Abstract
For on-chip interconnects, an ideal light source should have an ultralow energy consumption per bandwidth (operating en-ergy) as well as sufficient output power for error-free detection. Nanocavity lasers have been considered the most ideal for smaller operating energy. However, they have a challenge in obtaining a sufficient output power. Here, as an alternative, we propose an ultrahigh-speed microcavity laser structure, based on a vertical cavity with a high-contrast grating (HCG) mirror for transverse magnetic (TM) polarisation. By using the TM HCG, a very small mode volume and an un-pumped compact optical feedback structure can be realised, which together tailor the frequency response function for achieving a very high speed at low injection currents. Furthermore, light can be emitted laterally into a Si waveguide. From an 1.54-μm optically-pumped laser, a 3-dB frequency of 27 GHz was obtained at a pumping level corresponding to sub-mA. Using measured 3-dB frequen-cies and calculated equivalent currents, the modulation current efficiency factor (MCEF) is estimated to be 42.1 GHz/mA1/2, which is superior among microcavity lasers. This shows a high potential for a very high speed at low injection currents or avery small heat generation at high bitrates, which are highly desirable for both on-chip and off-chip applications.
Highlights
In this Letter, we propose a novel way of tailoring the frequency response, based on the Si-integrated VCL (Si-VCL) structure with a TM HCG reflector
It may enable to achieve a low operating energy, which is desirable for on-chip lasers
It may greatly reduce the heat generation, which is dominated by Joule heating around the active region
Summary
In this Letter, we propose a novel way of tailoring the frequency response, based on the Si-integrated VCL (Si-VCL) structure with a TM HCG reflector. The flattening of response spectrum allows for enhancing the modulation speed (B) at a given 3-dB frequency by diminishing the pulse-to-pulse interactions, called pattern effects. This tailoring enables to achieve a very high speed at low injection levels, resulting in a very high MCEF. An integrated lateral optical feedback structure enables to suppress the relaxation resonance as well as further increasing the 3-dB frequency. The laser sample was characterised by using the optically pumping method. The application potentials of the proposed laser structure and possible issues for electrically pumped versions are discussed
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