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Where and how new industrial paths emerge are much debated questions in economic geography, especially in light of the recent evolutionary turn. This article contributes to the ongoing debate on path creation with a new analytical framework that specifies the formation of generic resources in embryonic industries. It suggests that path creation processes are not only conditioned by preexisting regional capabilities and technological relatedness but also by the way firm and nonfirm actors mobilize and anchor key resources for industry formation. Our framework elaborates on the early industry development phase, extending the focus on regional knowledge spillovers in evolutionary economic geography (EEG) literature with recent insights on industry formation dynamics from innovation studies. It understands early path creation as conditioned by four systemic resource formation processes-knowledge creation, investment mobilization, market formation, and technology legitimation-that can be mobilized both from inside or anchored from outside the region. The use and value of the analytical framework is illustrated by a case study on on-site water recycling technology (OST), based on interviews with 40 experts in three Chinese city regions. The findings suggest that, despite possessing the least favorable initial conditions, a sizable OST industry developed only in Beijing. This is explained based on the specific anchoring process of the four key resources in the early development stage of the industry. Our results imply that EEG would profit from incorporating a broader set of variables than knowledge-based relatedness in explanations of regional industrial path creation.

An Advanced Water Treatment Plant (AWTP) for potable water recycling in Davis Station Antarctica was trialed using secondary effluent at Selfs Point in Hobart, Tasmania, for nine months. The trials demonstrated the reliability of performance of a seven barrier treatment process consisting of ozonation, ceramic microfiltration (MF), biologically activated carbon, reverse osmosis, ultra-violet disinfection, calcite contactor and chlorination. The seven treatment barriers were required to meet the high log removal values (LRV) required for pathogens in small systems during disease outbreak, and on-line verification of process performance was required for operation with infrequent operator attention. On-line verification of pathogen LRVs, a low turbidity filtrate of approximately 0.1 NTU (Nephelometric Turbidity Unit), no long-term fouling and no requirement for clean-in-place (CIP) was achieved with the ceramic MF. A pressure decay test was also reliably implemented on the reverse osmosis system to achieve a 2 LRV for protozoa, and this barrier required only 2–3 CIP treatments each year. The ozonation process achieved 2 LRV for bacteria and virus with no requirement for an ozone residual, provided the ozone dose was >11.7 mg/L. Extensive screening using multi-residue gas chromatography–mass spectrometry (GC–MS) and liquid chromatography–mass spectrometry (LC–MS) database methods that can screen for more than 1200 chemicals found that few chemicals pass through the barriers to the final product and rejected (discharge) water streams. The AWTP plant required 1.93 kWh/m3 when operated in the mode required for Davis Station and was predicted to require 1.27 kWh/m3 if scaled up to 10 ML/day. The AWTP will be shipped to Davis Station for further trials before possible implementation for water recycling. The process may have application in other small remote communities.

Water reuse can contribute to reducing pressures on water resources, as an important approach and practice, reducing the demand for potable water for purposes not requiring high quality water. With water resources being depleted and the demand for water increased, grey water reuse becomes more popular in order to preserve water worldwide. This paper presents a comprehensive review of all significant research and reviews existing case studies to review the present knowledge with respect to the characteristics of grey water. The main summary table covers 63 works that focus on the application of these methods to different fields of sustainable building design. Key fields are reviewed in detail: grey water, including water reuse; grey water recycling; water sustainability; building design optimization; and wastewater of several areas simultaneously, with particular focus on buildings. This research aims to introduce the review of the research that covered the grey water management. Various engineering databases, international journals, and conference proceedings were searched. International journals were searched for relevant research papers. This paper provides perspectives on grey water context in order to frame the breadth and multiple dimensions it encompasses, to summarize recent activities on selected relevant topics, and to highlight possible future directions in research and implementations.

Sustainable water management is a critical challenge in space exploration, where the limited availability of resources requires innovative approaches to ensure astronauts' survival on long‐duration missions. This narrative review explores the key technologies and methods involved in water recycling, in situ resource utilization (ISRU), and bioregenerative life support systems (BLSS) essential for supporting human life in space. The Environmental Control and Life Support System (ECLSS) aboard the International Space Station has demonstrated significant progress in recycling water from urine, sweat, and humidity, achieving up to 93% recovery. However, challenges remain in reducing energy consumption, improving system durability, and ensuring water quality. ISRU technologies, particularly those aimed at extracting water ice from lunar and Martian environments, offer promising solutions for future missions, but they must overcome scalability and logistical hurdles. This review also highlights the potential of nanotechnology and AI‐driven autonomous systems in enhancing water purification and management. Nanomaterials like graphene oxide membranes could revolutionize filtration efficiency, while AI could optimize real‐time water quality monitoring and recycling processes. As space agencies push toward establishing colonies on the Moon and Mars, the development of sustainable, closed‐loop water systems will be pivotal to the success of these missions. Continued research and innovation are essential to ensuring water resources are efficiently managed for long‐term human presence in space.

The mining industry is confronted with substantial challenges in achieving environmental sustainability, particularly regarding water usage, waste management, and dam safety. The increasing global demand for minerals has led to increased mining activities, resulting in significant environmental consequences. By 2025, an estimated 19 billion tons of solid tailings are projected to accumulate worldwide, exacerbating concerns over their management. Tailings storage facilities represent the largest water sinks within mining operations. The mismanagement of water content in tailings can compromise their stability, leading to potential dam failures and environmental catastrophes. In response to these pressing challenges, the mining industry is increasingly turning to innovative solutions such as tailings dewatering and water reuse/recycling strategies to promote sustainable development. This review paper aims to (I) redefine the role of mine tailings and explore their physical, chemical, and mineralogical characteristics; (II) discuss environmental concerns associated with conventional disposal methods; (III) explore recent advancements in dewatering techniques, assessing their potential for water recovery, technical and economic constraints, and sustainability considerations; (IV) and present challenges encountered in water treatment and recycling within the mining industry, highlighting areas for future research and potential obstacles in maximizing the value of mine tailings while minimizing their environmental impact.

Abstract Water resources management under the circumstances of climate change and increasing pressure on natural resources, especially in arid and semi-arid regions, has become an urgent problem. Using Uzbekistan as a case study, this paper addresses reclaiming and recycling nonconventional water as a necessity under the paradigm of water resources management. Information was collected in this study through water source sampling, interviewing farmers and local managers, and studying available documents in three provinces of Fergana, Khorezm, and Bukhara. The findings reveal the high potential of nonconventional water resources, including treated wastewater, brackish water, and agricultural drainage, with a total volume of about 1330 million cubic meters per year. Water quality analysis shows that treated urban wastewater is largely within agricultural standards, and saline groundwater requires management and caution due to high salinity and sodium. However, there have been significant social and economic limitations, including farmers' health concerns and high initial investment, in implementing these solutions. Economic comparisons demonstrate the cost-effectiveness of wastewater treatment technologies compared to brackish water desalination. The results of this study stress the need for coordinated government policies, investment in infrastructure, and extension program implementation to overcome bottlenecks and achieve sustainable water management in Uzbekistan. Resumo A gestão de recursos hídricos em um contexto de mudanças climáticas e crescente pressão sobre os recursos naturais, especialmente em regiões áridas e semiáridas, tornou-se um problema urgente. Utilizando o Uzbequistão como estudo de caso, este artigo aborda a recuperação e a reciclagem de água não convencional como uma necessidade dentro do paradigma da gestão de recursos hídricos. As informações foram coletadas neste estudo por meio de amostragem de fontes de água, entrevistas com agricultores e gestores locais, e estudo de documentos disponíveis em três províncias: Fergana, Khorezm e Bukhara. Os resultados revelam o alto potencial de recursos hídricos não convencionais, incluindo águas residuais tratadas, água salobra e drenagem agrícola, com um volume total de cerca de 1330 milhões de metros cúbicos por ano. A análise da qualidade da água mostra que as águas residuais urbanas tratadas estão, em grande parte, dentro dos padrões agrícolas, e que a água subterrânea salina requer gestão e cautela devido à alta salinidade e ao sódio. No entanto, têm ocorrido limitações sociais e econômicas significativas, incluindo preocupações com saúde dos agricultores e um elevado investimento inicial na implementação destas soluções. As comparações econômicas demonstram a relação custo-eficácia das tecnologias de tratamento de águas residuais em comparação com a dessalinização de água salobra. Os resultados deste estudo sublinham a necessidade de políticas governamentais coordenadas, investimento em infraestruturas e implementação de programas de extensão para superar estrangulamentos e alcançar uma gestão sustentável da água no Uzbequistão.

Climate change and the increase of population pose challenges to ensuring suitable water supply in water-scarce regions. This work presents a comparative analysis of the water-supply approaches adopted in Los Angeles, Southeastern Spain, and Sydney. Results show a decrease in per-capita water use in the period 2000–2020, which reflects an improvement in water conservation. Social factors in the domain of hydropolitics and economic efficiency explain the divergence of water policies adopted. The adaptation to water scarcity and growing population in three regions of developed countries located in different continents sheds light on challenges facing the achievement of water security worldwide.

Water conservation is a critical issue, particularly in arid countries and countries that suffer a lack of natural water resources. Jordan is one of the most water-scarce countries in the world; this fact has forced the search for alternative sustainable solutions. With the support of several regional and international organizations, tens of projects were implemented across the country over the past 30 years that aimed to reuse greywater in rural communities. The current review provides a wide overview of Jordan's experience in greywater treatment and its reuse for non-potable purposes in rural areas. To the best knowledge of the authors, the present review is the first to assess the Jordanian experience in this field. Many governmental authorities and non-governmental organizations have been involved in Jordan's experience. The greywater reuse systems were established to achieve advantageous environmental and socio-economic consequences on the rural communities. The strategy of greywater treatment was based on a local on-site greywater treatment system in households or the so-called ‘autonomous water management’. The applied greywater treatment technologies in households were found efficient in rendering greywater adequate for agricultural uses. However, further improvements and territorial expansion of the experiment are needed.

To meet increasing urban water requirements in a sustainable way, there is a need to diversify future sources of supply and storage. However, to date, there has been a lag in the uptake of managed aquifer recharge (MAR) for diversifying water sources in urban areas. This study draws on examples of the use of MAR as an approach to support sustainable urban water management. Recharged water may be sourced from a variety of sources and in urban centers, MAR provides a means to recycle underutilized urban storm water and treated wastewater to maximize their water resource potential and to minimize any detrimental effects associated with their disposal. The number, diversity and scale of urban MAR projects is growing internationally due to water shortages, fewer available dam sites, high evaporative losses from surface storages, and lower costs compared with alternatives where the conditions are favorable, including water treatment. Water quality improvements during aquifer storage are increasingly being documented at demonstration sites and more recently, full-scale operational urban schemes. This growing body of knowledge allows more confidence in understanding the potential role of aquifers in water treatment for regulators. In urban areas, confined aquifers provide better protection for waters recharged via wells to supplement potable water supplies. However, unconfined aquifers may generally be used for nonpotable purposes to substitute for municipal water supplies and, in some cases, provide adequate protection for recovery as potable water. The barriers to MAR adoption as part of sustainable urban water management include lack of awareness of recent developments and a lack of transparency in costs, but most importantly the often fragmented nature of urban water resources and environmental management.