Times Of Water Shortage Research Articles

Water use and carbon assimilation respond differently to nitrogen supplementation in mid-rotation Eucalyptus nitens

ABSTRACT Large amounts of nitrogen (N) fertiliser are often applied to commercial plantations in southern Australia to obtain high growth rates. The growth response to fertiliser can be realised through increased foliar N and hence improved leaf-level photosynthetic capacity, or through increased leaf area production, which in turn increases light capture and hence canopy-level photosynthesis. While extra leaf area is beneficial to a tree in this regard, extra leaves may also incur costs in terms of both carbon (C) and water. Since canopy water use scales with total leaf area, greater leaf area could cause stomatal closure in times of water shortage, reducing the C assimilation rate. Here, we used three factorial N × phosphorus fertiliser experiments in Eucalyptus nitens plantations across Tasmania, Australia, to assess the effects of 12 fertiliser treatments on C- and water-related gas exchange, foliar N and trunk shrinkage. As prior research in this system has demonstrated an increase in leaf area in response to high N, we investigated the potential physiological costs and benefits of this extra leaf area. N application appeared to have consequences for plant water use, as evidenced by greater trunk shrinkage and lower stomatal conductance. However, this varied by site and year, indicating that the response is dependent on environmental conditions. These results highlight the importance of considering site conditions when prescribing fertiliser application regimes because adding large amounts of N could have unintended consequences for growth due to increased leaf area and hence potential water use, especially in dry conditions.

Shift in the migration trajectory of the green biomass loss barycenter in Central Asia

Revealing the vegetation response law under drought stress has become a hot issue in global climate change research. Against the background of human beings actively responding to climate change, quantitatively revealing the change and migration laws of green biomass loss (GBL) caused by drought in historical and future periods is insufficient. In this regard, we innovatively constructed a joint kNDVI-SPEI (kernel normalized difference vegetation index and standardized precipitation evapotranspiration index) distribution based on copula theory to accurately capture GBL dynamic under various drought scenarios unlike previous studies conducted in a deterministic way. Taking the drought-sensitive and ecologically vulnerable Central Asia (CA) as a typical region, we verified that an average 94.4 % of region showed greater vegetation vulnerability in times of water shortage from May to October, which exhibited the greatest probability of GBL under different drought scenarios, mainly in Kazakhstan and Uzbekistan. Significantly intensified drought due to high emissions will cause an 18.16 percentage-point increase in GBL probability in the far future (FFP, 2061–2100) compared to the near future (NFP, 2019–2060), which is much higher than in the lower-emission (0.38 %) and moderate-emission scenarios (9.82 %). In the NFP, the GBL barycenter will shift from Kazakhstan to Xinjiang, China; in the FFP, it will shift back to Kazakhstan due to the measures taken by the Chinese government to conserve energy and reduce emissions. Results illustrate that against the background of worsening drought, active climate change coping strategies can reverse the migration trajectory of the GBL barycenter caused by drought, which provides a new idea for vegetation protection research in response to global climate change.

The development, implementation and challenges to water-saving practices in a water-stressed destination: a case study of the Songkran Festival, Thailand

PurposeThe contradiction between the purpose of the water-splashing tradition, the use of water in a water-stressed destination and overconsumption during a time of water shortage led the researchers to question the spirit of the Songkran Festival. It is important to keep the spirit of the festival alive without interrupting the livelihoods of the community and to critically engage with opportunities and challenges related to water-saving practices during the festival. Thus, this study aims to investigate the opportunities and challenges to responsible practices of water-saving at a cultural festival, using a case study of the water-splashing practice at the Songkran Festival in Thailand.Design/methodology/approachThis study used the cultural practice, namely, the water-splashing tradition at the Songkran Festival in Thailand, as a case study. The researchers conducted document analysis on local newspapers, the Bangkok Post specifically and participant observation at the Songkran Festival in the Khao San Road area in Bangkok, to gain first-hand insights to develop comprehensive results which answers the study’s objectives.FindingsThe key findings show three significant themes representing the opportunities for implementing sustainable water-saving practices; a call for a water-saving campaign, education on water saving and water-splashing restrictions. In terms of challenges to implementing water-saving practices, two key themes emerged; a lack of water stress and drought awareness and the hedonistic characteristic of water splashing. The study findings provide important implications to theory and practice for sustainable event management and provide considerations for event stakeholders to minimise water overuse in festivals.Originality/valueEnvironmental degradation is a key global issue that the United Nations addresses in the Sustainable Development Goals (SDGs) scheme (United Nations Development Program, 2016). According to Pereira et al. (2009), water scarcity can be caused by both human activities and natural causes. Factors such as unlimited water consumption, population growth and climate change are some of the contributing factors that not only affects resident's access to water but also on events hosted within communities. It is crucial that event managers critically re-think the way festivals are designed in water-stressed destinations.

Unpredictable spillovers among water uses? An analysis of agricultural, industrial, and household uses of water in the Balkans.

In times of water shortage, it becomes increasingly relevant for policymakers to understand the existing relationships between different types of water use, so as to encourage efficient water management. This article makes use of yearly data on agricultural, industrial, and household water use in the Balkan countries of Bulgaria, Romania, and Serbia. It does so to identify the potential interactions among these three categories of water use. Using a deterministic model based on differential equations, we provide an analysis of the interactions among these different sectors of water use for the period between 2008 and 2017. Results show that interactions among these different categories do not remain constant over periods of time, either across or within the countries analysed. We find that, for most countries, industrial and household water uses are more likely to be characterised by mutualism and competition, instead of a predator-prey relationship. Agricultural water use, on the other hand, takes on the role of predator against the other two.

Importance of new method of irrigation of fruit seedlings in the foothills with snow and rain water in times of water shortage

Importance of new method of irrigation of fruit seedlings in the foothills with snow and rain water in times of water shortage

Assessing environmental flows of coordinated operation of dams and weirs in the Geum River basin under climate change scenarios

The International Panel on Climate Change (IPCC) has predicted frequent and severe droughts and floods caused by irregular climatic conditions in the future, making water resources management difficult. Within the field of integrated watershed management, the concept of ‘environmental flow’ is being increasingly studied. In Korea, the Four Major Rivers Restoration Project was carried out as part of the plan to manage future water resources, particularly in response to climate change. In order to improve comprehensive water resources management, there is an interest in integrating into the operation of the existing dams the multi-functional weirs constructed under the said project. To date, there is an absence of studies comprehensively considering climate change, run-off volume, reservoir operations, and environmental flow, with most of the existing studies focusing only on one or the other of these factors. In this study, we presented a method to evaluate the river environment that considers all the said factors. To evaluate how environmental flow is influenced by the changes in river flow due to climate change and hydraulic structure operation, the Streamflow Synthesis and Reservoir Regulation (SSARR) was used as the hydrological model, HEC-ResSim was used as the hydraulic structures operational model, and the Global Environmental Flow Calculator (GEFC) was used as the method to evaluate environmental flows. RCP climate change scenarios, provided by the Climate Change Information Center (CCIC), a branch of the Korea Meteorological Administration, were applied to analyze the future watershed runoff characteristics of the Geum River Basin under different hydraulic structure operation modes. This study concludes that efficient use of water resources can be achieved through the integrated operation of the dams and multi-functional weirs in times of water shortage. Comparing the results of modelling under a no‑carbon reduction scenario on one hand, and a scenario in which emissions were reduced on the other hand, differences were found in flows during floods, in the mean annual runoff ratio in accordance with the environment management class, and in the environmental flow rating. It appears that a new water resources management plan is required to respond to climate change as indicated by the shift of the flow duration curve to a lower environmental management class (EMC) under climate change scenarios.

Farmer’s Perception about Water Demand and Availability in Koga Irrigation Project Under Climate Change

Irrigation is certainly a means for farmers to adapt to climate variability and change. However, the impact of climate change on irrigated agriculture and possible options to deal with it still deserves more research. We therefore assessed farmer‟s perception on climate change and its impact on current and future water management in the Koga irrigation scheme in Lake Tana sub-basin, source of upper Blue Nile River. Farmers in Koga who used to entirely rely on rain fed agriculture stated that the major benefits of the scheme are multiple cropping, increased productions and profits, savings, children‟s school enrollment and in general better livelihoods. Despite these observed benefits more than half of the respondents expressed dissatisfaction with the current water allocation. Farmers are concerned that climate variability and change might exasperate the current water allocation issues. For example, hail strom was cited as one of the major climate stress in the region by 60% of respondent. Seven out of ten respondents felt a change in rainfall pattern (onset and variability) in the past 20 years.Slightly less than half of the farmers believe that temperature has increased over the past two decades. More than half of the farmers anticipate future water shortages due to climate change and sedimentation. Almost all of the respondents do not use other water sources during times of water shortage. The main reasons for not using additional source of water are long distance from river water, and long distance between existing hand dug groundwater wells and cultivated lands. About 38%, 12% and 12% of the respondents suggest respectively digging groundwater wells, rainwater harvesting and improved governance as better strategies to deal with future water shortage. Measures that will solve existing water allocation problems and enable farmers to better deal with the anticipated future water shortages will increase the resilience of the scheme.

Study of the physical and chemical qualities of surface water and groundwater in the upper valley of wadi Rhumel (Eastern Algeria)

Our study region is characterized by a varied age detritus Mio-Plio-Quaternary formations. Some training can be an important groundwater sources (alluvial sand, shell, limestone, gravel). Agriculture in the study area is the first socio-economic activity and the largest consumer of water resources. It is therefore necessary to take into account for effective water management. This may causes a risk of pollution of various kinds: agricultural, industrial, and domestic water overlooked the lack of wastewater treatment plants in the region and that all discharges of sewage are dumped into the river are the Rhumel no prior treatment. Wadi Rhumel water pollution factors are multiple and related primarily to the agricultural vocation of the area, the nature of different domestic and industrial discharges. We note that the discharge of wastewater from the town of Tadjenanet and Chelghoum Laid is at wadi Rhumel, the latter during low water turns into open sewer. In times of water shortage, intensive pumping on the outskirts of the wadi locally generates an immigration of a possible pollution load to groundwater. Two major cities in our study area are located along of wadi Rhumel with an estimated population over 100,000 inhabitants. Both towns have uncontrolled landfills where one is located at the upstream of wadi Rhumel. Faced with this alarming environmental situation and the lack of treatment plants, we contribute to the study of the impact of wastewater on the quality of surface and groundwater through a physicochemical analysis interpretation.

Proportional water sharing vs. seniority-based allocation in the Bow River basin of Southern Alberta

Abstract We analyze the implications of switching from existing seniority-based allocations to proportional water sharing policies in times of water shortage in the Bow River Sub-Basin in Southern Alberta. In particular, we simulate three variations of the proportional water sharing concept: (1) irrigation districts’ permissible diversions are reduced in proportion to each district's licenced allocations; (2) the diversions are reduced in proportion with each district's past five-year average diversions; and (3) the diversions are reduced proportionately with each district's diversion in a single prior year. Compared to the seniority-based allocations, all three alternative policies produce unambiguously better results. With trades, the prospect of overall economic gain improves further. However, the distribution of potential monetary gains varies across scenarios.

<b>ANALISA POTENSI WADUK RUKOH DALAM MEMENUHI KEBUTUHAN AIR DI KABUPATEN PIDIE, INDONESIA</b><br><i>ANALYSIS OF RUKOH RESERVOIR POTENCY FOR DETERMINING WATER REQUIREMENT IN PIDIE DISTRICT, INDONESIA</i>

<em>Generally, reservoir can overcome problem of water availability in particular region. The reservoir collects excess water during rainy season to be used at the time of water shortage during dry season. In Pidie, the largest water sources are from Krueng Baro Geunik and Krueng Tiro. The reservoir is located at Krueng Rukoh with Krueng Tiro as the source of water supply. The reservoir provides water for irrigating and supplying domestic water in Baro (11.950 ha) and Tiro (6.330 ha) areas. There are 13 districts (216718 inhabitants) use the water from this reservoir. Given the population growing at rate of 0.52% then the water demand in the region increases. The aim of study was to estimate the volume of water entering the reservoir using the tank model. Calibration curve between the tank model output and observation data showed good correlation (R<sup>2</sup> = 0.7). The calibrated model was then used to calculate the discharge at Krueng Baro Geunik. A water balance analysis showed that the highest deficit occurred in September and the highest surplus in November. Based on this analysis, the capacity of Krueng Rukoh reservoir is able to fulfill its function assuming the rate of population growth and the irrigation area are constant.</em>

Traditional Farmer-Managed Irrigation System in Central Nigeria

This paper examines the characteristics of a traditional farmer-managed irrigation system in Nigeria, through the presentation of a detailed case study. It documents the development of a traditional irrigation system in the inland valley of the Bida region in central Nigeria and the features of its operation and management. The physical structure and the composition of system users were surveyed in detail. In addition, the characteristics of community management of several irrigation systems in the region were investigated. Farmers were able to mobilize necessary local resources for irrigation development and maintenance although they did this without any external support. The irrigation management institution in the area was highly linked to the local land tenure system. The involvement of landlords in the irrigation community greatly affected the performance of irrigation management. There was no clear definition of water rights. In times of water shortage, water was rotated and shared but water scrambling had become a severe problem in recent years with the higher demand for off-season crops. Irrigation communities were organized informally without tiers of nested organizations. Unfairness in water distribution and contribution to system maintenance existed between top-enders and tail-enders of irrigation canals. Nevertheless, the multi-layered and fragmented land ownership of the region made coordination among different irrigation communities difficult and the unfairness problem could not be solved without institutional changes.

Pilot filtration study to reduce fouling on Marbella seawater RO plant

The seawater RO plant at Marbella had operated intermittently, and at low flowrates, since its construction 10 years ago. This was because the plant had been designed to operate at times of water shortage, to provide water when the conventional supplies were not available.During the early part of the 21st century, the mode of the plant changed, and it was expected to operate at design capacity for most of the time. This brought two facts to light — that during high abstraction rates the intake water quality deteriorated significantly, and that the filtration system that had been installed was not capable of adequately filtering the feed water to make it suitable for feeding to a reverse osmosis plant.The plant was originally built using DuPont B10 permeators. Due to the unavailabilty of these permeators, the plant is currently being converted, stream by stream, to spiral wound membranes supplied by Hydranautics.At design flowrates, the DuPont system fouled rapidly, and required cleaning every two weeks. The spiral trains fouled more slowly, but still required cleaning at a higher frequency than would be considered normal for this type of plant.A pilot filtration plant was installed on site to attempt to find the following;•An optimum coagulant for the water.•An approximate dose rate for that coagulant.•The effect of different media on the quality of filtered water.•The length of run between backwashes using different media.•The quality of water that can be achieved using this coagulant and media.By installing pressure tapping points along the length of the filter, the area of differential pressure could be measured. This was used to ensure depth filtration was taking place, and the foulants were being removed through the length of the bed rather than surface filtration.The trials lasted a total of three months and achieved all of the targets set. The SDI typically achieved by the main plant was approximately 5. The pilot filter showed that the SDI could be reduced to below 2 by modifying the filters and applying a coagulant. Filter runs achieved by the pilot filters were in excess of 48 h.Following the trials, the plant commenced replacing the media in the filtration system, and is expected to install a coagulant dosing system once this was complete.This paper describes the pilot plant built, the selection of the media, and the coagulants used, and presents the operating data produced from the trials.

Comparative response of varied irrigated maize to organic and inorganic fertilizer application

The response of varied irrigated maize (Zea mays) to organic and inorganic fertilizer N, was evaluated at Kasinthula Agricultural Station (2003–2006), Malawi to determine the optimum nutrient and irrigation frequency combinations for soil–water and nutrient management which will address water stress and low soil fertility problem. Hybrid maize variety (DK 8031) was planted on ridges spaced at 0.75 × 0.25 m in a split-plot design replicated three times, with four irrigation frequencies as main plots and fertilizer sources as subplots. Irrigation frequencies comprised: water balance scheduling at 40% depletion, and irrigating 40 mm every 3–4 days, 7 days and 14 days. The nitrogen sources were compost (C), farmyard manure (FYM), urea (U) and their mixtures [(2U:C); (U:2C); (2U:FYM); and (U:2FYM)]. Organic manure was banded three weeks before planting. Data on grain yield was collected and subjected to ANOVA using the Genstat and LSD 0.05 test separating statistical significant means. There was positive ( P < 0.01) and highly significant interactions between maize grain yield, crop water productivity (CWP) and nitrogen use efficiency (NUE). The water balance scheduling at 40% soil moisture depletion had highest grain yields, CWP and NUE among the four irrigation frequencies that was not significantly different to 40 mm every 3–4 days and every 7 days obtained with nitrogen sourced from sole Urea which were not significantly different to mean grain yields, CWP and NUE from (2U:C) and (2U:FYM). CWP was optimally maximised in sole urea (9.8, 8.8 kg mm −1 ha −1) and mixed treatments of 2U:C (8.2, 7.2 kg mm −1 ha −1) or 2U:FYM (8.2–8.9 kg mm −1 ha −1) for maize irrigated every 7 days and at 40% depletion using soil water balance schedule respectively. The greatest NUE of 53.5 kg kg N −1 under (2U:FYM) treatments was experienced at 40% depletion irrigation schedule and was also not significantly different to sole urea and (2U:FYM) treatments (52.8 and 51.6 kg kg N −1) irrigated at 40% depletion and every 3–4 days irrigation schedule respectively. The minimum NUE 19.8 kg kg N −1was observed in FYM treatments irrigated every 14 days. Generally, yields were optimized in the 40% depletion and 40 mm in 7 days in the 2U:C and 2U:FYM treatment. Maize fertilized with sole organic N sources was lowest in CWP and NUE in all irrigation regimes, and exhibited high water dependencies. An increase in irrigation frequency and urea ratio increased maize yield and NUE, while CWP decreased. It can, therefore, be concluded that with adequate water and high inorganic N ratio, there is great potential to facilitate N release from organic matter. In times of water shortage, sole urea can better or more easily be utilized than organic nitrogen sources.

TRANSIENT RESPONSE FUNCTIONS FOR CONJUNCTIVE WATER MANAGEMENT IN THE SNAKE RIVER PLAIN, IDAHO1

ABSTRACT: Increasing demands on western water are causing a mounting need for the conjunctive management of surface water and ground water resources. Under western water law, the senior water rights holder has priority over the junior water rights holder in times of water shortage. Water managers have been reluctant to conjunctively manage surface water and ground water resources because of the difficulty of quantification of the impacts to surface water resources from ground water stresses. Impacts from ground water use can take years to propagate through an aquifer system. Prediction of the degree of impact to surface water resources over time and the spatial distribution of impacts is very difficult. Response functions mathematically describe the relationship between a unit ground water stress applied at a specific location and stream depletion or aquifer water level change elsewhere in the system. Response functions can be used to help quantify the spatial and temporal impacts to surface water resources caused by ground water pumping. This paper describes the theory of response functions and presents an application of transient response functions in the Snake River Plain, Idaho. Transient response functions can be used to facilitate the conjunctive management of surface and ground water not only in the eastern Snake River Plain basin, but also in similar basins throughout the western United States.

Integrated Water Management for the 21st Century: Problems and Solutions

Most of the projected global population increases will take place in third world countries that already suffer from water, food, and health problems. Increasingly, the various water uses (municipal, industrial, and agricultural) must be coordinated with, and integrated into, the overall water management of the region. Sustainability, public health, environmental protection, and economics are key factors. More storage of water behind dams and especially in aquifers via artificial recharge is necessary to save water in times of water surplus for use in times of water shortage. Municipal wastewater can be an important water resource but its use must be carefully planned and regulated to prevent adverse health effects and, in the case of irrigation, undue contamination of groundwater. While almost all liquid fresh water of the planet occurs underground as groundwater, its long-term suitability as a source of water is threatened by nonpoint source pollution from agriculture and other sources and by aquifer depletion due to groundwater withdrawals in excess of groundwater recharge. In irrigated areas, groundwater levels may have to be controlled with drainage or pumped well systems to prevent waterlogging and salinization of soil. Salty drainage waters must then be handled in an ecologically responsible way. Water short countries can save water by importing most of their food and electric power from other countries with more water, so that in essence they also get the water that was necessary to produce these commodities and, hence, is virtually embedded in the commodities. This “virtual” water tends to be a lot cheaper for the receiving country than developing its own water resources. Local water can then be used for purposes with higher social, ecological, or economic returns or saved for the future. Climate changes in response to global warming caused by carbon dioxide emission are difficult to predict in space and time. Resulting uncertainties require flexible and integrated water management to handle water surpluses, water shortages, and weather extremes. Long-term storage behind dams and in aquifers may be required. Rising sea levels will present problems in coastal areas.

Integrated water management: emerging issues and challenges

Most of the projected global population increases will take place in Third World Countries that already suffer from water, food, and health problems. Increasingly, agricultural water management must be coordinated with, and integrated into, the overall water management of the region. Sustainability, public health, and environmental protection are key factors. More storage of water behind dams and especially in aquifers via artificial recharge is necessary to save water in times of water surplus for use in times of water shortage. Municipal wastewater can be an important water resource but its use must be carefully planned and regulated to prevent adverse health effects and, in the case of irrigation, undue contamination of groundwater. While almost all liquid fresh water of the planet occurs underground, its long-term suitability as a source of water is threatened by non-point source pollution from agriculture and by aquifer depletion due to groundwater withdrawals in excess of groundwater recharge. Water short countries can save water by importing most of their food and electric power from other countries with more water, so that in essence they also get the water that was necessary to produce these commodities and, hence, is virtually embedded in the commodities. This ‘virtual’ water tends to be a lot cheaper for the receiving country than developing its own water resources. Local water can then be used for purposes with higher social or economic returns or saved for the future.

A simulation of water allocation policies in times of water shortage

The use of a simulation package to study the consequences of various water allocation policies during time of water shortage is described. The study shows that simulation can be a valuable aid to irrigation scheme managers in their decision making.

PROMOTING AWARENESS OF WATER CONSERVATION IN THE LANDSCAPE

Water conservation is making journal headlines nationwide because of drought, contamination, pollution, and over development. While the idea of xeriscaping began in the Western United States where landscapes can be truly dry, many water-saving principles apply to the Southeast, where home moisture problems and pest problems associated with moisture are a major problem. A year of drought maybe followed by three years of plentiful rainfall, and conditions are significantly different from the semi-arid regions of the country to which most of the present literature on water conservation is directed.The purpose of this project was to provide information on water conservation to designers, landscape industry personnel, and homeowners in the Southeast. This was done by compiling recommendations based on research being conducted by professionals in building science, forestry, horticulture, entomology and landscape architecture.An educational tool addressing the pressing national problem of water conservation with a regional emphasis, this project was designed to help readers increase landscape water efficiency by 30 to 50% while lowering maintenance costs and insuring greater survivability of landscape plants in times of water shortage. Through careful planning and design, economically attractive and aesthetically sound water conserving landscapes can be created.

Water Use and Public Policy in Florida

The interrelations of water use, population growth, and urbanization in the state of Florida are examined. Although the greatest freshwater use is for irrigation, the paper focuses on municipal use because of its projected increase and because it suffers the greatest problems in times of water shortage. Population and municipal water use trends, by county, show the greatest growth in South Florida coastal areas. Projections of water use to the year 2000 follow a similar pattern, with increased urbanization placing growing demands on water. Important policy issues are the ability to provide for future needs and the effectiveness of public policy for dealing with the interrelations of growth and municipal water use. Existing state laws and policies are reviewed, and their adequacy for handling future needs with respect to water use are considered. Water supply policy is being well served by the state's water management districts, but additional efforts must be placed on planning for municipal water shortages.

The mammalian urinary bladder: an accommodating organ.

Summary1. Urinary bladders are found in the amphibia, chelonian reptiles and mammals. In these orders liquid urine is stored in the bladder and eliminated at intervals from the body by micturation.2. In the amphibia and chelonian reptiles, the urinary bladder is a functional extension of the renal tubules. The composition of the urine in the bladder is modified by the active movement of water and ions across the bladder wall, and these transporting processes are under hormonal control. The bladder acts as a water reservoir which can be drawn upon in times of water shortage.3. The mammalian bladder separates two widely differing water phases, namely the urine which is frequently hypertonic to the blood and the tissue fluids which are isotonic. Its function is uniquely one of storage, and no adjustment to the composition of the urine is made by active transport of either water or ions across the bladder wall.4. The epithelium lining the mammalian bladder is the site of the osmotic barrier between urine and tissue fluids. This functional barrier is dependent on the structure of the epithelium and is maintained despite large alterations in the surface area of the epithelium as the bladder rapidly contracts, or slowly dilates.5. The epithelium is of mixed mesodermal and endodermal origin, is transitional in type and is usually 3 or 4 cell‐layers thick. If this urothelium is damaged, it has a high capacity for regeneration and rapidly re‐establishes an intact barrier over the luminal surface.6. The superficial cell layer of this epithelium is composed of large, polyploid, highly differentiated squamous cells which have a long life span. These cells are limited on their free surface by an unusual, angular, semi‐rigid luminal membrane. This membrane is assembled in the Golgi complex.7. The luminal membrane is composed of thickened, discoidal plaques, separated by narrow bands of thinner membrane. When the bladder contracts, the membrane folds along the thinner ‘hinge’ regions, and the rigid discoidal plates invaginate to form fusiform, cytoplasmic vacuoles. The thickened plaques contain a hexagonal lattice of sub‐units, spaced at 14 nm centre‐to‐centre. Each sub‐unit in the lattice is itself composed of 12 smaller particles. These particles may be envisaged as small rods 3 nm in diameter and 12 nm long, and are inserted into matrix from which they project on the luminal face by about 3 nm. Each rod has a central hydrophobic portion separating distal hydrophilic ends.8. The chemical composition of this luminal membrane is unusual. Cerebroside is a major component of the polar lipid fraction and there is an unusually high proline content in the protein fraction. When the mucoproteins are adequately dispersed, and the proteins separated by electrophoresis, a few major proteins are revealed in 33000–80000 dalton range of molecular weight.9. If the normal structure of the luminal membrane is altered, either by physical damage or by failure of the cells to produce it, the barrier function of the epithelium is lost.10. The structure and function of this membrane depend ultimately on its chemical composition. Cerebroside is known to decrease the permeability of lipid bi‐layers to water, but for maximum impermeability a lipid bi‐layer must be maintained in a condensed configuration. The stresses of bladder distension and contraction might be expected to disrupt the bi‐layer, and it is suggested that the function of the rigid plaque regions is to reduce mechanical stresses in the membrane to a minimum. The plaque areas occupy between 73 and 90 % of the membrane surface, and only the remaining 10–27% of the membrane is thus subject to bending and distortion when the bladder contracts or expands. The structure of the plaque areas is probably determined by the nature of the complex proteins which form the sub‐units. Proline is known to confer rigidity on polypeptide chains, and may play an important rôle in ordering the structure of the plaques.11. The bladder epithelium, though normally differentiated as a transitional epithelium, has other biologicai potentialities. It can undergo squamous metaplasia to form a stratified cornified epithelium in response to mechanical irritation and/or vitamin A deficiency. If transplanted from its normal location, it can induce other supporting mesenchyme tissues to lay down bone. When regenerating in response to damage, the newly formed transitional cells can act as phagocytes and engulf and digest damaged or dying cells. In the normal animal the epithelium is largely protected from tumour formation by cell‐mediated immunological surveillance. The defensive mechanisms are triggered by tissue‐type specific antigens which develop in neoplastic bladder epithelial cells.