ALBERT

Description: Virtually every coastal country in the world is affected by harmful algal blooms (HABs, commonly called “red tides”). This diverse array of phenomena includes blooms of toxic, microscopic algae that lead to illness and death in humans, fish, seabirds, marine mammals, and other oceanic life. There are also non-toxic HABs that cause damage to ecosystems, fisheries resources, and recreational facilities, often due to the sheer biomass of the accumulated algae. The term “HAB” also applies to non-toxic macroalgae (seaweeds), which can cause major ecological impacts such as the displacement of indigenous species, habitat alteration and oxygen depletion in bottom waters. The frequency, spatial extent, and economic impact of HABs have all expanded in recent decades, in parallel with, and sometimes a result of, the world’s increasing exploitation on the coastal zone for shelter, food, recreation, and commerce. HABs are complex oceanographic phenomena that require multidisciplinary study ranging from molecular and cell biology to large-scale field surveys, numerical modelling, and remote sensing from space. Multi-lateral international programmes and bilateral initiatives are bringing scientists together from different countries and disciplines in a concerted attack on this complex and multi-faceted issue. Our understanding of these phenomena is increasing dramatically, and with this understanding come technologies and management tools that can reduce HAB incidence and impact. More effective HAB management is sure to be one major outcome of the growing investment in the Global Ocean Observing System. HABs will always be with us, and in the next few decades at least, are likely to continue to expand in geographic extent and frequency. Nevertheless, scientifically based management should permit full exploitation of fisheries, recreational, and commercial resources, despite the recurrent and diverse threat that HABs pose. This series of lectures is dedicated to the memory of the noted Danish oceanographer and first chairman of the Commission, Dr Anton Frederick Bruun. The "Anton Bruun Memorial Lectures" were established in accordance with Resolution 19 of the Sixth Session of the IOC Assembly, in which the Commission proposed that important inter-session developments be summarized by speakers in the fields of solid earth studies, physical and chemical oceanography and meteorology, and marine biology.

Description: Published

Description: Refereed

Description: This document has been prepared by Laura Kong, Director International tsunami Information Centre (ITIC). The Tsunami Ready Recognition Programme is an international community-based recognition programme developed by UNESCO/IOC. It aims to build resilient communities through awareness and preparedness strategies that will protect life, livelihoods and property from tsunamis in different regions. In June 2021, the IOC Assembly through IOC Decision A-31/3.4.1 (Warning Mitigation Systems for Ocean Hazards) approved the establishment of the IOC Ocean Decade Tsunami Programme, with the aim of making 100% of communities at risk of tsunami prepared for and resilient to tsunamis by 2030 through the implementation of the UNESCO/IOC Tsunami Ready Recognition Programme and other initiatives. The implementation of the Tsunami Ready Recognition Programme will be a key contribution to achieving the societal outcome ‘A Safe Ocean’ of the Ocean Decade. This document presents the main features of a UNESCO/IOC Tsunami Ready Programme. It is presented to the TT DMP for discussion and approval for recommendation to the TOWS-WG-XV, for the establishment of the programme.

Description: OPENASFA INPUT Working Document from the Meeting of the Inter-ICG Task Team on Disaster Management and Preparedness held online on 21-22 February 2022, Proposal for endorsement by IOC.

Description: Published

Description: Not Known

Description: Six years after the First International Conference on “Water, Megacities and Global Change”, held on the occasion of the 21st United Nations Conference on Climate Change (COP 21), which drew attention to the significant challenges megacities are facing, and proposed the creation of the Megacities Alliance on Water and Climate (MAWAC), UNESCO’s Division of Water Sciences and ARCEAU-IdF1 decided to join forces once again to co-organize the Second International Conference on Water, Megacities and Global Change (EauMega) at UNESCO Headquarters in Paris, France and online on a dedicated platform for the conference, on 11-14 January 2022. Organized in close collaboration with the Greater Paris Metropolis and the Greater Paris Sanitation Authority (SIAAP), and with the support of many other public and private partners, this conference builds on the results of the online Pre-Conference on Water, Megacities and Global Change, which took place in December 2020. The Pre-Conference event, which brought together more than 6,000 participants, helped the organizers identify the issues requiring further consideration during the Second International Conference on Water, Megacities and Global Change by selected scientists, water operators, decision-makers, representatives of basin authorities and civil society at large. Given their size, the challenges posed to Megacities by water management within the context of climate change are of particular importance. Indeed, they raise new and specific issues that require close collaboration between scientists who advance knowledge, operators and basin authorities (public and private) who innovate technically and socio-politically, and local decision-makers who can support new, just and more efficient models of water governance, while remaining in constant interaction with civil society. Following a Call for Papers launched in late 2019, this publication is a compilation of the best scientific articles selected and peer-reviewed by the 87 international experts responsible for designing the scientific programme of the conference. Reflecting the structure of the conference with its 12 thematic sessions, the Proceedings present all the peer-reviewed articles in the following thematic chapters: • Disaster Risk Reduction; • Sustainable Development Goals & Service continuity; • Knowledge of the technical and social conditions; • Governance modalities in megacities; • Holistic water management; • Land issues and challenges; • Planning tools. • Technical and technological solutions; • Innovative initiatives at governance, technical, institutional or social level; • New water culture; • Strengthening of sustainable solidarity; The publication not only provides a state of the art on the challenges that Megacities are facing in their management of water and of the new global changes they encounter, but also presents the latest innovative and multi-disciplinary solutions being used to overcome these challenges and ensure optimal and sustainable resource management. By compiling a collection of experiences and best practices at global level, integrating the following three aspects – megacities, water and global change including climate change – it is our hope that this publication will represent a source of inspiration for other Megacities and large urban centers to overcome similar challenges and strengthen their climate resilience. By promoting fruitful exchanges and synergies among megacities, research institutions, the private sector and civil society at large, as well as inspiring further joint research studies on climate change and water-security related issues, the conference represents without doubt a fundamental building block of the Megacities Alliance on Water and Climate (MAWAC). On behalf of the Conference organizers, we wish to thank the co-conveners and partners of this second major international Conference on Water, Megacities and Global Change, as well as all the authors for their valuable contribution and their recommendations.

Description: Published

Description: Refereed

Description: It is our great pleasure to present the second volume of the Catalogue of Hydrologic Analysis for Asia and the Pacific. This volume focuses on the topic “Dam reservoir operation for addressing water related disasters, water scarcity and quality in Asia and the Pacific”. It contains seven documents from China, Indonesia, Japan, Republic of Korea, Malaysia, Philippines, and Viet Nam. It is the outcome of the international cooperation of the member countries of the Regional Steering Committee for Asia and the Pacific (RSC) under the auspices of the UNESCO Intergovernmental Hydrological Program Phase VIII (IHP-VIII, 2014-2021). It follows the 2020 publication of the Catalogue of Hydrologic Analysis (CHA) Volume 1. The objectives of the publication of the Catalogue of Hydrologic Analysis are: • To promote mutual understanding of hydrology and water resources of the region and of the neighboring countries. • To promote information exchange among different organizations in each country. • To share information on water-related issues such as disaster preparedness, water environment conservation, and water resources management in Asia and the Pacific. In Asia and the Pacific, various hydrologic analysis methods have been applied for designing hydraulic structures and river improvement works for rainfall-runoff predictions, flood inundation mapping and other purposes. These hydrologic analysis methods and experiences have different characteristics in terms of climate, topography, and development history of the catchments in which they are applied. Developing a platform to share these experiences and hydrologic analysis methods strengthen risk estimation and water-related hazard damage reduction; especially for researchers and engineers in the region who have limited knowledge of and experiences with them. To improve this situation and enhance risk estimation ability in research and engineering communities, meetings of the IHP Regional Steering Committee for Asia and the Pacific (RSC-AP) discussed the formation of a research team and the development of a hydro-informatics platform for Asia and the Pacific with the objective of realizing a hydro-hazard resilient region. With the objective enhancing regional capacity for evaluating water-related disaster risks, the RSC-AP decided to develop a Catalogue of Hydrologic Analysis (CHA) as a collaboration among researchers and engineers in Asia and the Pacific. The Catalogue collects documents including experiences and hydrologic analysis methods from practical use to advanced studies for short-term rainfall prediction, rainfall-runoff prediction, flood inundation mapping, hydrologic frequency analysis, eco-hydrology, and more. In this volume, we focus on dam reservoir operation in Asia and the Pacific. Since ancient times, dam reservoirs have aimed at securing water resources for living and agricultural production. Since then, industrial use and hydroelectric power generation were added – and most recently, securing the water environment and mitigating damage caused by floods. Dam operation methods are being studied and operated in each country to meet different objectives and to reduce the impact of flow control on the natural environment. This report summarizes the operation and water resource management of dams in China, Indonesia, Japan, Republic of Korea, Malaysia, Philippines, and Viet Nam. By developing and sharing knowledge through CHA, RSC-AP provides a platform to improve the ability for evaluating water-related disaster risks, which in turn will strengthen cooperation among researchers, governmental agencies and private sectors; serve to reduce the damage of water-related disasters; and stand as a regional contribution to achieve the targets of SDGs, UNESCO IHP-VIII (2014-2021) and UNESCO IHP-IX (2022-2029).

Description: The Ministry of Education, Culture, Sports, Science and Technology (MEXT), Japan, which provides funds to support UNESCO IHP activities in Asia and the Pacific

Description: From the People of Japan

Description: OPENASFA INPUT

Description: Published

Description: Not Known

Description: The Tenth Meeting of the Working Group on Tsunamis and Other Hazards Related to Sea-Level Warning and Mitigation Systems (TOWS-WG-X) was held in Paris, France, on 23-24 February 2017 under the Chairmanship of Mr Alexander Postnov (IOC Vice-Chair). The meeting evaluated progress in actions and decisions taken by the Governing Bodies through IOC-XXVIII/Dec. 8.2 and IOC EC-XLIX/3.4. The Group reviewed reports by the IOC Intergovernmental Coordination Groups as well as its own Task Teams on Disaster Management and Preparedness and Watch Operations. The Group noted with satisfaction the progress made during the intersessional period, including: - Three exercises carried out (CARIBEWave 2016, IOWAVE 2016, PACWAVE 2017) and regular communication tests - Accreditation of four Tsunami Service Providers in the North-Eastern Atlantic, the Mediterranean and Connected Seas Tsunami Warning and Mitigation System (NEAMTWS) - With regards to Tsunami Evacuation Mapping: a) The PTWS successfully completed a Pilot Tsunami Evacuation Maps, Plans and Procedures (TEMPP) over two years in Honduras with regional participation b) The ITIC, CTWP & IOC-UNESCO programme CARIBE EWS built experience with regards to implementation of the TEMPP and are ready to provide guidance to countries that want to implement similar projects c) The Project identified and references existing best practice evacuation mapping guidelines that countries have developed d) The PTWS will finalise project documentation and make it available to ICGs, noting the interest of IOTWMS and CARIBE-EWS  Tsunami Ready Community based performance recognition program achieved in St. Kitts & Nevis and Cedeño (Honduras)  The progress made by DBCP in developing an educational strategy to address buoy vandalism and endorse the development of the strategy and recommend that each ICG review the strategy The Group recommended the Assembly to encourage Member States to - sustain and increase technical and financial support of the tsunami warning systems in their respective regions - further promote tsunami awareness in communities and among authorities through communication and tsunami wave exercises, training, information, and community preparedness and recognition programmes - share Tsunami source scenario data as well sea level data relevant to tsunami detection and alerts - densify sea level networks particularly nearby tsunamigenic sources - extend exercises to community level and include critical infrastructure in exercises (e.g. hospitals, fire stations, police stations, electric power plants, airports, ports and harbors) The Group recommended the Assembly to instruct ICGs - to consider piloting the CARIBE EWS Tsunami Ready guidelines and report back to the TOWS-XI with a view to develop harmonized consistent global guidelines - to advocate the UN designated World Tsunami Awareness Day (5 November) among member states and advise them of the availability of material from the UNISDR in this regard, and share activities and materials with UNISDR and TICs - to recommend TSPs and NTWCs to also use the Common Alerting Protocol (CAP) to facilitate warning messages to be consistently disseminated simultaneously over many warning communication systems to many applications - to recommend TSPs and NTWCs register with international register of alerting authorities through WMO National Permanent Representative - to consider contributing any education or outreach materials related to data buoy vandalism to the DBCP for inclusion in a tool kit of regionally relevant materials to counter vandalism - the ICG/PTWS, in line with the IOC XXVII Assembly decision 8.2, to continue its work on the Key Performance Indicators to cover all aspects of the Tsunami Warning and Mitigation Systems, aligning as closely as possible with the Sendai Framework, and share it to the other ICGs for consideration by the Member States, and report back to TOWS XI with a view to establish global KPIs - to encourage NTWCs disseminate tsunami bulletins to ports, harbours and other maritime authorities within their countries - to share the results of Tsunami exercises and communication tests with WMO to facilitate improved performance of WMO related communication systems The Group recommended the Assembly to take the following actions - to conduct a symposium in early 2018 in Paris on enhancing existing TSP and NTWC operational tsunami forecasting to further develop warning products and enhancing timely, accurate, reliable and effective decision-making and community response, involving experts from monitoring networks, seismology, tsunami forecast modelling and warning centres, maritime authorities, and national and local emergency management authorities with advice on product requirements - to extend the tenure of TOWS and its Task Teams on (i) Disaster Management and Preparedness and (ii) Tsunami Watch Operations, with ToRs as given in IOC Resolution XXIV-4 [for TOWS-WG] and IOC/TOWS-WG-VI/3 [Annex II; for TTDMP] and ToRs for TTTWO to reflect work related to enhancements to the accuracy and effectiveness of tsunami forecast information for users The Group accepted the reports from the Task Teams on Disaster Management and Preparedness and Watch Operations and instructed the Task Team on Watch Operations - to develop in consultation with WWNWS-SC specific tsunami threat messages for vessels at sea - to consider tsunamis generated by non-seismic sources for integration into Tsunami watch operation The Group noted the information presented by the World Meteorological Organization (WMO) on the new developments on the WMO Information System and its use for dissemination of Tsunami alerts as well as WIS performance monitoring of messages and particular types of messages. The Group recommended WMO to explore rendering assistance to CARIBE-EWS concerning usage of GTS and WIS for dissemination of tsunami alerts in the Caribbean region. The Group recognized that the current financial situation strongly limits the implementation of the tasks of the Group, ICGs and Inter-ICG Task Teams and recommended that the Member States to increase their extra-budgetary contributions to the IOC to provide the needed resources for the priorities identified by TOWS-WG and ICGs.

Description: Published

Description: Non Refereed

Description: Dr Nasser Hadjizadeh Zaker, Director of the Iranian National Institute for Oceanography and Atmospheric Science (INIOAS) and Vice Chair of the Intergovernmental Coordination Group for the Indian Ocean Tsunami Warning and Mitigation System (ICG/IOTWMS) sub-regional working group for the North West Indian Ocean (WG-NWIO) welcomed all the participants to the meeting. He mentioned that it is very important to pay attention to the risk of tsunami to the countries of the NWIO from the Makran subduction zone. He acknowledged the contribution of the IOC-UNESCO ICG/IOTWMS in reducing tsunami risk in the region and reminded the Terms of Reference of the WG-NWIO. He wished all the participants a very successful meeting and an enjoyable stay in Iran. Dr Juma Al Maskari, Chair of the ICG/IOTWMS WG-NWIO thanked Dr Zaker and the Iranian government for hosting this meeting in Iran, the ICG/IOTWMS Secretariat for making preparations and all the participants for participating this meeting. He recalled that the WG-NWIO has been set up in the ICG/IOTWMS-X session in March 2015. Dr Al Maskari mentioned that this meeting offers a good opportunity to take stock of the progress made in the inter-sessional period and plan future activities. He concluded by welcoming all participants to the meeting. Dr Srinivasa Kumar Tummala, Head of the ICG/IOTWMS Secretariat welcomed all the participants to the meeting. He recalled that the WG-NWIO was established in the ICG/IOTWMS-X session with initial membership comprising India, Iran, Oman, Pakistan and Yemen to enhance tsunami warning system in the Makran region. He mentioned that the recent earthquake and minor tsunami events in September 2013 and February 2017 in Pakistan serve as a strong reminder that we need to closely study the Makran subduction zone to enhance the technical aspects of tsunami warning as well as awareness and preparedness. He listed the progress made in the inter-sessional period and also informed that this meeting offers a great opportunity to identify priorities in the region and develop a funding proposal for submission to United Nations Economic and Social Commission for Asia and the Pacific (UNESCAP). Dr. Tummala thanked Dr. Zaker and the government of Iran for hosting this important meeting. Dr Mahin Ghazani, Director of Science Department of the Iranian National Commission to UNESCO and Secretary of the Iranian National Committee for Oceanography welcomed all of the participants to the meeting. She informed that the IOC-UNESCO has an overall mandate for ocean science and capacity development in support of the 2030 agenda for Sustainable Development. With strong regional presence, links to other regional bodies and expertise, IOC-UNESCO is rightly placed to support ocean related activities of the 148 Member States. She mentioned that IOC developed strong outreach to support national policy in ocean observations, monitoring ocean health, ocean hazards and emerging ocean issues. Dr. Ghazani listed the contribution of IOC to implementation of Sustainable Development Goals (SDGs) of the United Nations (UN) Agenda 2030. She thanked Dr. Zaker for hosting this important event in Iran and wished the meeting a success.

Description: OpenASFA input

Description: Published

Description: Non Refereed

Description: The coast forms a dynamic, interface zone where the land and sea realms meet and is characterised by some of the world’s most sensitive ecosystems, such as mangroves, wetlands, coral reefs, dunes and beaches. Unlike watersheds, coastal areas have no natural, clear nor precise boundaries. They are subjected continuously to the natural processes of weathering, coastal erosion, coastal flooding and sea-level rise. The impacts of these processes and events vary from one coastal zone to another depending on the geology and geomorphology of the coast and its exposure to natural processes. As the interface between land and sea, coastal areas perform many essential functions like natural protection against storms, regulation of water exchange between land and sea, regulation of the chemical composition of sediments and water, storage and recycling of nutrients and maintenance of biological and genetic diversity. From socio-economic perspectives, coastal zones are important settlement areas which play a critical role in the wealth creation of many nations as they offer access to fisheries and commerce, proximity to rich agricultural lowlands, aesthetic landscapes as well as cultural and recreational opportunities.

Description: OpenASFA input

Description: Published

Description: Refereed

Description: • Harmful Algal Blooms (HABs) result from noxious and/or toxic algae that cause direct and indirect negative impacts to aquatic ecosystems, coastal resources, and human health. • HABs are present in nearly all aquatic environments (freshwater, brackish and marine), as naturally occurring phenomena. • Many HABs are increasing in severity and frequency, and biogeographical range. Causes are complex, but in some cases can be attributed to climate change and human impacts, including eutrophication, habitat modification, and human- mediated introduction of exogenous species. • There is no plan, and nor realistic possibility, to eliminate HABs and/or their depend-ent consequences. Decades of research and monitoring have, however, improved our understanding of HAB events, leading to better monitoring and prediction strate-gies. • HABs are a worldwide phenomenon requiring an international understanding leading ultimately to local and regional solutions. Continued progress in research, management, mitigation, and prediction of HABs benefits from international coordination. In this spirit, the international community has developed programmes sponsored by the Intergovernmental Oceanographic Commission (IOC) and Scientific Committee on Oceanic Research (SCOR) to coordinate international HAB research, framework activities, and capacity building. • HABs are recognized as one facet of complex ecosystem interactions with human society. HAB research, monitoring, and management must be closely integrated with policy decisions that affect our global oceans. • New initiatives, such as GlobalHAB sponsored by IOC and SCOR, will continue to provide the mechanisms to further understand, predict, and mitigate HABs. Research, management, and mitigation efforts directed towards HABs must be coordinated with other local, national, and international efforts focused on food and water security, human and ecosystem health, ocean observing systems, and climate change.

Description: OPENASFA INPUT For bibliographic purposes this document should be cited as: R.M. Kudela et al. 2015. Harmful Algal Blooms. A Scientific Summary for Policy Makers. IOC/UNESCO, Paris (IOC/INF-1320).

Description: Published

Description: Non Refereed

Description: Arid countries throughout the world are heavily reliant on seawater desalination for their supply of drinking and municipal water. The desalination industry is large and rapidly growing, approaching more than 20,000 plants operating or contracted in greater than 150 countries worldwide and capacity projected to grow at a rate of 12% per year for the next several decades (http://www.desaldata.com; 2016). Desalination plants are broadly distributed worldwide, with a large and growing capacity in what will be referred to as the “Gulf” region throughout this manual. Here the Gulf refers to the shallow body of water bounded in the southwest by the Arabian Peninsula and Iran to the northeast. The Gulf is linked with the Arabian Sea by the Strait of Hormuz and the Gulf of Oman to the east and extends to the Shatt al-Arab river delta at its western end. One of the operational challenges facing the industry is also expanding globally – the phenomena termed harmful algal blooms or HABs. Blooms are cell proliferations caused by the growth and accumulation of individual algal species; they occur in virtually all bodies of water. The algae, which can be either microscopic or macroscopic (e.g., seaweeds) are the base of the marine food web, and produce roughly half of the oxygen we breathe. Most of the thousands of species of algae are beneficial to humans and the environment, but there are a small number (several hundred) that cause HABs. This number is vague because the harm caused by HABs is diverse and affects many different sectors of society (see Chapter 1). HABs are generally considered in two groups. One contains the species that produce potent toxins (Chapter 2) that can cause a wide range of impacts to marine resources, including mass mortalities of fish, shellfish, seabirds, marine mammals, and various other organisms, as well as illness and death in humans and other consumers of fish or shellfish that have accumulated the algal toxins during feeding. The second category is represented by species that produce dense blooms - often termed high biomass blooms because of the large number of cells. Cells can reach concentrations sufficient to make the water appear red (hence the common term “red tide”), though brown, green and golden blooms are also observed, while many blooms are not visible. In this manual, we define toxic algae as those that produce potent toxins (poisonous substances produced within living cells or organisms), e.g., saxitoxin. These can cause illness or mortality in humans as well as marine life through either direct exposure to the toxin or ingestion of bioaccumulated toxin in higher trophic levels e.g. shellfish. Non-toxic HABs can cause damage to ecosystems and commercial facilities such as desalination plants, sometimes because of the biomass of the accumulated algae, and in other cases due to the release of compounds that are not toxins (e.g., reactive oxygen species, mucilage) but that can still be lethal to marine animals or cause disruptions of other types. Both toxic and non-toxic HABs represent potential threats to seawater desalination facilities. Although toxins are typically removed very well by reverse osmosis and thermal desalination processes (see Chapter 10), algal toxins represent a potential health risk if they are present in sufficiently high concentrations in the seawater and if they break through the desalination process. It is therefore important for operators to be aware when toxic blooms are near their plants so they can ensure that the removal has indeed occurred (Chapter 3). High biomass blooms pose a different type of threat, as the resulting particulate and dissolved organic material can accelerate clogging of media filters or contribute to (bio)fouling of pretreatment and RO membranes which may lead to a loss of production. Impacts of HABs on desalination facilities are thus a significant and growing problem, made worse by the lack of knowledge of this phenomena among plant operators, managers, engineers, and others involved in the industry, including regulatory agencies. Recognizing this problem, the Middle East Desalination Research Center (MEDRC) and the UNESCO Intergovernmental Oceanographic Commission (IOC) organized a conference in 2012 in Muscat, Oman, to bring HAB researchers and desalination professionals together to exchange knowledge and discuss the scale of the problem and strategies for addressing it. One of the recommendations of that meeting was that a “guidance manual” be prepared to provide information to desalination plant operators and others in the industry about HABs, their impacts, and the strategies that could be used to mitigate those impacts. With support from the US Agency for International Development (USAID) and the IOC Intergovernmental Panel for Harmful Algal Blooms (IPHAB), an editorial team was assembled and potential authors contacted. For the first time, HAB scientists worked closely with desalination professionals to write chapters that were scientifically rigorous yet practical in nature – all focused on HABs and desalination. During the planning of this manual, it became clear from an informal survey of the desalination industry that generally, HAB problems are far more significant for seawater reverse osmosis (SWRO) plants than for those that use thermal desalination. Both types of processes are very effective in removing HAB toxins (Chapter 10), but the SWRO plants are far more susceptible to clogging of pretreatment granular media filters and fouling of membranes by algal organic matter and particulate biomass. Accordingly, the focus of this book is on SWRO, with only occasional reference to thermal processes. Likewise, emphasis has been placed on seawater HABs, with reference to estuarine and brackish-water HABs only when practices from those types of waters can be informative or illustrative. A brief synopsis of the book follows. Chapter 1 provides a broad overview of HAB phenomena, including their impacts, the spatial and temporal nature of their blooms, common causative species, trends in occurrence, and general aspects of bloom dynamics in coastal waters. Chapter 2 describes the metabolites of HAB cells, including toxins, taste and odor compounds. Methods for analyses are presented there, supplemented by detailed methodological descriptions of rapid toxin screening methods in Appendix 2. As discussed in Chapters 8 and 10, thermal and SWRO operations are highly effective in the removal of HAB toxins, but plant personnel should have the capability to screen for these toxins in raw and treated water to ensure that this removal has been effective. This would be critical, for example, if the public or the press were aware of a toxic HAB in the vicinity of a desalination plant intake and asked for proof that their drinking water is safe. Currently, most desalination plants do not collect data on seawater outside their plants, so they are generally unaware of the presence (now or anticipated) of a potentially disruptive HAB. Chapter 3 provides practical information on the approaches to implementing an observing system for HABs, describing sampling methods and measurement options that can be tailored to available resources and the nature of the HAB threat in a given area. Appendix 4 provides more details on methods used to count and identify HAB cells during this process. All are based on direct water sampling, but it is also possible to observe HABs from space – particularly the high biomass events. Chapter 4 describes how satellite remote sensing can be used to detect booms. The common sources of imagery (free over the Internet) are presented, as well as descriptions of the software (also free) that can be used to analyze the satellite data. It is relatively easy and highly informative for plant personnel to use this approach to better understand what is in the seawater outside their plants. The cover of this guide provides a graphic example of the incredible scale and resolution of this observational approach. Chapter 5 discusses typical water quality parameters that are measured online or in feedwater samples at desalination plants that could be used to detect blooms at the intake or evaluate process efficiency in removing algal particulates and organics. Emerging parameters that also show promise are examined to provide a resource for plant personnel. Chapter 6 looks at desalination seawater intakes that are the first point of control in minimizing the ingress of algae into the plant. A brief overview of siting considerations that may ultimately drive the location of an intake is also provided. One question asked frequently of HAB scientists is whether the blooms can be controlled or suppressed in a manner analogous to the treatment of insects or other agricultural pests on land. This has proven to be an exceedingly difficult challenge for the HAB scientific and management community, given the dynamic nature of HABs in coastal waters, their large spatial extent, and concerns about the environmental impacts of bloom control methods. Chapter 7 presents a summary of the approaches to bloom prevention and control that have been developed, and discusses whether these are feasible or realistic in the context of an individual desalination plant. Chapter 8 describes management strategies for HABs and risk assessment, including Hazard Analysis Critical Control Point (HACCP) and Alert Level Framework procedures. Once a HAB is detected, a wide range of approaches can be used to address the problems posed by the dissolved toxins associated with those blooms. Chapter 9 presents many of these pretreatment strategies and discusses their use in removing algal organic matter and particulates to prevent filter clogging and membrane fouling. This is necessary to maintain effective plant operation and avoid serious operational challenges for the reverse osmosis step. The chapter covers common pretreatments such as chlorination/dechlorination, coagulation, dissolved air flotation, granular media filtration, ultrafiltration, and cartridge filtration, in addition to discussing issues experienced due to the inefficiencies of each pretreatment on reverse osmosis. Chapter 10 then addresses the important issue of HAB toxin removal during pretreatment and desalination, and describes laboratory and pilot-scale studies that address that issue. Finally, Chapter 11 provides a series of case studies describing individual HAB events at desalination plants throughout the world, detailing the types of impacts and the strategies that were used to combat them. These studies should be of great interest to other operators as they encounter similar challenges. The manual concludes with a series of appendices that provide images and short descriptions of common HAB species (Appendix 1), rapid screening methods for HAB toxins (Appendix 2), methods to measure transparent exopolymer particles (TEP) and their precursors (Appendix 3), methods to enumerate algal cells (Appendix 4), and reverse osmosis autopsy and cleaning methods (Appendix 5).

Description: OPENASFA INPUT For bibliographic purposes this document should be cited as follows: Anderson D. M., S. F. E. Boerlage, M. B. Dixon (Eds), Harmful Algal Blooms (HABs) and Desalination: A Guide to Impacts, Monitoring and Management. Paris, Intergovernmental Oceanographic Commission of UNESCO, 2017. 539 pp. (IOC Manuals and Guides No.78.) (English.) (IOC/2017/MG/78).

Description: Published

Description: Refereed

Description: Our planet Earth is changing. Marine and freshwater ecosystems are experiencing intense natural and anthropogenic pressures that will generate unforeseen changes in their struc-ture and functioning. The drivers of climate change have already altered the dynamics and interactions of the biotic and abiotic components in these ecosystems, and these changes are anticipated to accelerate in the future. Embedded within natural aquatic ecosystems are Harm-ful Algal Blooms (HABs) that are noxious to aquatic organisms as well as human health and wellbeing. There is concern that climate-driven changes will exacerbate HABs at a time when humans are increasingly reliant on aquatic systems for food and drinking water, livelihoods, mariculture and recreational resources. But there are many unknowns. What trends are evident in HAB distribution, frequency and severity? Might the drivers of climate change alter ecological out-comes to promote HABs? How might HABs and other planktonic species adapt to a changing environment? And, how can we prevent or mitigate future HABs impacts? These are only some of the important questions for which the scientific community should seek answers. The need to support this process forms the basis of the GlobalHAB Programme, launched by IOC UNESCO and SCOR, with the aim of promoting international and multidisciplinary coordina-tion of the research on HABs (www.globalhab.info). HAB science today is founded on studies dealing with a great diversity of topics and harmful organisms, using a variety of continuously evolving experimental methods and approaches. The rich insights obtained to date have been key to supporting research on the potential impacts of climate change on HABs. But more quantitative intercomparisons are now needed amongst studies as well as global comparisons of generated data, which is hampered by the diversity of methods and approaches that have brought us so far. The challenge to achieving greater harmonization of our experimental and observational practices is substantial, although it is acknowledged that this is not necessarily the case in all situations. The major aim of these guidelines is to communicate standardized strategies, tools, and protocols to assist researchers studying how climate change drivers may increase or decrease future HAB prevalence in aquatic ecosystems. These guidelines represent a first step that will help inform HAB scientists, students, and researchers entering the field, as well as scientists seeking to incorporate HAB studies into existing and developing ocean and freshwater observing systems.

Description: Scientific Committee on Oceanic Research (SCOR) provided by the U.S. National Science Foundation (Grants OCE-OCE- 1546580 and OCE-1840868)

Description: National SCOR committees

Description: OPENASFA INPUT This publication should be cited as follows: GlobalHAB. 2021. Guidelines for the Study of Climate Change Effects on HABs. Paris, UNESCO-IOC/SCOR. M. Wells et al. (eds.) (IOC Manuals and Guides no 88)

Description: Published

Description: Refereed

Description: The southern coast of Dominican Republic is a very populated region, withseveral important cities including Santo Domingo, its capital. Important activities are rooted in the southern coast including tourism, industry, commercial ports, and, energy facilities, amongothers. According to historical reports, it has been impacted by big earthquakes accompanied by tsunamis as in Azua in 1751 and recently Pedernales in 2010, but their sources are not clearly identified.With partial support of the European Union funded project "Life-Saving Actions: Disaster preparedness and seismic and tsunami risk reduction in the south coast of San Cristóbal province, Dominican Republic» implemented by UNDP, UNESCO and the Assembly of Cooperation for Peace in Dominican Republic (ACPP),UNESCO together with the Seismological Institute of the Autonomous University of Santo Domingo,organized the meeting of experts "Sources of tsunamis in the Caribbean with possibility to impact the southern coast of the Dominican Republic", on 6 and 7 May 2016, with invited experts and specialists ofDominican Republic, France, Haiti, Spainand theUnited States.The invited experts analysedin a closed meeting three groups of tsunami sources(tectonic sources, landslides and volcanic eruptions)of which they identified two groups of crediblesources of tsunamis in the Caribbean that could impact the southern coast of the Dominican Republic(tectonic sources and submarine landslides):I. Tectonic Sources: A.Near-field tectonic sources(less than 500 km from impact zone):-Western Muertos Trough (WMT) –Mw 8.0:-Small Muertos Trough 1 (SMT1) –Mw 7.6-Small Muertos Trough 2 (SMT2) –Mw 7.6-Muertos Trough Mega-splay (MS)–Mw 7.7B.Far-field tectonic sources:1. Southern Caribbean:-Northern Panama Deformed Belt (NPDB)–Mw 8.5-West branch of the South Caribbean Deformed Belt (WSCDB)–Mw 8.6-Full South Caribbean Deformed Belt (FSCDB)2. Northeastern Caribbean: Although thefollowing sources are at less than500 km of the impact zone, experts classified them as far-field given its expectedlower impact:-Puerto Rico Trench (PRT) –Mw 8.6-Mona Extension Fault (MEF) –Mw 7.6II. Submarine landslides: Within the different sourcesdiscussed only one was consideredasa potential threat, a potential landslide located ~100 km off the coast of Santo Domingo, denominated Complutense Slump (CS)by Granja et al. (2014).Volume of slump: 224km3.

Description: OpenASFA input

Description: Published

Description: Non Refereed

Description: Mr Renato Solidum, Director of the Philippine Institute of Volcanology and Seismology PHIVOLCS delivered the welcome speech on behalf of the Government of Philippines. He recalled that Philippines is a country that is exposed to several natural hazards. He indicated that PHIVOLCS is happy to host the 5th meeting of the Pacific Tsunami Warning and Mitigation System (PTWS) South China Sea Region Working Group (SCS-WG), and emphasized the importance of monitoring real time data from regional and global seismic networks in order to detect and rapidly locate, size, and characterize the source of tsunami, forecast coastal impacts and assess potential hazards. He officially opened the meeting.

Description: OpenASFA input

Description: Published

Description: Non Refereed

Description: This manual seeks to assist countries participating in the IOC-coordinated regional Tsunami Warning and Mitigation Systems in strengthening their existing tsunami warning and emergency responses through the development of Tsunami Warning and Emergency Response Plans and Standard Operating Procedures (SOPs). It relates to tsunami warning authorities (referred to as National Tsunami Warning Centres - NTWCs) and to tsunami emergency management authorities (referred to as Emergency Management Agencies - EMAs), promoting alignment, interoperability and consistency among all stakeholders in the end-to-end tsunami warning system. The Tsunami Warning System (TWS) An end-to-end Tsunami Warning System (TWS) includes the following components: - Knowledge of the hazards and risks to coastal communities from tsunamis and planning for their potential impact - Access to information from the ICG Tsunami Service Providers and/or National Tsunami Warning Centres on the earthquake characteristics, a tsunami assessment and forecast, and tsunami observations - Capability to evaluate the information received in order to determine the threat to their communities - Ability to quickly disseminate and communicate clear, understandable, and actionable warnings to prepared coastal communities in advance of the oncoming tsunami; and - Capacities at national, local and community levels for effective tsunami emergency response. A TWS is best defined in an end-to-end National Tsunami Warning and Emergency Response Plan, with a minimum requirement being the existence of such a document approved at the national level. The main purpose of this guideline is to describe the collective components of the TWS and the allocation (and description) of responsibilities and actions for each component, then designating relevant authorities for each action. The plan may also contain the concepts, thresholds, target times, systems, procedures, and templates used in the tsunami warning chain and a concise description of the tsunami threat for the country (or reference to the relevant documents). In some countries this Plan may need to be split into two plans, a National Tsunami Warning Plan and a Tsunami Emergency Response (TER) Plan, to recognise different functions and responsibilities. In either respect, the overall content and end-to-end processes should be complementary. This guideline describes the TWS and its supporting documents, with a specific focus on tsunami warning plans and SOPs for tsunami warning authorities and emergency response plans and SOPs for key responding agencies. Tsunami warning The NTWC provides warnings of potentially dangerous tsunamis to EMAs and in many cases direct to the communities of the sovereign nation in which it resides and which it serves. It operates on a 24/7 basis to receive earthquake and tsunami information from ICG Tsunami Service Providers (TSPs) of its choice, evaluates the information in terms of the tsunami threat to the country’s coastal communities, and issues warnings about threats. Each country formally nominates a Tsunami Warning Focal Point (TWFP) to the IOC for receipt and national management of tsunami threat information received from TSPs. Some countries have established their own NTWC as the national tsunami warning authority, which have the independent capacity to continuously monitor seismicity in real-time using local and global seismographic networks to locate and determine the magnitude of potentially tsunamigenic earthquakes. This capacity allows them to assess the threat of a tsunami empirically (based mainly on the earthquake magnitude) or through tsunami modelling in the same manner as done by a TSP. Such national assessments may be shared with the TSPs and the NTWCs of other countries. Whether a NTWC has its own in-house seismic processing facility and tsunami monitoring and assessment capability, or whether it relies on the seismic and tsunami threat information contained in notifications from TSPs (and other NTWCs), the next steps are common to all NTWCs. These are the formulation and dissemination of official national warnings to the EMA and other recipients in accordance with the National Tsunami Warning and Emergency Response Plan. A NTWC must respond quickly, be as accurate as possible, and be reliable in order to be effective. In order to achieve this, an NTWC should have regularly exercised and tested SOPs in place for efficiently receiving the earthquake and tsunami information from TSPs (and other NTWCs), or generated by themselves, evaluate and assess the threat to their country before issuing clearly understood threat alerts to national authorities responsible for emergency management and public safety. In some cases NTWCs may issue warnings directly to the public and media, but still in consultation with EMA. This guideline describes the essential functions of a NTWC and the relationship of an NTWC to ICG Tsunami Service Providers (TSPs) and other NTWCs. It is supported by Annexes containing more detail and examples. Tsunami emergency response In association with other authorities, government agencies, and community groups, EMAs must establish and maintain preparedness for an effective tsunami response through hazard risk assessment and the establishment of emergency response plans and accompanying procedures that focus on public awareness, public alerting, and evacuations. These plans and procedures must acknowledge that notifications from a NTWC may provide little response time – a tsunami generated by a local earthquake may impact within minutes, and they can occur at any time of the day or night. In such cases, natural warning signs (e.g. unexpected sudden drop in sea level indicating the pending arrival of the tsunami crest, although not always the case) may be able to provide much more timely warnings than waiting for the seismic information to feasibly reach the sensors, be analysed and tsunami forecasts and warnings generated and issued. During tsunami events EMAs must immediately interpret the warnings issued by the NTWC, and then decide on the appropriate response actions. Accordingly, they must also operate on a 24/7 basis in order to disseminate warnings (if required), instructions and other safety information to agencies at all applicable levels of government, threatened communities, and the media, in accordance with the National Tsunami Warning and Emergency Response Plan. They are also responsible for informing the public of the “All Clear” when the threat is over. Through the activation of Emergency Operations Centres (EOCs) at the respective levels of government, EMAs must coordinate an appropriate emergency response amongst all participating agencies. This guideline covers the linkage between the NTWC and the EMA with a description of the procedures to be adopted by the latter as recipients or potential recipients of warnings from their NTWC, and their subsequent response actions. It is supported by Annexes containing more detail and examples.

Description: OpenASFA input

Description: Published

Description: Refereed

Description: Among the approximately 10,000 beneficial species of marine phytoplankton in the world’s oceans today, some 200 taxa can harm human society through the production of toxins that threaten seafood security and human health. These toxins are also responsible for wild or aquaculture fish-kills, may interfere with recreation-al use of coastal or inland waters, or cause economic losses. Non-toxic microalgae attaining high biomass can also cause Harmful Algal Blooms (HABs) by producing seawater discolorations, anoxia or mucilage that negatively affect the environment and human activities. The most frequently asked questions about harmful algal blooms are if they are increasing and expand-ing worldwide, and what are the mechanisms behind this perceived escalation. These questions have been addressed in several review papers concerning HAB trends at various scales, where evidences of expansion, intensification and increased impacts of harmful algal blooms have been gathered from a selection of examples that have gained high prominence in the scientific world and in society 1,2,3,4. Eutrophication, human-mediated introduction of alien harmful species, climatic variability, and aquaculture have all been mentioned as possible causes of HAB trends at various spatial and temporal scales 5,6. Over the last 40 years, the capacity and monitoring efforts to detect harmful species and harmful events have significantly increased, thus increasing the reporting of harmful events across the world’s seas. The resulting information is mostly scattered in the ever growing literature, with data from statutory monitoring programs often not published in peer review journals, while an extensive and detailed overview of the huge amount of information on harmful species, their spatial and temporal distribution and the trends of HABs they have caused has never been attempted so far. This lack of a synthesis of the relevant data has hampered a sound global assessment of the present status of phenomena related to harmful algae. Following the lead of the International Panel for Climate Change (IPCC) consensus reporting mechanism, and to complement the World Ocean Assessment, the need has been expressed for a Global HAB Status Report compiling an overview of Harmful Algal Bloom events and their societal impacts; providing a worldwide appraisal of the occurrence of toxin-producing microalgae; aimed towards the long term goal of assessing the status and probability of change in HAB frequencies, intensities, and range resulting from environmental changes at the local and global scale. This initiative was launched in April 2013 in Paris by the IOC Intergovernmental Panel on HABs (IOC/IPHAB), and has been pursued with the support of the Government of Flanders and hosted within the IOC International Oceanographic Date Exchange Programme (IODE) in partnership with ICES, PICES and IAEA. As a first step towards a global HAB status assessment, a Special Issue of the journal Harmful Algae (vol. 102, February 2021) has been published comprising 12 papers 7-18 each presenting an overview of toxic and non-toxic HABs in a specific area of the world’s seas. The regional overviews build on existing literature and exploit the information gathered in two relevant data-bases, both incorporated into the Ocean Biodiversity Information System (OBIS).

Description: Government of Flanders

Description: OPENASFA INPUT This Global HAB Status Report summary was prepared based on the special issue Global HAB Status reporting, vol. 102 (Feb. 2021) of the Harmful Algae (Elsevier Journal)

Description: Published

Description: Refereed

Description: In December 2004, 227,899 people lost their lives and around US$10 billion were estimated as overall economic losses in the 14 countries affected by the 9.1-magnitude Indian Ocean earthquake. In response to the devastation caused by the earthquake and consecutive tsunami, the international community reinforced and expanded its initiatives to reduce the tsunami-related risk of coastal communities worldwide. In response, the Tsunami Unit of the Intergovernmental Oceanographic Commission of UNESCO (UNESCO/IOC) was established. It aims to prevent the loss of lives and livelihoods that are caused by tsunamis, offering its support to IOC Member States in assessing tsunami risk, implementing Tsunami Early Warning Systems (EWS) and educating communities at risk about preparedness measures. Since 2015, the UNESCO/IOC has been promoting the Tsunami Ready Recognition Programme as an international performance-based community recognition pilot consisting of key actions that help to reduce tsunami-related risks to individuals and communities. Through the Tsunami Ready Recognition Programme, communities become aware of the risks they face from tsunamis and take steps to address them. To support current and future pilots, UNESCO/IOC commissioned the review and analysis of the Tsunami Ready Guidelines, which were initially established in the Caribbean, with the purpose of expanding the implementation of the programme globally. To this end, a desk-based review of all key documents and literature was conducted to assess the existing frameworks, documents and additional literature about the implementation of the Tsunami Ready Recognition Programme in different regions Figure 1. Recognition sign delivered and countries. Likewise, interviews with to St Kitts & Nevis, in 2021. experts on the Tsunami Ready Recognition Programme, as well as an online survey among relevant and experienced users, were conducted with the purpose of having a better understanding of the areas to be reinforced. This document presents the Standard Guidelines for the Tsunami Ready Recognition Programme based on the review process undertaken. After this introduction, the second section of this manual includes the framework and background information; the third section identifies key issues concerning the Tsunami Ready Recognition Programme and its methodological references; the fourth section presents the indicators to achieve the Tsunami Ready recognition, as well as the templates for requesting recognition; and finally, the fifth section contains the glossary of terms and a list of available tools and references to facilitate its implementation.

Description: OPENASFA INPUT

Description: Published

Description: Not Known