Abstract
Ultraviolet (UV) irradiation has proven an effective tool for inactivating microorganisms in water. There is, however, a need to look at disinfection from a different perspective because microbial inactivation alone may not be sufficient to ensure the microbiological safety of the treated water since pathogenic genes may still be present, even after disinfection. Antibiotic resistance genes (ARGs) are of a particular concern since they enable microorganisms to become resistant to antibiotics. UV irradiation has been widely used for disinfection and more recently for destroying ARGs. While UV lamps remain the principal technology to achieve this objective, UV light emitting diodes (UV-LEDs) are novel sources of UV irradiation and have increasingly been reported in lab-scale investigations as a potential alternative. This review discusses the current state of the applications of UV technology for controlling antibiotic resistance during water and wastewater treatment. Since UV-LEDs possess several attractive advantages over conventional UV lamps, the impact of UV-LED characteristics (single vs combined wavelengths, and operational parameters such as periodic or pulsed and continuous irradiation, pulse repetition frequencies, duty cycle), type of organism, and fluence response, are critically reviewed with a view to highlighting the research needs for addressing future disinfection challenges. The energy efficiency of the reported UV processes is also evaluated with a focus on relating the findings to disinfection efficacy. The greater experience with UV lamps could be useful for investigating UV-LEDs for similar applications (i.e., antibiotic resistance control), and hence identification of future research directions.
Highlights
Ultraviolet (UV) irradiation has proven an effective tool for inactivating microorganisms in water
Disinfection using UV irradiation with a particular focus on controlling antibiotic resistance is reviewed in relation to the potential of UVLEDs as possible alternatives to UV lamps in future applications
The current low output power of UV light emitting diodes (UV-LEDs) and high cost are the main limitations to their application in water and wastewater treatment, significant developments in terms of wall plug efficiency, external quantum efficiency, and output power have been made over the last few years
Summary
UV irradiation is traditionally divided into four regions: UVA (315–400 nm), UVB (280–315 nm), UVC (200–280 nm) and vacuum UV (VUV, 100–200 nm) (Oppenländer, 2007; Phillips, 1983). The UV/chlorine AOP could be more efficient than UV/H2O2 due to the higher molar absorption coefficient and quantum yield (i.e., the ratio of the number of photons emitted to the number of photons absorbed) of UV/HOCl (1.4 ± 0.18 Mol/Es) compared with UV/H2O2 (1.0 Mol/Es) This can reduce the energy requirement for contaminant degradation by 30–75% (Sichel et al, 2011; Watts and Linden, 2007). Mass transfer limitations due to the low solubility of ozone in water and the low efficiency of its photolysis are some of the issues associated with this process (Shu and Huang, 1995) Another AOP that has been investigated widely at lab-scale for disinfection is UV/TiO2.
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