Removal of Microcystin-LR from Drinking Water Using Granular Activated Carbon

Villars, Kathryn E., Villars

12 December 2018

No description available.

Engineering

Environmental Engineering

Water Resource Management

microcystin

adsorption

granular activated carbon

GAC

cyanotoxin

HAB

harmful algal bloom

water treatment

RSSCT

rapid small scale column test

Effects of Low Bioavailable Nitrogen and Phosphorus on Cyanobacteria Dynamics in Eutrophic Lake Erie

Chaffin, Justin D.

11 July 2013

No description available.

Limnology

Freshwater Ecology

Microbiology

Anabaena

Cyanobacteria

Delta 15N

DGGE

Eutrophication

Harmful algal bloom

Lake Erie

Maumee Bay

Microcystin

Microcystis

Monod

Nitrogen

Nutrients

Phosphorus

Planktothrix

Design and implementation of embedded system for chl-a fluorescence detection / Design och implementering av inbyggt system för klorofyll-a fluorescens detektering

Katsogridakis, Anargyros

January 2021

Over the last decades, the effects of climate change have become increasingly evident across natural environments. Apart from other areas, climate change poses a serious threat on water quality. More specifically, it is expected that the effects of global warming around the world will severely limit our ability to control the spread and occurrence of Harmful Algal Blooms (HABs) in the future. A HAB episode is characterised by rapid proliferation of algal biomass which can cause major implications on the environment, the ecosystems, on human health, the economy, and societies overall. One way of detecting the presence of algae is to determine the chlorophyll-a concentration levels in water. This project proposes an embedded system for early algae detection in water samples by means of chl-a fluorometry. The system makes use of a constructed sensor to detect chl-a fluorescence emission. Two versions of the sensor were designed and implemented, both of which were calibrated and then tested. Afterwards, the results were presented, and the system’s performance was evaluated and discussed. Lastly, it was concluded that the performance of the system was adequate for detecting a 50 μg/L limit of chl-a concentration, however, careful testing of the site is required for field applications in samples of natural water. / ­Under de senaste decennierna har effekterna av klimatförändringar blivit allt tydligare i naturliga miljöer. Förutom andra områden utgör klimatförändringarna ett allvarligt hot mot vattenkvaliteten.  I synnerhet förväntas effekterna av global uppvärmning över hela världen begränsa vår förmåga att kontrollera spridningen och förekomsten av skadliga algblomningar (HAB) i framtiden. En HAB-episod kännetecknas av snabb spridning av algbiomassa som kan orsaka stora konsekvenser för miljön, ekosystemen, människors hälsa, ekonomin och samhället i stort. Ett sätt att upptäcka förekomsten av alger är att bestämma klorofyll-a-koncentrationsnivåerna i vatten.  Detta projekt föreslår ett inbyggt system för tidig algedetektering i vattenprover med hjälp av chl-a fluorometri. Systemet använder en konstruerad sensor för att detektera chl-a-fluorescensemission. Två versioner av sensorn designades och implementerades, båda kalibrerades och testades sedan. Därefter presenterades resultaten och systemets prestanda utvärderades och diskuterades.  Slutligen drogs slutsatsen att systemets prestanda var tillräcklig för att detektera 50 μg/L-gräns för chl-a-koncentration, men noggrann testning av platsen krävs för fältapplikationer i prover av naturligt vatten.

Embedded systems

Microcontrollers

Harmful algal bloom

Climate change

chl-a fluorescence

Inbyggda system

mikrokontroller

skadlig algblomning

klimatförändring

chl-a-fluorescens

Elektroteknik och elektronik

Field Ecology Patterns of High Latitude Coral Communities

Foster, Kristi A.

01 November 2011

Some climate models predict that, within the next 30-50 years, sea surface temperatures (SSTs) will frequently exceed the current thermal tolerance of corals (Fitt et al. 2001; Hughes et al. 2003; Hoegh-Guldberg et al. 2007). A potential consequence is that mass coral bleaching may take place (i) during warm El Niño-Southern Oscillation (ENSO) events which are predicted to occur in some regions more frequently than the current 3-7 year periodicity (Hoegh-Guldberg 1999; Sheppard 2003) or (ii) perhaps as often as annually or biannually if corals and their symbionts are unable to acclimate to the higher SSTs (Donner et al. 2005, 2007). Global data also indicate an upward trend toward increasing frequencies, intensities, and durations of tropical hurricanes and cyclones (Emanual 2005; Webster et al. 2005). As coral communities have been shown to require at least 10-30 years to recover after a major disturbance (e.g. Connell 1997; Ninio et al. 2000; Bruno & Selig 2007; Burt et al. 2008), it is possible that future coral communities may be in a constant state of recovery, with regeneration times exceeding the periods between disturbances. Life history traits (e.g. reproduction, recruitment, growth and mortality) vary among species of hard corals; thus, gradients in community structures may have a strong influence on susceptibilities to disturbance and rates of recovery (Connell 1997; Ninio & Meekan 2002). Taxa which are more susceptible to bleaching and mechanical disturbance (e.g. tabular and branching acroporids and pocilloporids) may experience continual changes in population structure due to persistent cycles of regeneration or local extirpation, while the more resistant taxa (e.g. massive poritids and faviids) may display relatively stable population structures (Woodley et al. 1981; Hughes & Connell 1999; Baird & Hughes 2000; Marshall & Baird 2000; Loya et al. 2001; McClanahan & Maina 2003). Determining whether resistant coral taxa have predictable responses to disturbances, with consistent patterns over wide spatial scales, may improve predictions for the future affects of climate change and the composition of reefs (Done 1999; Hoegh-Guldberg 1999; McClanahan et al. 2004). The work presented in this dissertation describes the spatial and temporal patterns in community structures for high latitude coral assemblages that have experienced the types of natural disturbances which are predicted to occur in tropical reef systems with increasing frequency as a result of climate change. The primary area of focus is the southeastern Arabian Gulf, where the coral communities are exposed to natural conditions that exceed threshold limits of corals elsewhere in the world, with annual temperature ranges between 14-36°C (Kinzie 1973; Shinn 1976) and salinities above 40 ppt. Two additional regions are included in this study for comparisons of high latitude coral community structures. The northwestern Gulf of Oman is adjacent to the southeastern Arabian Gulf (i.e. the two bodies of water are connected by the Strait of Hormuz); however, the environmental conditions are milder in the Gulf of Oman such that the number of coral taxa therein is threefold that found in the southeastern Arabian Gulf (i.e. 107 coral species in the Gulf of Oman compared to 34 species in this region of the Arabian Gulf (Riegl 1999; Coles 2003; Rezai et al. 2004)). Broward County, Florida is geographically remote from the Gulfs and, therefore, serves as a benchmark for testing whether consistent patterns in community structures exist despite different climatic and anthropogenic influences. The coral communities within the southeastern Arabian Gulf, the northwestern Gulf of Oman, and Broward County, Florida have been exposed to recurrent elevated sea surface temperature (SST) anomalies, sequential cyclone and red tide disturbances, and frequent hurricanes and tropical storms, respectively. These disturbances and other impacts (e.g. bleaching episodes, disease outbreaks, anthropogenic stresses) have affected the more susceptible acroporids and pocilloporids, resulting in significant losses of coral cover by these families and shifts towards massive corals as the dominant taxa. During the post-disturbance scarcity or absence of branching and tabular corals, the resistant massive taxa have become the crux of the essential hard coral habitat for fish, invertebrates and other marine organisms. Because recovery to pre-disturbance community structures may take decades or may not occur at all, it is vital that scientists and resource managers have a better understanding of the spatial and temporal ecology patterns of the corals that survive and fill in the functional gaps that are created by such disturbances. To aid in this understanding, this dissertation presents spatial and temporal patterns for the coral assemblages which have developed after the respective disturbances. Spatial ecology patterns are analyzed using graphical descriptions (e.g. taxa inventories, area cover, densities, size frequency distributions), univariate techniques (e.g. diversity indices), distributional techniques (e.g. k-dominance curves) and multivariate techniques (e.g. hierarchical clustering, multidimensional scaling). Temporal comparisons at monitoring sites within the southeastern Arabian Gulf and northwestern Gulf of Oman describe the coral population dynamics and are used to create size class transition models that project future population structures of massive corals in the recovering habitats.

Coral community structure

population dynamics

natural disturbance

mass mortality

recovery

projection models

elevated temperature anomalies

Cyclone Gonu

red tide

harmful algal bloom

Arabian Gulf

Gulf of Oman

Broward County

Florida

Acropora

Pocillopora

Marine Biology

The Spatial and Temporal Distribution and Environmental Drivers of Saxitoxin in Northwest Ohio

Nauman, Callie A.

12 August 2020

No description available.

Biology

Freshwater Ecology

Ecology

Microbiology

Harmful algal bloom

cyanobacteria

cHABS

Ohio

benthic

saxitoxin

neurotoxin

STX

sxtA

algal

algae

phytoplankton

Lake Erie

Maumee River

qPCR

toxin freshwater

detection

molecular

gene

phytoxigene

spatial

temporal

Removal of Saxitoxin and Microcystin when present alone or simultaneously in drinking water plants with different PAC sources

WALKE, DIVYANI

17 May 2023

No description available.

Chemical Engineering

Civil Engineering

Environmental Engineering

Methods to Monitor Lake Erie's Harmful Algal Blooms: A Fellowship with the Cooperative Institute for Great Lakes Research

Fyffe, Deanna Lynne

30 November 2017

No description available.

Aquatic Sciences

Environmental Health

Environmental Science

Environmental Studies

Freshwater Ecology

Microbiology

Water Resource Management

Harmful Algal Blooms in Small Lakes: Causes, Health Risks, and Novel Exposure Prevention Strategies

Mrdjen, Igor

28 September 2018

No description available.

Aquatic Sciences

Biology

Environmental Health

Environmental Science

Ecology

Geology

Land Use Planning

Public Health

Remote Sensing

Water Resource Management

harmful algal bloom

microcystin

carcinogenesis

cancer

algae

cyanobacteria

community

tile drainage

drone

UAV

remote sensing

NDVI

toxicity

Protecting Public Health at Inland Ohio Beaches: Development of Recreational Water Quality Indicators Predictive of Microbial and Microcystin Exposure

Marion, Jason W.

20 October 2011

No description available.

Biology

Ecology

Environmental Health

Environmental Science

Epidemiology

Freshwater Ecology

Limnology

Public Health

Recreation

E. coli

fecal indicator

epidemiology

recreational water

microcystin

harmful algal bloom

cyanotoxin

phycocyanin

trophic state index

inland lakes

Ohio

gastrointestinal illness

beach water quality

Skyfallens hot mot Mälarens ekosystem / The effects of high precipitation on phosphorus transport in three tributaries to Lake Mälaren, Sweden

Immo, Nelly

January 2024

Hälsosamma ekosystem försörjer oss med livsviktiga resurser och tjänster – ekosystemtjänster så som skydd mot översvämning. I Norra Östersjöns vattendistrikt, som Mälaren tillhör, är statusen på den ekosystemtjänsten dålig. Detta beror till stor del på en omfattande dikning och brist på svämplan i området. Under perioder med skyfall riskerar därför området runt Mälaren och dess tillrinnande vattendrag att drabbas av översvämningar som skadar matproduktion, infrastruktur och miljö. Övergödning är redan ett problem i området och stora tillskott av fosfor till följd av översvämmade jordbruksmarker kan orsaka stora algblomningar och försämrad livsmiljö för vattenlevande organismer. Under augusti och september 2023 föll ovanligt stora mängder regn över mellersta Sverige vilket ökade vattenföringen i vattendragen runt Mälaren och översvämmade vissa av dem. Högfrekventa turbiditetsmätningar från in-situ sensorer installerade i Sagån, Hågaån och Fyrisån, tre vattendrag i Mälarens avrinningsområde, har använts för att undersöka skyfallens effekter på deras vattenföring och beräknad fosfortransport. Resultaten visade en signifikant korrelation mellan ökad vattenföring och ökad fosfortransport, en signifikant ökning under 2023 jämfört med 2018–2022 och signifikanta skillnader mellan vattendragen. Översvämmade Sagån hade extremt höga toppar i beräknad fosfortransport. Resultaten indikerar att övergödningsproblemen i Mälaren kan förvärras i ett framtida klimat med mer intensiva skyfall om inte åtgärder tas för att stärka avrinningsområdets förmåga att hantera stora mängder nederbörd. / Healthy ecosystems provide us with vital resources and services – ecosystem services such as flood protection. In the North Baltic Sea Water District, to which Lake Mälaren belongs, the status of that ecosystem service is poor, largely as a result of extensive draining in the area leading to a lack of floodplains. During periods of torrential rain, the area around Lake Mälaren and its tributaries is therefore at risk to be affected by floods that cause damage to food production, infrastructure and the environment. Eutrophication is already a problem in the area and large additions of phosphorus as a result of flooded agricultural land can cause large algal blooms and degraded habitat for aquatic organisms. During August and September 2023, unusually large amounts of rain fell over central Sweden, which increased the flow of water in Lake Mälarens tributaries and flooded some of them. High frequency turbidity data from in-situ sensors installed in Sagån, Hågaån and Fyrisån, three tributaries to Lake Mälaren, was used to study the effects of the heavy rains on their waterflow and estimated phosphorus transport. The results showed a significant correlation between increased water flow and increased phosphorus transport, a significant increase in 2023 compared to 2018-2022 and significant differences between the tributaries. Flooded Sagån had extremely high peaks in estimated phosphorus transport. The results indicate that the eutrophication problems in Lake Mälaren may worsen in a future climate with more intense downpours unless measures are taken to strengthen the catchment's ability to handle large amounts of rainfall.

phosphorus transport

Lake Mälaren

tot-P

nutrient loads

in situ sensor

turbidity

eutrophication

algal bloom

flooding

ecosystem services

Sagån

Hågaån

Fyrisån

fosfortransport

Mälaren

näringsläckage

tot-P

in-situ sensor

turbiditet

övergödning

eutrofiering

algblomning

översvämning

skyfall

ekosystemtjänster

Sagån

Hågaån

Fyrisån

Environmental Sciences

Miljövetenskap