Superconductive quantum circuits (SQCs) comprise quantized energy levels that may be coupled via microwave electromagnetic fields. Described in this way, one may draw a close analogy to atoms with internal (electronic) levels coupled by laser light fields. In this Letter, we present a superconductive analog to electromagnetically induced transparency (S-EIT) that utilizes SQC designs of present day experimental consideration. We discuss how S-EIT can be used to establish macroscopic coherence in such systems and, thereby, utilized as a sensitive probe of decoherence.PACS numbers: 42.50.GySuperconductive quantum circuits (SQCs) comprising mesoscopic Josephson junctions can exhibit quantum coherence amongst their macroscopically large degrees of freedom [1]. They exhibit quantized flux and/or charge states depending on their fabrication parameters, and the resultant quantized energy levels are analogous to the quantized internal levels of an atom. Spectroscopy, Rabi oscillation, and Ramsey interferometry experiments have demonstrated that SQCs behave as "artificial atoms" under carefully controlled conditions [2,3,4,5,6,7,8,9]. This Letter extends the SQC-atom analogy to another quantum optical effect associated with atoms: electromagnetically induced transparency (EIT) [10,11]. We propose the demonstration of microwave transparency using a superconductive analog to EIT (denoted S-EIT) in a superconductive circuit exhibiting two meta-stable states (e.g., a qubit) and a third, shorter-lived state (e.g., the readout state). We show that driving coherent microwave transitions between the qubit states and the readout state is a demonstration of S-EIT. We further propose a means to use S-EIT to experimentally probe the qubit decoherence rate in a sensitive manner. The philosophy is similar to that in Ref. 12, where it was proposed to use EIT to measure phase diffusion in atomic Bose-Einstein condensates.The three-level Λ system illustrated in Fig. 1a is a standard energy level structure utilized in EIT [10,11]. It comprises two meta-stable states |1 and |2 , each of which may be coupled to a third excited state |3 . In atoms, the meta-stable states are typically hyperfine or Zeeman levels, while state |3 is an excited electronic state that may spontaneously decay at a relatively fast rate Γ 3 . In an atomic EIT scheme, a resonant "probe" laser couples the |1 ↔ |3 transition, and a "control" laser couples the |2 ↔ |3 transition. The transition coupling strengths are characterized by their Rabi frequencies Ω j3 ≡ −d j3 · E j3 for j = 1, 2 respectively, where d j3 are the dipole matrix elements and E j3 are the slowly varying envelopes of the electric fields. For particular Rabi frequencies Ω j3 , the probe and control fields are effectively decoupled from the atoms by a destructive quantum interference between the states of the two driven transitions. The result is probe and control field transparency [10,11]. In more recent experiments, ultraslow light propagation due to EIT-based refractive index modifications in atomi...
