Masahiro Otaki

Environmental and economic life cycle assessment for sewage sludge treatment processes in Japan

Life cycle assessment for sewage sludge treatment was carried out by estimating the environmental and economic impacts of the six alternative scenarios most often used in Japan: dewatering, composting, drying, incineration, incinerated ash melting and dewatered sludge melting, each with or without digestion. Three end-of-life treatments were also studied: landfilling, agricultural application and building material application. The results demonstrate that sewage sludge digestion can reduce the environmental load and cost through reduced dry matter volume. The global warming potential (GWP) generated from incineration and melting processes can be significantly reduced through the reuse of waste heat for electricity and/or heat generation. Equipment production in scenarios except dewatering has an important effect on GWP, whereas the contribution of construction is negligible. In addition, the results show that the dewatering scenario has the highest impact on land use and cost, the drying scenario has the highest impact on GWP and acidification, and the incinerated ash melting scenario has the highest impact on human toxicity due to re-emissions of heavy metals from incinerated ash in the melting unit process. On the contrary, the dewatering, composting and incineration scenarios generate the lowest impact on human toxicity, land use and acidification, respectively, and the incinerated ash melting scenario has the lowest impact on GWP and cost. Heavy metals released from atmospheric effluents generated the highest human toxicity impact, with the effect of dioxin emissions being significantly lower. This study proved that the dewatered sludge melting scenario is an environmentally optimal and economically affordable method.

Direct and indirect inactivation of microcystis aeruginosa by UV-radiation

Excessive algal growth in drinking water sources like lakes and reservoirs is responsible for filter-clogging, undesirable taste and odor, disinfection-by-product formation and toxin generation. Although various methods are currently being used to control algal bloom, their successes are limited. Some water utilities routinely use copper sulfate to control excessive algal growth. But there is a growing concern against its use mainly because it is non-specific to target algae and kills many non-target species. In this study, the scope of using UV-radiation to control algal growth was assessed using Microcystis aeruginosa as test species. A UV-dose of 75 mW s cm(-2) was found to be lethal to M. aeruginosa. A smaller dose of 37 mW s cm(-2) prevented growth for about 7 days. It was found that UV-radiation may increase the specific gravity of the cells and thus may adversely affect the ability of the cells to remain in suspension. Three days after a UV-dose of 75 mW s cm(-2), almost all the cells settled to the bottom of the incubation tubes, whereas all the unirradiated cells remained in suspension. It was also observed that UV-radiation on algal extracellular products has a significant residual effect and can contribute to algal growth control. The extent of residual effect depends on the UV-dose and can continue even for 7 days. UV-radiation was found to produce H2O2 in the microM level concentration. But at such level, H2O2 itself is not likely to cause the residual effect that was found in this study.

Effects of wastewater disinfection on waterborne bacteria and viruses.

Wastewater disinfection is practiced with the goal of reducing risks of human exposure to pathogenic microorganisms. In most circumstances, the efficacy of a wastewater disinfection process is regulated and monitored based on measurements of the responses of indicator bacteria. However, inactivation of indicator bacteria does not guarantee an acceptable degree of inactivation among other waterborne microorganisms (e.g., microbial pathogens). Undisinfected effluent samples from several municipal wastewater treatment facilities were collected for analysis. Facilities were selected to provide a broad spectrum of effluent quality, particularly as related to nitrogenous compounds. Samples were subjected to bench-scale chlorination and dechlorination and UV irradiation under conditions that allowed compliance with relevant discharge regulations and such that disinfectant exposures could be accurately quantified. Disinfected samples were subjected to a battery of assays to assess the immediate and long-term effects of wastewater disinfection on waterborne bacteria and viruses. In general, (viable) bacterial populations showed an immediate decline as a result of disinfectant exposure; however, incubation of disinfected samples under conditions that were designed to mimic the conditions in a receiving stream resulted in substantial recovery of the total bacterial community. The bacterial groups that are commonly used as indicators do not provide an accurate representation of the response of the bacterial community to disinfectant exposure and subsequent recovery in the environment. UV irradiation and chlorination/dechlorination both accomplished measurable inactivation of indigenous phage; however, the extent of inactivation was fairly modest under the conditions of disinfection used in this study. UV irradiation was consistently more effective as a virucide than chlorination/dechlorination under the conditions of application, based on measurements of virus (phage) diversity and concentration. Taken together, and when considered in conjunction with previously published research, the results of these experiments illustrate several important limitations of common disinfection processes as applied in the treatment of municipal wastewaters. In general, it is not clear that conventional disinfection processes, as commonly implemented, are effective for control of the risks of disease transmission, particularly those associated with viral pathogens. Microbial quality in receiving streams may not be substantially improved by the application of these disinfection processes; under some circumstances, an argument can be made that disinfection may actually yield a decrease in effluent and receiving water quality. Decisions regarding the need for effluent disinfection must account for site-specific characteristics, but it is not clear that disinfection of municipal wastewater effluents is necessary or beneficial for all facilities. When direct human contact or ingestion of municipal wastewater effluents is likely, disinfection may be necessary. Under these circumstances, UV irradiation appears to be superior to chlorination in terms of microbial quality and chemistry and toxicology. This advantage is particularly evident in effluents that contain appreciable quantities of ammonia-nitrogen or organic nitrogen.

Surface water quality and information about the environment surrounding Inle Lake in Myanmar

Inle Lake is the second largest lake in Myanmar and one of the nine key sites for sightseeing there. An analysis of its water quality has not been published before. The objective of this study is to reveal the current situation and find any major problems with the lake. For this purpose, the natural and cultural environments were examined. Some physical and chemical aspects of the surface water were assayed in situ for 2 days in November 2004. The principal ions were analyzed in our laboratory. The main cation and anion species in the lake surface water are Ca2+ and HCO3−. Its high calcium content can be attributed to the limestone of Shan Plateau around the lake. The alkalinity of the lake water was 3829–4114 acid-neutralizing capacity (ANC) (pH 7.8–8.0); it can be attenuated by Ca2+. The concentrations of PO4-P, NO2-N, and NO3-N were relatively high; these could originate from domestic and agriculture uses. The trophic state is eutropic. The concentrations of coliform bacteria indicated that the lake water was unfit to drink, but some people use it for drinking anyway. The bacteria could enter the lake through the direct latrine system used there. The thermal type of the lake is presumed to be warm polymictic. More extensive studies are needed because the lake is thought to be the most changing site in Myanmar as a result of both the tourism boom and increasing agricultural activity.

Effects of photocatalysis on biological decolorization reactor and biological activity of isolated photosynthetic bacteria.

In the treatment of synthetic dye wastewater by photosynthetic bacteria under optical irradiation, excessive algal growth and adhesion on the wall of the reactor has been a severe problem. A laboratory scale flow-through model reactor with thin film photocatalysis for improving the efficiency of optical irradiation and controlling algal adhesion is presented. The system showed the efficiency of continuous biodegradation of dye was improved significantly by thin film photocatalysis. Moreover, the effects of photocatalysis on the color removal activity and the growth of isolated photosynthetic bacteria were investigated in batch experiment. Although photocatalytic reactions of TiO2 could inhibit the growth of isolated photosynthetic bacteria, the negative effects of photocatalysis on photosynthetic bacterial growth and decolorant activity were negligible under UV+FL irradiation. These results implicate the possibility of using thin film photocatalysis for controlling algal adhesion and enhancing the decolorant efficiency of photosynthetic bacteria.

A fate model of pathogenic viruses in a composting toilet based on coliphage inactivation.

A composting toilet using sawdust as a matrix has the potential to trap pathogens that might occasionally be contained in human feces. Therefore, care should be taken when handling the sawdust. It should also be noted that pathogenic viruses tend to have stronger tolerance than pathogenic bacteria. The fates of several species of coliphages, T4, lambda, Qbeta and MS2, in sawdust were investigated as a viral model. The fates of coliphages were significantly different among them, and they changed in response to temperature and the water content of the sawdust. As the results, T4 coliphage had the strongest tolerance and Qbeta had the weakest one in sawdust. It was estimated the days required to decrease virus to a safe level based on a risk assessment. According to the rates of Qbeta and T4, 15 days and 167 days were required respectively for a safe level of infection risk based on actually operated composting toilet condition. Thus, it was significantly different depending on the species and sawdust conditions.

Use of lytic phage to control Salmonella typhi’s viability after irradiation by pulsed UV light

The infectivity rates of Salmonella typhi’s phage was used as a bio-indicator to detect the presence of viable but non cultivable bacteria after irradiation by an increasing number of pulsed UV light. Indeed, the combination of a conventional method used to measure colony-forming ability of UV-irradiated bacteria, and the study of relationship between host bacteria and a suitable phage can reveal the existence of active bacteria which lose the cultivability in usual culture media, but keep viability and phage susceptibility.

Development of a DNA-dosimeter system for monitoring the effects of pulsed ultraviolet radiation

To improve the ultraviolet (UV) water disinfection process and to better understand the impact of the harmful effects of germicidal radiation on the DNA molecule, we have developed a reliable biological monitoring system based on PCR 16S ribosomal DNA (rDNA) and terminal restriction fragment length polymorphism analysis. The PCR analysis was performed using the bacteria-specific 27F and 905R primers to replicate a fragment of the rDNA gene. This new and versatile method can be used to evaluate the effects of direct UV radiation on DNA (UV dose/response) and to estimate the potential of bacteria to mitigate UV lethal effects via photoreactivation and dark repair.

Combined Methods for Quantifying End-Uses of Residential Indoor Water Consumption

This study aims to develop a suitable tool for understanding the end-uses of indoor water consumption (e.g., toilet, kitchen, bathroom, clothes washing) in developing countries. Both direct metering and questionnaire survey were conducted for each end-use in the surrounding areas of Hanoi, Vietnam. We measured the detailed end-uses of residential indoor water, the disaggregation of total consumption of individual household into a number of end-uses, and conducted a detailed questionnaire survey on water use behaviour. A tablet-based questionnaire was used and it proved effective in terms of usability and data collection. The results suggest that the combination of direct metering, questionnaire survey, and toilet tank and shower flow rate measurement is the best method for understanding residential indoor water use.

Fate of Pathogens in Composting Process

Composting toilet has a characteristic that it has possibility to stock pathogens for a while when the patient uses it. Then health hazard aspects must be considered in the case of composting toilet more than water flush type. In this chapter, the typical and important pathogenic microbes relating to composting toilet are introduced. And the fate of model microbes which indicates pathogenic microbes in composting toilet was shown here. The decreasing rate of them depends upon the operating condition. We have to consider what appropriate conditions for enhancing reduction of pathogens are, and the quantitative microorganism risk assessment (QMRA) method is explained here to consider the acceptable risk when we handled the material such as sawdust. Based on QMRA consideration, the required reduction level is revealed, and the appropriate indicator microbes are suggested for monitoring high-tolerant pathogens in compost. In addition, the methods to estimate the inactivation mechanisms of microbes in compost are suggested in this chapter.