project, led by Fraunhofer’s Centre for Applied Photonics (CAP), will make quantum technology easier to adopt by addressing the challenges of size, weight, power and reliability of systems. Through the development of reliable integrated components and sub-systems, the project goal is to widen current opportunities and open up new markets for navigation, communications, sensing and computing.
In terms of laser development, UniKLasers works to increase Technology Readiness Level (TRL) of its lasers as key components for the emerging commercial QT market, while reducing the cost, power consumption and footprint.
DPSS Laser stabilised at 813nm for Sr Clock Application (LQT813)
Quantum technologies are considered to have a similarly wide and ubiquitous social impact that electronics have enjoyed after the invention of the transistor, but to achieve this it will be necessary to make a vital transition from research labs and large scale installations into industrial and consumer markets. In particular, the development of compact and rugged single-frequency light sources is required by QT to manipulate the quantum states of atoms and ions.
In this project UKRI-supported, we will develop a compact single frequency solid-state laser for controlling quantum states of strontium atoms via light-matter interaction at their near-IR transition at 813nm, using our innovative proprietary technology platform. We will reduce the size and cost of this critical component enormously, without losing performance, in order to place the UK at the vanguard of QT development and commercialisation.
