The sub-wavelength focusing ability of Bessel beam may provide us with a way to circumvent the closely interlocked relationship between the depth of focus and the spot size. In addition, Bessel beam may be able to bypass the short focal length associated with the light spot as well as the drawbacks of hard to manipulate light beams in near-field optics based systems. There are many methods proposed to generate Bessel beams in recent years. Ebbesen et al. found that illuminating a metallic film perforated with periodic subwavelength apertures led to unexpected large transmission and directional beaming effect. Following these studies, our research group proposed different structures of optical head. The subwavelength annular aperture SAA proposed in recent years formed the starting point of the research innovations disclosed in this thesis. The SAA optical head can be applied to micro lithography process and laser machining to produce high aspect ratio structures. After the preliminary study of using tapering capillary tube to produce optical head for better transmission the optical head developed in this thesis was fabricated by using non-MEMS process to reduce the cost. 　　The subject of this research work is to fabricate the subwavelength focusing optical head. Started from choosing the material and defining the specification, this thesis discussed the way of tapering and the method adapted to set parameters. Heat melting method was implemented to fabricate the optical head with micron sized tips. The optical head’s inner and outer sides were blocked to ensure the tapered structure can act as a waveguide to couple light beam completely through the optical head. The materials used to cover the capillary were identified by using simulation and the methods were verified by experiment. To ensure the quality of incident and injecting light beams, both ends of the optical head were polished to achieve optical quality. 　　The focusing phenomenon will be discussed first with simulations. These studies use finite-difference time-domain method to do the electromagnetic simulation. Different parameters associated with the optical head were then identified to fabricate the optical head. In this work, light intensity profile experiment and lithography experiment were set up to prove the high depth-of-focus property of the optical head generated Bessel beam. A home-made microscope was used to measure the intensity profile at different distances from the optical head tip. The intensity profile will also be discussed by using simulation results. The lithography experiment developed to perform exposures that led to high aspect ratio hole in AZ4620 photoresist. The method tried to measure these holes will also be discussed in this thesis so as to provide a strong basis for future researchers along the requirements of identifying proper metrology methods.