学术文献库

The scaled-up qubits proposed are molecules which display large amplitude motions at very low temperatures and the matrix that traps them. These comprise ionic solids such as ammonium tetraphenylborate (ATPB) or methane dilute in a xenon matrix. In this manner, an enormous number qubits are present from inception. Each kind of qubit has a multiplicity of transitions of interest which are observed (without the need of external fields, ultra-low temperatures or ultra-high vacuum conditions) using diverse well established experimental techniques at frequencies ranging from 10 to 3300 cm-1. Described in detail are the transitions in ATPB. These include: (i) the IR N-H asymmetric vibration of the ammonium ion qubit which nearly freely rotate about their C3 axes inside the tetraphenylborate matrix. This results in a multi-level vibration-orientation which exhibits multiple bands even at very low temperatures due to nuclear spin freezing between the first three orientation levels. Accessible tunneling frequencies between the orientation levels and the possibility to control inter-qubit distance make this qubit a strong candidate to generate concurrently large entanglement and stable superposition in diverse experimental set-ups; and (ii) the Raman allowed normal modes of the tetraphenylborate anion qubit. These are experimentally resolved from very low temperatures up to 300 K. Further qubit examples and transitions of interest are examined. Experimental setups with multi-crystal arrays, both in a given or several locations, become possible using this approach.