New cross-coupled resonator induced shifted absorption (CRISA) in double microring resonators using a cross-coupling-structure technique

We report, for the first time to the best of our knowledge, a technique that employs ' cross-coupling structure' in the cascaded microring resonators (MRRs) to bring new optical analogues of quantum coherence phenomena. The new configuration resembles a standard double resonator (SDR) but uses cross-coupled-based directional couplers (DCs) instead of the typical direct-coupled-based DCs. One of its unique features is that it does not exhibit the typical SDR's signature quantum coherence analogue effects like coupled-resonator induced transparency (CRIT) or coupled-resonator induced absorption (CRIA). On the contrary, it produces a new very narrow reflection dip positioned at single-pass phase shift theta = - pi/2 which we refer to as cross-coupled resonator induced shifted absorption (CRISA). We compare extensively CRISA's characteristics with the CRIT, CRIA, and Autler-Townes splitting (ATS) found in SDR. The technique opens up new configurations with richer optical behaviours that could find potentially still unexplored applications.