Diamond film electrode has been known as a material with very wide potential window for water electrolysis which leads to its applicability in numerous electrochemical processes. Its expansive application is even more driven by the possibility of producing synthetic polycrystalline diamond via chemical vapor deposition (CVD), a technique that is operated under low pressure and cost considerably lower compared to previously known High Pressure High Temperature (HPHT) technology. Especially in environmental application, boron-doped diamond (BDD) film electrode finds suitable use in wastewater treatment and heavy metal measurements. High potential window allows BDD film electrode to detect compounds that is oxidized in relatively high anodic potential. A wide potential window for oxygen evolution also permits electrogeneration of oxidants such as hydroxyl radicals from water discharge for pollutants degradation. Nevertheless, the effectiveness of its application is not only determined by intrinsic quality of the film, but also the surface activation process following the fabrication. In this study, after the fabricated boron-doped nanocrystalline diamond (BD-NCD) via hot filament CVD (HFCVD) being thoroughly characterized, its surface activation was conducted by electrochemical polarization. The effect of this treatment on the BD-NCD characteristics and its correlation to the performance in decolorization and Pb(II), Cu(II) and Hg(II) measurement in aqueous solutions were investigated. BD-NCD film with metal-like resistivity characteristics are successfully fabricated via HF-CVD. The grain size distribution of non-faceted nodular 2 µm-thick BD-NCD film is 80.68% within the range of 10–30 nm. Raman shift acquired by multiple excitation wavelength show typical NCD spectra with ID/IG of around 1.36–1.73. Carbon sp3 content is higher in the deeper film; 40% on the surface and 60% at 9 nm-deep. The performance of boron-doped nanocrystalline diamond (BD-NCD) film electrode for decolorization with respect to the surface activation by electrochemical polarization was studied. Anodic polarization found to be more suitable as electrode pretreatment compared to cathodic one. After anodic polarization, the originally H terminated surface of BD-NCD was changed into O terminated, making it more hydrophilic. Due to the oxidation of surface functional groups and some portion of sp2 carbon in the BD-NCD film during anodic polarization, the electrode was successfully being activated showing lower background current, wider potential window and considerably less surface activity compared to the non-polarized one. Consequently, electrooxidation capability of the anodically-polarized BD-NCD to degrade the dye solution was significantly enhanced; capable of nearly total decolorization and COD removal even after several times of re-using. The BD-NCD film electrode favored acidic condition for the dye degradation, and the presence of chloride ion in the solution was found to be more advantageous than sulphate active species. Applying different current density of 10, 20 and 30 mA cm-2, it is found that the higher the current density the faster the decolorization rate. General current efficiency achieved after nearly total decolorization and ~80% COD removal in batch recirculating reactor was around 74% , with specific power consumption of 4.4 kWh m-3 (in terms of volume of solution treated) or 145 kWh kg-1 (in terms of kg COD treated). Dynamic polarization applied on the BD-NCD electrode was proven to enhance its surface properties. The results of XPS analysis show that polarized electrode exhibits diminution of Csp2 and possess minimum adventitious carbon content on its surface. This leads to an increase of electrode kinetic and promotes its capability for Pb, Cu and Hg ions measurements in the aqueous solution using linear sweep voltammetry (LSV) technique without pre concentration step. The linearity of current response with increasing heavy metals concentration in an acetate buffer is ranging from 1 to 22.5 µM for Pb and Cu ions and 1 to 10 µM for Hg ion. The detection limit and sensitivity are 1.339, 0.102 and 0.666 µM, and 0.014, 0.104 and 0.057 µA µM-1 mm-2 for Pb2+, Cu2+ and Hg2+, respectively. The BD-NCD electrode also exhibits capability in simultaneous multi-metals determination although the presence of Cu ion was found to be a disturbance in the system as well. On the other hand, the high content of organics in the real water sample such as lake water also demonstrated to hinder heavy metals measurement. Finally, this study confirms that the BD NCD after undergoing dynamic polarization are capable of direct determination of Pb2+, Cu2+ and Hg2+ ions both individually and simultaneously either in the acetate buffer solution or natural water system, within µM level.