When the evanescent field decays to 1/e of its value at the core-cladding interface, we can get the penetration depth of the evanescent field:dp=��2��n1?|n2r|/n2sin2��i?n22n12(4)Usually, n2r n2, then the penetration depth is mathematically described as:dp=��2��n1sin2��i?n22n12(5)where �� is the wavelength of the light source. As the wavelength becomes larger, the penetration depth increases.3.?Sensing Segment Fabrication3.1. MEMS Microfluidic Channel Chip FabricationConsidering the sensor fabrication process, a cladding segment (2 cm long) of the optical fiber was totally removed to make it the sensing fiber. The hydrofluoric acid wet etch method was adopted in the experiments.
The required diameter of the sensing fiber was less than 8 ��m, which makes it very thin and fragile, hence a microfluidic channel chip based on the micro electromechanical systems (MEMS) technology is presented, which contains a main deep channel in the middle and two microfluidic channels branches in the two sides as inlets and outlets of the analyte solution.Figure 2 illustrates the microchannel chip process based on MEMS technology. The fabrication process is rather simple: (1) a clean (100) n-type single side polished silicon wafer with 380 um thickness was prepared; (2) a 1 ��m thick aluminum layer was deposited by DC magnetron sputter and then a 2 ��m photoresist layer was deposited on it; one side of the silicon wafer lithography was completed utilizing Mask 1, which transferred the pattern onto the photoresist layer; (3) the aluminum layer was patterned by the IBE ion beam etch method; (4) another photoresist layer is deposited and then lithography was done using Mask 2; (5) the photoresist layer was patterned by an inductively coupled plasma ICP process while the aluminum layer was etched about 50 ��m; (6) the photoresist layer was totally removed, then the aluminum layer was still etched by ICP of 200 ��m thickness.
(7) the residual aluminum layer was removed by the wet etching method and the microchannel chip Batimastat was successfully completed, as shown in Figure 3(a).Figure 2.Fabrication process sequence and the mask
Quorum sensing (QS) is a widespread, well-known cell-to-cell communication phenomenon in proteobacteria. QS is used by proteobacteria for the regulation of behaviors such as bioluminescence, biofilm formation, antibiotic production, conjugation and virulence [1�C3]. QS comprises of chemical communication among bacteria involving formation, secretion, detection and reaction to molecules known as autoinducers (AI).