Abstract: The invention proposes several aspects of a Micro-Nano-Micro (MNM) device. According to one aspect, a plurality of observation channels are positioned in parallel, and each has a smaller cross-section in order to generate a disturbance in order to cause preconcentration. The cross-sections of two separate channels are different. According to another aspect, the observation channel has a smaller width, preferably with a constant depth. According to another aspect, a method for analysing and/or distinguishing between and/or sorting analytes is presented. Several types of analytes can be used. According to one aspect, a method for manufacturing a device according to the invention is presented.

Abstract: The present invention relates to a microfluidic analysis device (1) including: a substrate (20) wherein a separation channel (10) is arranged, in which an electrolyte flows, a portion of the separation channel (10) being covered with a polarizable surface (11); two longitudinal field electrodes (8a, 8b) arranged on either side of the separation channel (10); at least one control electrode (6a, 6b) positioned in the separation channel (10), the control electrode (6a, 6b) being suitable for polarizing the polarizable surface (11) so as to control the speed of the electro-osmotic flow in the separation channel (10); the microfluidic analysis device (1) being characterised in that the polarizable surface (11) includes an insulating sub-layer (12) made of amorphous silicon carbide (SiC) and an upper polarizable layer (13) in direct contact with the electrolyte, the control electrodes (6a, 6b) being positioned between the insulating sub-layer (12) and the upper polarizable layer (13).

Abstract: The present invention relates to a microfluidic analysis device (1) including: a substrate (20) wherein a separation channel (10) is arranged, in which an electrolyte flows, a portion of the separation channel (10) being covered with a polarisable surface (11); two longitudinal field electrodes (8a, 8b) arranged on either side of the separation channel (10); at least one control electrode (6a, 6b) positioned in the separation channel (10), the control electrode (6a, 6b) being suitable for polarising the polarisable surface (11) so as to control the speed of the electro-osmotic flow in the separation channel (10); the microfluidic analysis device (1) being characterised in that the polarisable surface (11) includes an insulating sub-layer (12) made of amorphous silicon carbide (SiC) and an upper polarisable layer (13) in direct contact with the electrolyte, the control electrodes (6a, 6b) being positioned between the insulating sub-layer (12) and the upper polarisable layer (13).

Abstract: According to one aspect, the invention relates to an asymmetric MIM type absorbent nanometric structure (1, 1?) intended to receive a wide-band incident light wave the absorption of which is to be optimised within a given spectral band, comprising an absorbent dielectric layer (10) in said spectral band, of subwavelength thickness, arranged between a metal array (11) of subwavelength period and a metal reflector (12).