Photo-detectors have been applied in wide range of applications, such as image sensing, optical communication, environmental monitoring, astronomical studies, spectrometer, and medical therapy. However, large bias voltage, narrowband of sensing spectral and insufficient detection capability limited the practical applications of detectors. In this thesis, some techniques and specific nanostructures were proposed for improving the performances of photodetectors. The first part of thesis was focused on photodetector working in the ultraviolet (UV) range. A KrF excimer laser was used to rapidly anneal and largely improve the crystallinity of zinc oxide (ZnO) film within ultrashallow region, thereby enhancing the photoresponse of ZnO-based photoconductors. Moreover, the laser annealing process has successfully improved the photoresponse of ZnO photoconductor at low power density of 0.38 fW 〖μm〗^(-2) by only applying 10 mV of bias voltage. In the second part of thesis, we combined an aluminum-doped zinc oxide (AZO) film with ZnO nanorods to construct a hybrid anti-reflection of transparent electrode. Since the AZO could form a rectifying Schottky contact with n-type silicon (Si), we fabricate a Schottky photodiode with broadband photoresponse from visible to near-infrared (NIR) regime. The photodetector exhibited high photoelectric conversion efficiency without applying any bias. At the wavelength of 850 nm, the photoresponsivity of detector was 0.59 A/W, and the photovoltage responsivity was 8,200 V/W. Moreover, the photodetector exhibited omnidirectional light-harvesting ability, and the hydrophobic surface of the nanorod based photodetector performed a great self-cleaning ability. In the third part of thesis, we demonstrated an inverse-tapered deep-trench Si structure covering with a continuous thin metal film that can be used a superior photodetector working from the UV to NIR spectral region. This corrugated metal film on Si plays the important role of (1) the conducting electrode of photodetector, (2) large area of three dimensional Schottky junction, and (3) low reflectance of metal film ranging over the UV to NIR regime. The multifunctional structured metal film form a well rectifying Schottky contact with Si substrate, it greatly enhanced the external quantum efficiency of Si in the UV regime up to 60 % and also enhance the corresponding low-light detection capability under zero bias voltage. It is worth to note that this strategy exhibit high responsivity under zero bias voltage, while preserve the advantage of polarization-insensitive detection. The device can be easily fabricated by the mature and low-cost Si-based processes.