The design, fabrication, and characterization of novel Si-based sensors based on dual antiresonant reflecting optical waveguides (ARROWs) are proposed. For an ARROW structure, the light is confined within the core layer by antiresonant reflection in the cladding layers and by total internal reflection at the air-core interface. It can guide lightwaves in low-index cores on a high-index substrate, and the refractive index and size of the cores can be flexibly designed to be compatible with single-mode fibers. For dual ARROW, it can operate as a directional coupler or as two decoupled waveguides by controlling maximum coupling efficiency. Based on these structure, Si-based sensors based on dual ARROWs structure without any bending structure can be realized. The characteristics of dual ARROW structures were analyzed with the transfer matrix method (TMM) and the effective index method (EIM). Then, we used the beam propagation method (BPM) to simulate the propagation characteristics of the dual ARROW sensor. The devices were fabricated and characterized. Experimental results show that our Si-based sensors based on dual ARROW structure without any bending structure can be realized.