Powering Up THz Systems with Injection-Locked Amplifiers

For decades, the terahertz (THz) region of the electromagnetic spectrum – roughly 300 GHz to 3 THz – has intrigued researchers with its potential to enable faster wireless communications, ultra-high-resolution spectroscopy, and more precise sensing. Yet, despite a solid understanding of the underlying physics, real-world THz systems have remained elusive. A major challenge has been the lack of THz sources capable of delivering both the output power and spectral purity required for practical applications.

That may be starting to change. Researchers at IMRA America have demonstrated a new THz source architecture that overcomes several long-standing limitations. By combining a resonant tunneling diode (RTD), a photomixed dual-wavelength Brillouin laser, and a low-loss waveguide circulator, the team achieved more than 40 dB of gain at 260 GHz. Just as importantly, they became the first group to characterize the residual phase noise of an injection-locked RTD at this frequency, providing new insight into how high-power, low-noise THz oscillators can be built and scaled.

According to a new publication on the demonstration, 260 GHz was only proof of principle. What matters is that this architecture shows a clear path to combining power and spectral purity at terahertz frequencies, and that’s what makes practical THz systems possible.

From diode to THz oscillator

At the heart of the system is the RTD: a well-established semiconductor device that, when properly biased, can generate radiation in the THz range.

They are like the laser diodes of the terahertz world. They convert electric current directly into high-frequency radiation, and because they’re chip-scale, efficient, and fabricated with standard semiconductor processes, they’re inherently scalable.

RTDs offer strong advantages in size, efficiency, and integration potential. However, they’ve historically struggled with spectral purity. Their output linewidths, often several megahertz, have limited their use in applications that require narrow frequency resolution. These include rotational spectroscopy, high-precision sensing, or next-generation wireless links where clean carrier signals are critical.

Injection-locked amplifier in a waveguide

To overcome the RTD’s limitations in spectral purity, the IMRA team turned to a technique known as injection locking, which enables a lower-purity oscillator to synchronize with a higher-quality reference. In this case, that reference is a dual-wavelength Brillouin laser that’s photomixed to generate a stable THz tone with exceptionally low phase noise.

The study emphasizes that the concept of injection locking is not new, but it is the way the IMRA researchers utilized it that makes it novel. Most previous demonstrations relied on quasi-optical free-space setups. Those introduce significant power loss, alignment sensitivity, and are hard to scale.

The photomixed signal was injected into the RTD, which re-radiated the same frequency but at significantly higher power, functioning as a THz amplifier. This allowed the IMRA team to combine the low noise of the laser with the high output power of the RTD.

A hybrid THz circulator

What made this system practical wasn’t just the injection method, but the physical implementation. The entire signal chain – source, amplifier, and diagnostics – was built with waveguide components. That architecture reduced insertion loss, preserved signal integrity, and delivered stable, repeatable performance. Just as critically, it enabled clean isolation between components, preventing unwanted reflections that can degrade spectral purity or disrupt the injection lock.

As the publication notes, IMRA was the first to do this in a waveguide. That is because in free-space setups, the losses are so high that it makes it nearly impossible to demonstrate amplification. However, with a new THz circulator, IMRA was able to show 40 dB of gain, which was unprecedented at such frequencies.

Traditional Y-junction circulators aren’t viable at most MMW and sub-THz frequencies primarily due to extremely narrow bandwidths, stringent manufacturing tolerances, and material limitations.

The broadband hybrid circulator IMRA utilized was developed by Micro Harmonics. The design combines a Faraday rotator with an orthomode transducer (OMT): both components are inherently broadband and, when properly configured, enable low-loss signal routing across the entire band.

Beyond 260 GHz

Although the proof-of-concept centered on 260 GHz, the IMRA team emphasized that the architecture is scalable to 1 THz and beyond.

As noted in the publication, there is nothing that fundamentally limits the research to 260 GHz. The RTD, the photomixed source, and the waveguide infrastructure can all support operation well above that frequency. If a 1 THz circulator existed today, IMRA could run the same experiment at 1 THz.

The RTD itself, fabricated by ROHM Semiconductor, spans a tuning range of 240–260 GHz and produces up to 40 µW of power in free-running mode. Once injection locked, the team achieved a spectral linewidth narrowing from 5 MHz to less than 1 Hz, enabling precise control over frequency output.

This kind of tunability is vital for real-time signal processing and opens up architectures such as tracking oscillators, where noisy or drifting signals can be amplified, filtered, and stabilized inside the same waveguide loop.

First-ever residual phase noise characterization

In addition to demonstrating signal amplification, the IMRA team performed the first-ever residual phase noise characterization of an injection-locked RTD at THz frequencies.

The results confirmed key trade-offs between gain and bandwidth. As injection power increased, the phase noise dropped by up to 90 dB at 100 Hz offset. But the effective locking range narrowed accordingly. The study quantifies this behavior using theoretical modeling based on the Adler-type injection locking and the oscillator's quality factor (Q ≈ 165).

This level of detail enables researchers to treat the RTD amplifier as a “resonant amplifier”, one that is narrowband but extremely quiet within its range.

Why it matters

Reliable THz sources have applications across a wide swath of industries. In wireless communications, they could unlock ultra-high-speed links or reduce congestion via parallel channelization. In sensing, they’re essential for rotational spectroscopy, molecular clocks, and narrow-linewidth radar.

Until now, the tools to generate these signals with both high power and low noise have been lacking. This shows that with the right architecture, researchers can have both.

Next steps

Looking forward, the IMRA team is exploring ways to push the technology even further via RTD arrays, integrated amplifier designs, and extended frequency operation.

The full study on the patent-pending architecture is now available through the IEEE Journal of Quantum Electronics. 

As high-frequency systems inch closer to mainstream adoption, especially in the context of 6G, compact atomic clocks, or THz imaging, the ability to produce clean, tunable, and powerful THz signals will be essential. With this work, IMRA has provided a concrete step in that direction.