Sustainable water resource management through conjunctive use of groundwater and surface water: a review

“…Connections with outdoor recreation • designing multifunctional areas for climate resilience and recreation [27] • the role of NBSs in shaping multifunctional land use [28] • multifunctional outdoor recreation and flood management in flood-prone areas [29] Sustainability • ways in which water management can improve sustainability [30] • using ecosystem services for greater sustainability [31] • using NBSs for economic sustainability in cities [32] Ecosystem services • using technology to expand ecosystem services [20] • using ecosystem services to support nutrient cycling food supply and resource allocation [33] • ways in which ecosystem services can contribute to sustainability [31] • using ecosystem services for cultural purposes and nature recreation [34] • using ecosystem services for wastewater management [35] • using technology to improve ecosystem services and resilience [36] • using urban and spatial planning to improve or extend the resilience of urban ecosystems (how can we improve ecosystem resilience through urban and spatial planning strategies?) [37] Water management • improving wastewater treatment by using the functions of NBSs [38] • forecasting the quantity of refuse and developing an intelligent system within water treatment facilities to facilitate immediate anticipatory management of sewage treatment [39] • creating an intelligent microgrid for waste management [40] • leveraging the Internet of Things (IoT) for the purpose of effectively handling domestic waste [41] • using ecosystem services for wastewater treatment [42] Mitigate and absorb carbon dioxide • investigating crucial elements in the cultivation of algal biomass and lipids for the generation of sustainable energy sources [43] • predicting future biomass yields of crops [44] • investigating the impact of climate change on carbon flux as a major driver of algal biofuel production [45] • technology potential for carbon uptake from the air and other resources [46] • prediction of renewable energy production [47] • accurate prediction of CO2 emissions [48] Flooding • the floating city and the use of NBSs to improve performance [49] • the role of ecosystem services in mitigating or preventing flooding…”

Nature-Based Solutions and Climate Resilience: A Bibliographic Perspective through Science Mapping Analysis

“…Connections with outdoor recreation • designing multifunctional areas for climate resilience and recreation [27] • the role of NBSs in shaping multifunctional land use [28] • multifunctional outdoor recreation and flood management in flood-prone areas [29] Sustainability • ways in which water management can improve sustainability [30] • using ecosystem services for greater sustainability [31] • using NBSs for economic sustainability in cities [32] Ecosystem services • using technology to expand ecosystem services [20] • using ecosystem services to support nutrient cycling food supply and resource allocation [33] • ways in which ecosystem services can contribute to sustainability [31] • using ecosystem services for cultural purposes and nature recreation [34] • using ecosystem services for wastewater management [35] • using technology to improve ecosystem services and resilience [36] • using urban and spatial planning to improve or extend the resilience of urban ecosystems (how can we improve ecosystem resilience through urban and spatial planning strategies?) [37] Water management • improving wastewater treatment by using the functions of NBSs [38] • forecasting the quantity of refuse and developing an intelligent system within water treatment facilities to facilitate immediate anticipatory management of sewage treatment [39] • creating an intelligent microgrid for waste management [40] • leveraging the Internet of Things (IoT) for the purpose of effectively handling domestic waste [41] • using ecosystem services for wastewater treatment [42] Mitigate and absorb carbon dioxide • investigating crucial elements in the cultivation of algal biomass and lipids for the generation of sustainable energy sources [43] • predicting future biomass yields of crops [44] • investigating the impact of climate change on carbon flux as a major driver of algal biofuel production [45] • technology potential for carbon uptake from the air and other resources [46] • prediction of renewable energy production [47] • accurate prediction of CO2 emissions [48] Flooding • the floating city and the use of NBSs to improve performance [49] • the role of ecosystem services in mitigating or preventing flooding…”

Nature-Based Solutions and Climate Resilience: A Bibliographic Perspective through Science Mapping Analysis

“…In countries with absence of rainfall seasons due to the effects of climate change [62], water management is more important every day [63]. Therefore, surface irrigation or furrow irrigation systems needs to be constantly evaluated and monitored if low infrastructural investments, cost of energy supply and the general cost efficiency is still according to the availability of natural resources to maintain this kind of systems [51].…”

Horticulture Irrigation Systems and Aquaculture Water Usage: A Perspective for the Use of Aquaponics to Generate a Sustainable Water Footprint

“…The importance of water in the contemporary world cannot be overstated, as it plays a crucial role in promoting socioeconomic progress and preserving the environment. Its significance is evident in various aspects of our lives, including agriculture, industry, energy production, and domestic use [ 1 ]. Furthermore, water is essential for maintaining ecological balance and preserving biodiversity, as it supports the survival of diverse plant and animal species.…”

“…Rasifaghihi et al [ 1 ] proposed a technique for predicting water usage through the utilization of Bayesian statistical approaches. The correlation between water usage and air temperature was used to divide observed daily water usage and climate variables into base and seasonal water use through clustering analysis.…”

Hybrid approach for accurate water demand prediction using socio-economic and climatic factors with ELM optimization