The aim of the present work was to develop analytical methods capable of determining mercury species such as methylmercury (CH3Hg), ethylmercury (CH3CH2Hg), inorganic mercury (Hg2+, Hg0), in produced water (PW) and urine, as well as thiomersal C9H9HgNaO2S) in effluent from a pharmaceutical industry and in urine. Despite many methods for quantifying mercury species are reported, few studies address speciation in PW, sample known to have high oil and salt contents. Besides, the use of nanomaterials such as graphene quantum dots (GQDs) alone or decorating titanium dioxide nanoparticles (GQDs-TiO2 NPs) were used as photocatalytic agents to produce the detected elemental mercury. The analytical techniques used for total mercury detection and mercury speciation were multipath cold vapor atomic absorption spectrometry (multipath˗CV˗AAS) and gas chromatography cold vapor atomic fluorescence spectrometry (GC˗CV˗AFS). In the first work, the photo-degradation of thiomersal has been achieved using visible light and GQDs, obtained from hydro-exfoliation of citric acid and glutathione, as catalysts. The generated Hg0 (using adjusted experimental conditions) was detected by multipath-CV-AAS, enabling quantification of thiomersal at values as low as 20 ng L-1 even in complex samples as aqueous effluents from the pharmaceutical industry and in the urine. The reaction kinetic (pseudo-first-order with k = 0.11 min-1 ) was determined. The second work provided a speciation method for mercury in PW using multipath-CV-AAS. Under adjusted salt and oil contents (by dilution and centrifuging), a sample aliquot was treated with SnCl2, leading to the Hg0 quantified as the original inorganic mercury. A second sample aliquot was exposed to UV (under optimized conditions) that promoted oxidation of CH3Hg to Hg2+, which was then reduced, with SnCl2, producing the Hg0 relative to the total mercury content in the sample. The CH3Hg content was obtained by the difference in results achieved for both aliquots. Matrix effects imposed by oil and salt were studied, and although affecting the intensity of the mercury time profile, quantification was successfully achieved by matrix-matched standards containing NaCl and mineral oil.