Single-led-pumped Maser Advances Solid-State Technology at Room Temperature

The pursuit of low-noise signal sources has led researchers to explore solid-state masers, devices that promise exceptional performance without the need for extreme cooling. Michael Newns, Shirley Xu, and Mingyang Liu, alongside colleagues from Imperial College London, have now achieved a significant breakthrough in this field, demonstrating maser oscillation at room temperature using a remarkably compact, single-LED pump. This innovative approach overcomes a key limitation of previous designs, where the size of the pump source often dictated the overall size of the maser system. By employing a waveguide to deliver light directly into the maser crystal, the team not only miniaturises the device but also enhances its efficiency, achieving a substantial improvement in performance compared to conventional excitation methods.

Their ability to achieve ‘cryogenic’ levels of noise performance while operating at room temperature means optically-pumped, solid-state (OPSS) masers show great promise as quantum sensors, oscillators, and amplifiers. This work demonstrates maser oscillation in a microwave cavity containing a crystal of pentacene-doped para-terphenyl (ptc:ptp) pumped by a single, chip-scale LED. Crucially, the size of the LED pump no longer dominates the overall maser system size, a substantial improvement over previous designs. This miniaturisation is achieved through an invasive pumping technique, embedding a waveguide directly into the maser crystal.

Invasive Pumping of Pentacene Maser Gain Medium

This research details the development of a room-temperature solid-state maser, a significant advancement because traditional masers require cryogenic cooling. The team focuses on using pentacene (and more recently, diazapentacene) doped into para-terphenyl as the gain medium, employing invasive optical pumping to directly illuminate the gain medium with light. This approach allows for a more compact and potentially more efficient maser, operating at zero magnetic field and simplifying design.

Miniature LED Pumps High-Performance Maser Oscillation

This work demonstrates a significant advancement in maser technology, achieving miniaturisation of the optical pump source while maintaining high performance. Scientists successfully demonstrated maser oscillation within a microwave cavity containing a pentacene-doped para-terphenyl crystal, pumped by a single, chip-scale LED. The size of the LED pump no longer dominates the overall maser system size, a substantial improvement over previous designs. This miniaturisation is achieved through an invasive pumping technique, embedding a waveguide directly into the maser crystal, offering at least a two-fold enhancement in cooperativity compared to end-on excitation methods. Measurements reveal a magnetic quality factor, Qm, of approximately 3000, competitive with previously reported ptc:ptp masers.

Room-Temperature Maser Oscillation in Compact Device

This research demonstrates a significant advance in solid-state maser technology, achieving maser oscillation at room temperature within a remarkably small device. By employing a novel invasive pumping technique, where an optical pump is embedded directly into the maser crystal, the team successfully created a system where the pump source does not limit the overall size or weight of the maser. This represents a substantial improvement over previous designs and opens possibilities for more compact and portable applications. The team’s maser, based on a pentacene-doped crystal, exhibits a cooperativity estimated to be around 2, enabling quasi-continuous wave operation. Focusing the pump light onto a smaller area of the crystal, near the region of maximal magnetic flux density, significantly enhances performance, particularly when the total available optical power is limited.

Simulations and experimental results align, confirming the effectiveness of this invasive pumping approach and demonstrating at least a two-fold improvement in cooperativity compared to conventional end-on excitation. Researchers acknowledge that the gain medium is not yet fully utilized, indicating potential for further optimization and performance gains. Future work will focus on developing more advanced optical pumping methods and incorporating more realistic three-dimensional simulations, with the goal of creating even more advantageous devices for a wide range of applications.