6.3 By 2030, improve water quality by reducing pollution, eliminating dumping and minimizing release of hazardous chemicals and materials, halving the proportion of untreated wastewater and substantially increasing recycling and safe reuse globally

Graphic displaying the improvement of water quality, wastewater treatment and safe reuse

Related Content

Article

Interview with Dr Khalid Mahmood, Assistant Professor at the University of the Punjab

Could you describe your professional career and/or personal experiences related to space technology and water? Where does your interest in those sectors come from?

I started my research career in 2013, with research interests revolving around various environmental concerns that were deeply rooted in water related issues of Pakistan. Having an educational background in Space Science, it was quite intuitive to possess understanding of the very high potential of applicability of Geospatial technologies in the water sector.

Monitoring River Delta Using Remote Sensing

Since ancient times, people have established communities in river deltas because it provides water, fertile land, and transportation access, making them an ideal place to live. This pattern has been carried forward to the present. With nearly 6 billion people living in river deltas, they are one of the most densely populated places on Earth (Kuenzer and Renaud, 2011). However, they are facing threats such as climate change, sea level rise, land use changes, and ecosystem degradation.

Indicateurs de la Qualité de l'Eau - Vue d'ensemble

Merci à Denis Gringas d'avoir traduit cet article volontairement.

L'eau potable est une ressource précieuse. Elle est à la base de notre vie quotidienne et décide comme aucune autre substance de notre santé et de notre bien-être. Il est donc important de s'assurer que l'eau d'usage quotidien réponde aux critères de qualité les plus élevés. Mais que signifie le terme qualité de l'eau et comment peut-on mesurer et comparer la qualité de l'eau? Cette question sera abordée et expliquée plus en détail dans les sections suivantes.

The advantages of applying space-based technology in monitoring and controlling water hyacinth in aquatic ecosystems

Water hyacinth is a well-known plant that has invaded many aquatic ecosystems around the globe. The fast growing nature of the weed makes it challenging to contain. The weeds’ presence in aquatic bodies results in decreased oxygen and nutrient levels, which threatens aquatic life as well as the productivity and functionality of the whole aquatic ecosystem. This not only causes ecological disturbances but evidently socio-economic challenges arise as well as the weed can be detrimental to health as well as economic activities in many riparian communities worldwide. The use of space-based technology together with modern technologies is of great significance in capturing the weed and identifying its spatial and temporal distribution even in hard to reach places. This helps scientists better understand the weed and how infestation occurs which enables better management and control of the weed.

Monitoring runoff using Earth observation data

When rain falls on Earth, the water starts moving and flowing downhill through sewers and rivers as runoff. Runoff is extremely important to recharge surface water bodies and groundwater. Furthermore, runoff changes the landscape by action of erosion. It is an integral part of the water cycle (Earth Science Data Systems 2021). 

Leveraging space technologies to monitor plastic pollution in oceans

 

Several ongoing projects are trying to detect plastic pollution in oceans by using Space technology

The ocean is where life began. It is home to the majority of the Earth’s plants and animals. However, there is currently another habitant endangering all species living under and above water. Humans included. The habitant is called “Plastic”. Plastic’s largest market is packaging designed for immediate disposal (Sigogneau-Russell, 2003).

Les Avantages de l'Application des Technologies Spatiales dans la Surveillance et le Contrôle de la Jacinthe d'Eau dans les écosystèmes aquatiques

Merci à Mussa Kachunga Stanis d'avoir traduit cet article volontairement.

La résilience d'un socio-écosystème est généralement testée par sa capacité à persister et à maintenir sa fonctionnalité tout en subissant des changements dus à des perturbations. Mais que se passe-t-il lorsque les perturbations sont trop rapides, trop préjudiciables et trop fortes pour qu'un socio-écosystème puisse maintenir sa fonctionnalité ?

The water cycle from space: the central role of satellite-informed models in corporate water management

Water in the atmosphere, in the soil, in rivers and oceans is in continuous exchange via the global water cycle. This is commonly thought to be the circular movement of water that evaporates from the Earth's surface, rises on warm updrafts into the atmosphere, and condenses into clouds. It is transported by the wind as water vapour, and eventually falls back to the Earth’s surface as rain or snow.

Water Quality Indicators – an Overview

Clean drinking water is a precious resource. It is the basis of our daily life and decides like no other substance about our health and well-being. It is therefore important to ensure that the water for everyday use meets the highest quality criteria. But what is meant by the term water quality and how can water quality be measured and compared? This question will be addressed and explained in more detail in the following sections.

Tirer Parti des Technologies Spatiales pour Surveiller la Pollution Plastique dans les Océans

Plusieurs projets en cours tentent  de détecter la pollution plastique dans les océans en utilisant la technologie spatiale.

L’océan est où la vie a commencé. Il abrite la majorité des plantes et des animaux de la Terre. Cependant, il y a actuellement un autre habitant qui met en danger toutes les espèces vivantes sous et au-dessus de l’eau, les humains inclus. Cet habitant est appelé « plastique ». Le plus grand marché du plastique est celui des emballages destinés à l’élimination immédiate (Sigogneau-Russell, 2003).

Interview with Nuredin Teshome Abegaz, Senior Lecturer and PhD candidate at Wollo University

Nuredin Teshome received the Bachelor of Science degree in Physics from Dire Dawa University and the Master of Science degree in Computational Physics from Haramaya University. In support of his bachelor, master studies and his enrolment for PhD studies he received fellowships to carry out research at Botswana International University of Science and Technology (2022-2023). In addition, he also received ‘Advanced Diploma in Data Science with R’, ‘Diploma in Environmental Management’ and ‘Diploma in Environmental Quality Monitoring and Analysis’ from Alison online training platform. From 2016 to 2019 he served as a lecturer and head of the Department of physics at Jigjiga University and he also serves as a lecturer at Wollo University starting from mid-2019. Currently, he is a PhD student at Addis Ababa University (Space Science and Geospatial Institute) in Space and Planetary Science Department.

Interview with Claudia Ruz Vargas, Researcher at IGRAC

Claudia Ruz Vargas is a civil engineer, graduated from the University of Santiago, Chile, with an international master’s degree in Groundwater and Global change. Her master thesis focused on groundwater modelling for recharge and saline intrusion risk assessment under climate change scenarios, in Cape Verde. Claudia has six years of work experience as a project engineer and researcher. She is currently a researcher at the International Groundwater Resources Assessment Centre (IGRAC), where she is involved in projects of high impact on the groundwater sector. In this interview, we talked to her about her career path, and how she has contributed to an improved and more sustainable management of groundwater resources, at a regional and global levels.

Interview with Dr Khalid Mahmood, Assistant Professor at the University of the Punjab

Could you describe your professional career and/or personal experiences related to space technology and water? Where does your interest in those sectors come from?

I started my research career in 2013, with research interests revolving around various environmental concerns that were deeply rooted in water related issues of Pakistan. Having an educational background in Space Science, it was quite intuitive to possess understanding of the very high potential of applicability of Geospatial technologies in the water sector.

Call for abstracts - until 31 August - for the 5th SADC Groundwater conference

The SADC Groundwater Management Institute will host its 5th SADC Groundwater Conference on 16, 17 & 18 November 2022.

The conference is held annually, with the primary objective of providing a platform for the advancement of knowledge sharing on sustainable management of groundwater at national and transboundary levels across SADC Members States

This year the event will be physically held in Windhoek, Namibia with an online participation option.

Interview with Claudia Ruz Vargas, Researcher at IGRAC

Claudia Ruz Vargas is a civil engineer, graduated from the University of Santiago, Chile, with an international master’s degree in Groundwater and Global change. Her master thesis focused on groundwater modelling for recharge and saline intrusion risk assessment under climate change scenarios, in Cape Verde. Claudia has six years of work experience as a project engineer and researcher. She is currently a researcher at the International Groundwater Resources Assessment Centre (IGRAC), where she is involved in projects of high impact on the groundwater sector. In this interview, we talked to her about her career path, and how she has contributed to an improved and more sustainable management of groundwater resources, at a regional and global levels.

Interview with Nuredin Teshome Abegaz, Senior Lecturer and PhD candidate at Wollo University

Nuredin Teshome received the Bachelor of Science degree in Physics from Dire Dawa University and the Master of Science degree in Computational Physics from Haramaya University. In support of his bachelor, master studies and his enrolment for PhD studies he received fellowships to carry out research at Botswana International University of Science and Technology (2022-2023). In addition, he also received ‘Advanced Diploma in Data Science with R’, ‘Diploma in Environmental Management’ and ‘Diploma in Environmental Quality Monitoring and Analysis’ from Alison online training platform. From 2016 to 2019 he served as a lecturer and head of the Department of physics at Jigjiga University and he also serves as a lecturer at Wollo University starting from mid-2019. Currently, he is a PhD student at Addis Ababa University (Space Science and Geospatial Institute) in Space and Planetary Science Department.

Capacity Building and Training Material

Water Quality Assessment

Module

This module consists of four Courses with mainly theoretical background and one Course with a final assignment. Following the DPSIR structure (Driving forces, Pressures, State, Impact and Response), we will look first at some causes and consequences of water pollution and then learn how to measure and evaluate water pollution.

Local Perspectives Case Studies

Project / Mission / Initiative / Community Portal

Socio-groundwater toolbox

To date, hydrological issues are playing a key role in the implementation of the goals in which water has a crosscutting role linked to many other Sustainable Development Goals (SDG’s) set in the 2030 Agenda. According to SDG 6, there is a need to monitor eight different interrelated targets globally. At present, several global tools and initiatives for water monitoring exist. A prerequisite for their implementation is to have a thorough knowledge of the system and a consistent database, usually collected at a country and global scale worldwide.