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Notably, Lake Hopatcong, located in Sussex and Morris Counties, remained virtually ice-free throughout the winter, with only a brief period of minor ice formation in early January. This pattern was not isolated to Lake Hopatcong; many lakes across the state and the broader Mid-Atlantic region exhibited similar ice-free conditions. Such conditions can lead to increased algal and plant growth earlier in the year. Adding to this, from January to early June 2024, 15 of New Jersey's 21 counties recorded precipitation levels 26% to 50% higher than their long-term averages. The remaining six counties, predominantly in the southern part of the state, had precipitation increases of 11% to 25% above their long-term normals. This heightened precipitation is significant as it can transport nutrients, most notably phosphorus and nitrogen, into water bodies, potentially fueling the growth of algae. Compounding these factors, long-range climate models and trends suggest that the summer of 2024 could rank among the hottest on record. The combination of a mild winter, increased precipitation, and anticipated high summer temperatures sets the stage for conditions similar to those experienced in 2019, a year marked by widespread harmful algal blooms (HABs) in numerous lakes. HABs, characterized by rapid overgrowths of cyanobacteria, present serious challenges to water quality and aquatic ecosystems. Cyanobacteria, or blue-green algae, naturally occur in aquatic environments but can proliferate rapidly under warm, nutrient-rich conditions. These blooms pose risks to human health, wildlife, aquatic species, local economies, and the overall ecological balance. The interplay between climate change and HABs is undeniable: rising temperatures and altered precipitation patterns foster conditions that exacerbate bloom occurrences. Given these circumstances, it is crucial for lake managers and water utilities to adopt proactive measures. Early and consistent sampling efforts can detect cyanobacteria and akinetes, dormant spores that contribute to bloom formation. Additionally, reducing nutrient inputs, particularly phosphorus, into waterways is essential to prevent HABs. Princeton Hydro strongly recommends that lake managers, water utilities, and concerned community members closely monitor their lakes, reservoirs, and riverways to stay as proactive as possible in managing these valuable resources. By raising awareness, fostering collaboration, and implementing effective strategies, we can work towards safeguarding the health and sustainability of our freshwater ecosystems. Together, we can address the challenges posed by HABs and protect the integrity of our water bodies. For more information about HABs, click here. Dr. Fred Lubnow, Princeton Hydro’s Senior Technical Director, Ecological Services, is an expert in aquatic and watershed management, restoration ecology, community and ecosystem ecology, and the use of benthic macroinvertebrate and fish in-stream bioassessment protocols. Dr. Lubnow has managed hundreds of lake projects and provides technical expertise for a variety of lake and watershed restoration projects. His experience in lake and reservoir restoration includes the design and implementation of dredging, aeration, chemical control of nuisance species, nutrient inactivation (i.e. alum) and biomanipulation. His experience in watershed restoration includes the design and implementation of structural Best Management Practices (BMPs), the development of Total Maximum Daily Load (TMDL) pollutant budgets, and the design, implementation and analysis of watershed-based monitoring programs. [post_title] => Preparing for Potential Harmful Algal Blooms: An Urgent Call to Action for NJ's Lakes and Reservoirs [post_excerpt] => [post_status] => publish [comment_status] => open [ping_status] => open [post_password] => [post_name] => an-urgent-call-to-action-habs [to_ping] => [pinged] => [post_modified] => 2024-06-11 18:25:13 [post_modified_gmt] => 2024-06-11 18:25:13 [post_content_filtered] => [post_parent] => 0 [guid] => https://princetonhydro.com/?p=15090 [menu_order] => 0 [post_type] => post [post_mime_type] => [comment_count] => 0 [filter] => raw ) [1] => WP_Post Object ( [ID] => 10283 [post_author] => 1 [post_date] => 2022-03-07 06:12:46 [post_date_gmt] => 2022-03-07 06:12:46 [post_content] => Lake Latonka is a 260-acre man-made freshwater lake in Mercer County, Pennsylvania. The lake serves as the centerpiece of the Lake Latonka community, and is used for fishing, boating, swimming, and a variety of recreation activities. The watershed of Lake Latonka encompasses 8,000+ acres of rural land, which is comprised predominantly by agricultural type land uses (57%) and forest (27%) with low-density residential (12%) occurring along the immediate lake shores. The area is bordered by Ohio to the West and located midway between the cities of Erie and Pittsburgh. [caption id="attachment_10338" align="aligncenter" width="841"] Photo by Lynne Annis[/caption] The Lake, which was formed in 1965, has been studied and managed in some form since its formation with a record of consistent management and study since the mid-1990s. This work has included water quality monitoring, academic study of the sediment transport to the lake, herbicide and algaecide applications, and the development of generalized guidance for lake management. Additionally, some advanced management and restoration activities were implemented, including the installation of a community sewer system and maintenance dredging of the lake's inlet area. Despite these ongoing efforts, the lake has suffered from water quality impairments primarily due to excessive phosphorus from surrounding agricultural land that flows into the waterbody via stormwater runoff. These nutrients fuel algal growth and contribute to the increased deposition of sediment and nutrients at the lake bottom. Over time, the increase in biological oxygen demand has led to anoxia (i.e. no oxygen) in the lake’s deep waters, which causes phosphorus to be ‘pumped’ from the sediments during the summer months. This process is termed ‘internal loading’ and leads to an acceleration of lake productivity that has fueled harmful algal blooms (HABs). Recognizing the importance of the lake within the community, the Water Quality Committee (WQC) of Lake Latonka commissioned Princeton Hydro to perform an in-depth diagnostic/feasibility study and, based on the study's findings, develop a comprehensive Lake Management Plan. The diagnostic/feasibility study, in accordance with USEPA protocol, also analyzed background data; collected site specific water quality and fishery data; and computed the nutrient and hydrologic load. The study also included trophic calculations, the development of SMART (Specific, Measurable, Achievable, Relevant, and Time-based) goals, and the establishment of site-specific management recommendations. In order to meet Lake Latonka’s water quality goals most expediently, Princeton Hydro recommended five primary management measures: Phosphorus Loading Mitigation Biomanipulation Management of Submerged Aquatic Vegetation Waterfowl Management Regular Water Quality Monitoring and Testing. Phosphorus Loading Mitigation Although phosphorus is a nutrient utilized for plant growth, excessive phosphorus in waterbodies has problematic effects in that it speeds up weed production, reduces water quality, and can lead to HABs. One of the most sustainable means of controlling nuisance weed and algae proliferation is to control phosphorus inputs or reduce the availability of phosphorus for biological uptake and assimilation. For Lake Latonka, Princeton Hydro recommended an alum treatment as a primary method for reducing internal phosphorus loading. Alum (aluminum sulfate) is a commonly used nutrient inactivation product that controls the internal recycling of phosphorus from the sediments of the lake bottom. On contact with water, the alum binds with the phosphorus so it can no longer be used as food by algae. On the bottom of the lake, the alum creates a barrier that prevents the phosphorus from releasing into the lake’s sediments under anoxia. In addition, recommendations were made to address phosphorous loading from the larger agricultural watershed. These recommendations lead to the formation a Watershed Sub-Committee, which has been monitoring water quality and identifying nutrient-loading "hot spots." As these areas are discovered, the community will work with local stakeholders to recommend watershed best management practices (BMPs) to reduce phosphorus and sediment loading at the source. Biomanipulation The diagnostic/feasibility study revealed a major change in Lake Latonka from a previous fishery study conducted in 2016: the establishment of gizzard shad. The gizzard shad, not found in any previous surveys, represented 29% of the total catch in the 2020 survey. These fish can, if present in significant densities, outcompete beneficial fish and aquatic species and alter the zooplankton population, which can lead to water quality impairment, HABs, and cyanobacteria. Biomanipulation in lake management refers to the deliberate alteration of the lake’s ecosystem by adding or removing species. One of the main recommendations for Lake Latonka is to control the gizzard shad population by stocking the lake with hybrid striped bass (Morone saxatilis x Morone chrysops), which is a cross between striped bass and white bass that are not able to reproduce. The plan includes measures to bolster the walleye, largemouth bass, black crappie, and panfish populations to offer a robust recreational fishery. This "top down" approach to nutrient management serves as a complementary effort to the aforementioned phosphorus loading mitigation activities. Management of Submerged Aquatic Vegetation [caption id="attachment_10336" align="alignright" width="273"] Photo by Lynne Annis[/caption] As phosphorus is reduced and water quality conditions improve, algae will diminish in abundance and water clarity will improve, and the shallow areas of the lake will become excellent habitat for increased growth of submerged aquatic vegetation (SAV). SAV is a critical component of a healthy lake and important habitat for juvenile fish and invertebrates. Additionally, SAV serves to precipitate suspended solids and assimilates nutrients that may otherwise be taken up by algae for growth. Still, elevated levels of SAV may prove to hinder recreational use of the lake. The Plan for Lake Latonka recommends regular SAV surveys in order to monitor densities, document species composition, and ensure proper management. As SAV increases, pragmatic, measured management will be recommended to maintain an optimal balance of plant growth while allowing for recreational lake access. Waterfowl Management Resident populations of Canada Goose (Branta canadensis) contribute acute sources of nitrogen, phosphorus, and bacteria to lakes via waste products. Using loading coefficients derived from scientific literature, in combination with Canada geese population surveys, the team determined the approximate phosphorus load being contributed by the resident goose population each year is 88.6 lbs per year. The Plan recommends a variety of deterrent/harassment actions as permitted through Federal and State agencies in order to minimize the resident population of these waterfowl. Regular Water Quality Monitoring and Testing The Management Plan also provided recommendations for routine water quality monitoring related to nutrient concentrations, algal types and densities, and safety for lake users. Lake monitoring helps track changes in water quality over time and is utilized to objectively assess the impacts of prescribed management measures. In this manner, monitoring can help to address potential issues before they become large problems. Specifically, Princeton Hydro recommended growing season monitoring, which entails monitoring for five months each year, in order to build a lake water quality database for nutrients, in-situ measures, and plankton. Additionally, the team recommends robust contact testing at the beach and open water for E. coli sampling, fecal coliform, and cyanotoxins. [caption id="attachment_10339" align="aligncenter" width="793"] Photo by Jim Janzig[/caption] Simply put, there is more to lake management than weed and algae treatments alone. A customized plan acts as a “blueprint” that guides proactive, long-term lake management and care while remaining flexible enough to adapt to new challenges that may arise. Our scientists, engineers, and Certified Lake Managers can assess the status of a waterbody and provide a holistic management plan that is based on the waterbody's unique physical, hydrologic, chemical, and biological attributes. A management plan identifies water quality issues, determines the causes of those issues, and provides the guidance needed to correct the issues. The results are far more environmentally sustainable than simple (and often unnecessary) reactive weed and algae treatments. During the Pennsylvania Lake Management Society Annual Conference held on March 2 & 3, Senior Aquatic Ecologist Michael Hartshorne gave a presentation about the the creation and implementation of the Lake Latonka Management Plan: If you're interested in reading more on the topic of lake management, click here: [visual-link-preview encoded="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"] [post_title] => Reducing HABs & Increasing Biodiversity in Lake Latonka [post_excerpt] => [post_status] => publish [comment_status] => open [ping_status] => open [post_password] => [post_name] => lake-latonka-management-plan [to_ping] => [pinged] => [post_modified] => 2025-11-07 14:54:20 [post_modified_gmt] => 2025-11-07 14:54:20 [post_content_filtered] => [post_parent] => 0 [guid] => https://princetonhydro.com/?p=10283 [menu_order] => 0 [post_type] => post [post_mime_type] => [comment_count] => 0 [filter] => raw ) [2] => WP_Post Object ( [ID] => 5757 [post_author] => 3 [post_date] => 2021-01-19 17:48:32 [post_date_gmt] => 2021-01-19 17:48:32 [post_content] => When monitoring and managing the health of a lake or pond, dissolved oxygen is one of the most important indicators of water quality. Dissolved oxygen refers to the level of free, non-compound oxygen present in water. It is an important parameter in assessing water quality because of its influence on the organisms living within a body of water; the vast majority of aquatic life needs sufficient amounts of oxygen dissolved in water in order to survive. Pollutants, the decomposition of invasive aquatic weed growth, and algae blooms significantly reduce dissolved oxygen. The purpose of aeration in lake management is to increase the concentrations of dissolved oxygen in the water. Aeration systems achieve these water quality improvements by helping prevent stagnation of water, increasing circulation, disrupting thermal stratification which provides “through-column” mixing, and minimizes the occurrence of harmful algal blooms (HABs). Princeton Hydro has been working with the Lake Hopatcong Commission and Lake Hopatcong Foundation to implement several projects aimed at reducing the impacts of HABs in Lake Hopatcong, including the installation of three innovative aeration systems in different areas of the lake. Funding for these projects have come from a NJ Department of Environmental Protection Water Quality Restoration HAB grant awarded to the Commission in 2020, with additional funding and support coming from the Foundation, Morris and Sussex Counties, and four municipalities that surround Lake Hopatcong. Air Curtain Aeration System Our team completed the installation of an air curtain system at Shore Hills Country Club in Roxbury Township in early November 2020. The system produces a wall of bubbles that provide the kinetic energy to push and deflect away floating cyanobacteria and other toxins trying to enter the waterway. Installed near the shoreline, the air curtain increases the movement of the water, making it more difficult for floating debris, pollutants, and HABs to accumulate near the shore and in nearby shallow water areas. Nanobubble Aeration System Nanobubbles are extremely small gas bubbles that have several unique physical properties that make them very different from normal bubbles. Nanobubble aerators directly saturate the water with significantly more oxygen than traditional water aeration systems. These systems produce ultra-fine bubbles that are nearly invisible to the human eye. Unlike “traditional” aeration systems that push air bubbles to the surface in order to circulate the water and increase the dissolved oxygen levels, nanobubbles are so small that they remain within the water column for an extended period of time, directly oxygenating the water. Our team is scheduled to complete a nanobubble system install for Lake Hopatcong in the Spring of 2021. Nanobubble Aeration System with Ozone At Lake Hopatcong’s Lake Forest Yacht Club in Jefferson Township, our team installed a Nanobubble System with Ozone, which was completed in November 2020. This system generates ultrafine microbubbles (nanobubbles) containing ozone, which is used to disinfect water supplies and works to break down organic material in the water. These nanobubbles harness the unique biocidal power of ozone and place it into a safe delivery mechanism that is highly effective but also ensures human and environmental safety. The resulting ozone nanobubbles eliminate a wide range of polluting chemicals as well as herbicides, pesticides, and microbial toxins, which are all known causes of HABs. The nanobubble technology is a relatively new strategy for preventing cyanobacteria blooms. Evaluation of the air curtain and both nanobubble systems in controlling and minimizing HABs in Lake Hopatcong will begin in Spring 2021. Our team will closely monitor the effectiveness throughout the 2021 season and provide detailed reports of our findings. Stay tuned for more info! Increasing the dissolved oxygen levels in a pond or lake provides many benefits including improved water quality, healthier fish and plants, more efficient filtration, and reduced nuisance algae growth. To learn more about Princeton Hydro's collaborative efforts to protect our valuable water resources, click here. [post_title] => Preventing Harmful Algal Blooms with Innovative Aeration Technology [post_excerpt] => [post_status] => publish [comment_status] => open [ping_status] => open [post_password] => [post_name] => innovative-aeration-technology [to_ping] => [pinged] => [post_modified] => 2025-03-12 11:03:33 [post_modified_gmt] => 2025-03-12 11:03:33 [post_content_filtered] => [post_parent] => 0 [guid] => https://www.princetonhydro.com/blog/?p=5757 [menu_order] => 0 [post_type] => post [post_mime_type] => [comment_count] => 0 [filter] => raw ) [3] => WP_Post Object ( [ID] => 5103 [post_author] => 3 [post_date] => 2020-07-01 15:19:38 [post_date_gmt] => 2020-07-01 15:19:38 [post_content] => July is Lakes Appreciation Month - a great time of year to enjoy your community lakes and help protect them. Lakes Appreciation Month was started by North American Lake Management Society (NALMS) to help bring attention to the countless benefits that lakes provide, to raise awareness of the many challenges facing our waterways, and to encourage people to get involved in protecting these precious resources. “You work and play on them. You drink from them. But do you really appreciate them? Growing population, development, and invasive species stress your local lakes, ponds, and reservoirs. All life needs water; let’s not take it for granted!” - NALMS Chemical pollutants, stormwater runoff, hydrocarbons, invasive aquatic species, and climate change are just a few of the the serious threats facing lakes and other freshwater habitats. So what can you do to to help? We’ve put together six tips to help you celebrate Lakes Appreciation Month and get involved in protecting your favorite lakes:
As we reflect on the winter of 2023-2024, it's evident that New Jersey experienced another unusually mild season, mirroring the winter of 2022-2023. Notably, Lake Hopatcong, located in Sussex and Morris Counties, remained virtually ice-free throughout the winter, with only a brief period of minor ice formation in early January. This pattern was not isolated to Lake Hopatcong; many lakes across the state and the broader Mid-Atlantic region exhibited similar ice-free conditions. Such conditions can lead to increased algal and plant growth earlier in the year.
Adding to this, from January to early June 2024, 15 of New Jersey's 21 counties recorded precipitation levels 26% to 50% higher than their long-term averages. The remaining six counties, predominantly in the southern part of the state, had precipitation increases of 11% to 25% above their long-term normals. This heightened precipitation is significant as it can transport nutrients, most notably phosphorus and nitrogen, into water bodies, potentially fueling the growth of algae.
Compounding these factors, long-range climate models and trends suggest that the summer of 2024 could rank among the hottest on record. The combination of a mild winter, increased precipitation, and anticipated high summer temperatures sets the stage for conditions similar to those experienced in 2019, a year marked by widespread harmful algal blooms (HABs) in numerous lakes.
HABs, characterized by rapid overgrowths of cyanobacteria, present serious challenges to water quality and aquatic ecosystems. Cyanobacteria, or blue-green algae, naturally occur in aquatic environments but can proliferate rapidly under warm, nutrient-rich conditions. These blooms pose risks to human health, wildlife, aquatic species, local economies, and the overall ecological balance. The interplay between climate change and HABs is undeniable: rising temperatures and altered precipitation patterns foster conditions that exacerbate bloom occurrences.
Given these circumstances, it is crucial for lake managers and water utilities to adopt proactive measures. Early and consistent sampling efforts can detect cyanobacteria and akinetes, dormant spores that contribute to bloom formation. Additionally, reducing nutrient inputs, particularly phosphorus, into waterways is essential to prevent HABs. Princeton Hydro strongly recommends that lake managers, water utilities, and concerned community members closely monitor their lakes, reservoirs, and riverways to stay as proactive as possible in managing these valuable resources.
By raising awareness, fostering collaboration, and implementing effective strategies, we can work towards safeguarding the health and sustainability of our freshwater ecosystems. Together, we can address the challenges posed by HABs and protect the integrity of our water bodies. For more information about HABs, click here.
Dr. Fred Lubnow, Princeton Hydro’s Senior Technical Director, Ecological Services, is an expert in aquatic and watershed management, restoration ecology, community and ecosystem ecology, and the use of benthic macroinvertebrate and fish in-stream bioassessment protocols. Dr. Lubnow has managed hundreds of lake projects and provides technical expertise for a variety of lake and watershed restoration projects.
His experience in lake and reservoir restoration includes the design and implementation of dredging, aeration, chemical control of nuisance species, nutrient inactivation (i.e. alum) and biomanipulation. His experience in watershed restoration includes the design and implementation of structural Best Management Practices (BMPs), the development of Total Maximum Daily Load (TMDL) pollutant budgets, and the design, implementation and analysis of watershed-based monitoring programs.
Lake Latonka is a 260-acre man-made freshwater lake in Mercer County, Pennsylvania. The lake serves as the centerpiece of the Lake Latonka community, and is used for fishing, boating, swimming, and a variety of recreation activities.
The watershed of Lake Latonka encompasses 8,000+ acres of rural land, which is comprised predominantly by agricultural type land uses (57%) and forest (27%) with low-density residential (12%) occurring along the immediate lake shores. The area is bordered by Ohio to the West and located midway between the cities of Erie and Pittsburgh.
The Lake, which was formed in 1965, has been studied and managed in some form since its formation with a record of consistent management and study since the mid-1990s. This work has included water quality monitoring, academic study of the sediment transport to the lake, herbicide and algaecide applications, and the development of generalized guidance for lake management. Additionally, some advanced management and restoration activities were implemented, including the installation of a community sewer system and maintenance dredging of the lake's inlet area.
Despite these ongoing efforts, the lake has suffered from water quality impairments primarily due to excessive phosphorus from surrounding agricultural land that flows into the waterbody via stormwater runoff. These nutrients fuel algal growth and contribute to the increased deposition of sediment and nutrients at the lake bottom.
Over time, the increase in biological oxygen demand has led to anoxia (i.e. no oxygen) in the lake’s deep waters, which causes phosphorus to be ‘pumped’ from the sediments during the summer months. This process is termed ‘internal loading’ and leads to an acceleration of lake productivity that has fueled harmful algal blooms (HABs).
Recognizing the importance of the lake within the community, the Water Quality Committee (WQC) of Lake Latonka commissioned Princeton Hydro to perform an in-depth diagnostic/feasibility study and, based on the study's findings, develop a comprehensive Lake Management Plan.
The diagnostic/feasibility study, in accordance with USEPA protocol, also analyzed background data; collected site specific water quality and fishery data; and computed the nutrient and hydrologic load. The study also included trophic calculations, the development of SMART (Specific, Measurable, Achievable, Relevant, and Time-based) goals, and the establishment of site-specific management recommendations.
In order to meet Lake Latonka’s water quality goals most expediently, Princeton Hydro recommended five primary management measures:
Although phosphorus is a nutrient utilized for plant growth, excessive phosphorus in waterbodies has problematic effects in that it speeds up weed production, reduces water quality, and can lead to HABs. One of the most sustainable means of controlling nuisance weed and algae proliferation is to control phosphorus inputs or reduce the availability of phosphorus for biological uptake and assimilation.
For Lake Latonka, Princeton Hydro recommended an alum treatment as a primary method for reducing internal phosphorus loading. Alum (aluminum sulfate) is a commonly used nutrient inactivation product that controls the internal recycling of phosphorus from the sediments of the lake bottom. On contact with water, the alum binds with the phosphorus so it can no longer be used as food by algae. On the bottom of the lake, the alum creates a barrier that prevents the phosphorus from releasing into the lake’s sediments under anoxia.
In addition, recommendations were made to address phosphorous loading from the larger agricultural watershed. These recommendations lead to the formation a Watershed Sub-Committee, which has been monitoring water quality and identifying nutrient-loading "hot spots." As these areas are discovered, the community will work with local stakeholders to recommend watershed best management practices (BMPs) to reduce phosphorus and sediment loading at the source.
The diagnostic/feasibility study revealed a major change in Lake Latonka from a previous fishery study conducted in 2016: the establishment of gizzard shad. The gizzard shad, not found in any previous surveys, represented 29% of the total catch in the 2020 survey. These fish can, if present in significant densities, outcompete beneficial fish and aquatic species and alter the zooplankton population, which can lead to water quality impairment, HABs, and cyanobacteria.
Biomanipulation in lake management refers to the deliberate alteration of the lake’s ecosystem by adding or removing species. One of the main recommendations for Lake Latonka is to control the gizzard shad population by stocking the lake with hybrid striped bass (Morone saxatilis x Morone chrysops), which is a cross between striped bass and white bass that are not able to reproduce. The plan includes measures to bolster the walleye, largemouth bass, black crappie, and panfish populations to offer a robust recreational fishery. This "top down" approach to nutrient management serves as a complementary effort to the aforementioned phosphorus loading mitigation activities.
As phosphorus is reduced and water quality conditions improve, algae will diminish in abundance and water clarity will improve, and the shallow areas of the lake will become excellent habitat for increased growth of submerged aquatic vegetation (SAV).
SAV is a critical component of a healthy lake and important habitat for juvenile fish and invertebrates. Additionally, SAV serves to precipitate suspended solids and assimilates nutrients that may otherwise be taken up by algae for growth. Still, elevated levels of SAV may prove to hinder recreational use of the lake.
The Plan for Lake Latonka recommends regular SAV surveys in order to monitor densities, document species composition, and ensure proper management. As SAV increases, pragmatic, measured management will be recommended to maintain an optimal balance of plant growth while allowing for recreational lake access.
Resident populations of Canada Goose (Branta canadensis) contribute acute sources of nitrogen, phosphorus, and bacteria to lakes via waste products.
Using loading coefficients derived from scientific literature, in combination with Canada geese population surveys, the team determined the approximate phosphorus load being contributed by the resident goose population each year is 88.6 lbs per year.
The Plan recommends a variety of deterrent/harassment actions as permitted through Federal and State agencies in order to minimize the resident population of these waterfowl.
The Management Plan also provided recommendations for routine water quality monitoring related to nutrient concentrations, algal types and densities, and safety for lake users. Lake monitoring helps track changes in water quality over time and is utilized to objectively assess the impacts of prescribed management measures. In this manner, monitoring can help to address potential issues before they become large problems.
Specifically, Princeton Hydro recommended growing season monitoring, which entails monitoring for five months each year, in order to build a lake water quality database for nutrients, in-situ measures, and plankton. Additionally, the team recommends robust contact testing at the beach and open water for E. coli sampling, fecal coliform, and cyanotoxins.
When monitoring and managing the health of a lake or pond, dissolved oxygen is one of the most important indicators of water quality. Dissolved oxygen refers to the level of free, non-compound oxygen present in water. It is an important parameter in assessing water quality because of its influence on the organisms living within a body of water; the vast majority of aquatic life needs sufficient amounts of oxygen dissolved in water in order to survive.
Pollutants, the decomposition of invasive aquatic weed growth, and algae blooms significantly reduce dissolved oxygen. The purpose of aeration in lake management is to increase the concentrations of dissolved oxygen in the water. Aeration systems achieve these water quality improvements by helping prevent stagnation of water, increasing circulation, disrupting thermal stratification which provides “through-column” mixing, and minimizes the occurrence of harmful algal blooms (HABs).
Princeton Hydro has been working with the Lake Hopatcong Commission and Lake Hopatcong Foundation to implement several projects aimed at reducing the impacts of HABs in Lake Hopatcong, including the installation of three innovative aeration systems in different areas of the lake. Funding for these projects have come from a NJ Department of Environmental Protection Water Quality Restoration HAB grant awarded to the Commission in 2020, with additional funding and support coming from the Foundation, Morris and Sussex Counties, and four municipalities that surround Lake Hopatcong.
Our team completed the installation of an air curtain system at Shore Hills Country Club in Roxbury Township in early November 2020. The system produces a wall of bubbles that provide the kinetic energy to push and deflect away floating cyanobacteria and other toxins trying to enter the waterway. Installed near the shoreline, the air curtain increases the movement of the water, making it more difficult for floating debris, pollutants, and HABs to accumulate near the shore and in nearby shallow water areas.
Nanobubbles are extremely small gas bubbles that have several unique physical properties that make them very different from normal bubbles. Nanobubble aerators directly saturate the water with significantly more oxygen than traditional water aeration systems. These systems produce ultra-fine bubbles that are nearly invisible to the human eye. Unlike “traditional” aeration systems that push air bubbles to the surface in order to circulate the water and increase the dissolved oxygen levels, nanobubbles are so small that they remain within the water column for an extended period of time, directly oxygenating the water. Our team is scheduled to complete a nanobubble system install for Lake Hopatcong in the Spring of 2021.
At Lake Hopatcong’s Lake Forest Yacht Club in Jefferson Township, our team installed a Nanobubble System with Ozone, which was completed in November 2020. This system generates ultrafine microbubbles (nanobubbles) containing ozone, which is used to disinfect water supplies and works to break down organic material in the water. These nanobubbles harness the unique biocidal power of ozone and place it into a safe delivery mechanism that is highly effective but also ensures human and environmental safety. The resulting ozone nanobubbles eliminate a wide range of polluting chemicals as well as herbicides, pesticides, and microbial toxins, which are all known causes of HABs.
The nanobubble technology is a relatively new strategy for preventing cyanobacteria blooms. Evaluation of the air curtain and both nanobubble systems in controlling and minimizing HABs in Lake Hopatcong will begin in Spring 2021. Our team will closely monitor the effectiveness throughout the 2021 season and provide detailed reports of our findings. Stay tuned for more info!
Increasing the dissolved oxygen levels in a pond or lake provides many benefits including improved water quality, healthier fish and plants, more efficient filtration, and reduced nuisance algae growth. To learn more about Princeton Hydro's collaborative efforts to protect our valuable water resources, click here.
July is Lakes Appreciation Month - a great time of year to enjoy your community lakes and help protect them.
Lakes Appreciation Month was started by North American Lake Management Society (NALMS) to help bring attention to the countless benefits that lakes provide, to raise awareness of the many challenges facing our waterways, and to encourage people to get involved in protecting these precious resources.
“You work and play on them. You drink from them. But do you really appreciate them? Growing population, development, and invasive species stress your local lakes, ponds, and reservoirs. All life needs water; let’s not take it for granted!” - NALMS
Chemical pollutants, stormwater runoff, hydrocarbons, invasive aquatic species, and climate change are just a few of the the serious threats facing lakes and other freshwater habitats. So what can you do to to help?
We’ve put together six tips to help you celebrate Lakes Appreciation Month and get involved in protecting your favorite lakes:
The “Secchi Dip-In” is an annual citizen science event where lake-goers and associations across North America use a simple Secchi disk to monitor the transparency or turbidity of their local waterway. Created and managed by NALMS, volunteers have been submitting information during the annual Dip-In since 1994. Get all the Dip-In details here.
With the BloomWatch App, you can help the U.S. Environmental Protection Agency understand where and when potential harmful algae blooms (HABs) occur. HABs have the potential to produce toxins that can have serious negative impacts on the health of humans, pets, and our ecosystems. Click here to learn more and download the app here. For more information on HABs, check out our recent blog.
Commit to keeping your lake clean: Volunteers play a major role in maintaining the health and safety of community waterways. If you’re interested in helping to conserve and protect your water resources, you can start by cleaning up trash. Choose a waterbody in your community; determine a regular clean-up schedule; and stick to it! Cleaning your neighborhood storm drains really helps too; click here to find out how.
You can help support your favorite lake by joining or donating to a lake or watershed association. As an organized, collective group, lake associations work toward identifying and implementing strategies to protect water quality and ecological integrity. Lake associations monitor the condition of the lake, develop lake management plans, provide education about how to protect the lake, work with the government entities to improve fish habitat, and much more.
There are countless ways to enjoy and appreciate your community lakes. During Lakes Appreciation month, take photos that illustrate how you appreciate your community lakes, share them on social media using the hashtag: #LakesAppreciation, and hopefully you’ll inspire others to show their Lake Appreciation too.
NALMS invites you to participate in its social media photo contest, titled "Show Your Lakes Appreciation Challenge." To participate: Take a picture of yourself or someone you know enjoying or working on a lake or reservoir during July. And, upload the photo to Facebook, Instagram and/or Twitter using a descriptive caption and the #LakesAppreciation hashtag. Three winners will be determined via a raffle and announced via social media on Monday, August 3rd. Learn more.
To ensure you’re staying safe while participating in Lakes Appreciation Month and all outdoor activities, please be sure to follow local regulations and the CDC's recommended COVID-19 guidelines.
To learn more about NALMS and get more ideas on how to celebrate your local lakes, go here: https://www.nalms.org. If you’re interested in learning more about Princeton Hydro’s broad range of award-winning lake management services, go here: http://bit.ly/pondlake.
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Harmful Algae Blooms (HABs) were in the spotlight this summer due to the severe impacts they had on lakes throughout the country. The nation-wide HABs outbreak caused beach closures, restricted access to lake usage, and wide-ranging health advisories.
What exactly are HABs? Why were they so severe this summer? Will this trend continue? Can anything be done to prevent the occurrence or mitigate the impacts?
In this blog, we provide answers to all of those questions, exploring what HABs are, why they occur, why they were particularly prevalent this summer, and what we can do to combat them.
Simply put, HABs are rapid, large overgrowths of cyanobacteria. Cyanobacteria, also known as blue-green algae, aren’t actually algae, they are prokaryotes, single-celled aquatic organisms that are closely related to bacteria and can photosynthesize like algae. These microorganisms are a natural part of aquatic ecosystems, but, under the right conditions (primarily heavy rains, followed by hot, sunny days), these organisms can rapidly increase to form cyanobacteria blooms, also known as HABs.
HABs can cause significant water quality issues in lakes and ponds, often forming a visible and sometimes odorous scum on the surface of the water. They can produce toxins that are incredibly harmful (even deadly) to humans, animals, and aquatic organisms.
HABs also negatively impact economic health, especially for communities dependent on the income of jobs and tourism generated through their local lakes and waterways.
HABs are caused by a complex set of conditions, and many questions remain about exactly why they occur and how to predict their timing, duration, and toxicity. Primarily, HABs are caused by warmer temperatures and stormwater run-off pollutants, including fertilizers with phosphates.
HABs are induced by an overabundance of nutrients in the water. The two most common nutrients are fixed nitrogen (nitrates and ammonia) and phosphorus. Discharges from wastewater treatment plants, runoff from agricultural operations, excessive fertilizer use in urban/suburban areas, and stormwater runoff can carry nitrogen and phosphorus into waterways and promote the growth of cyanobacteria.
Climate change is also a factor in HAB outbreaks, which typically occur when there are heavy rains followed by high temperatures and sunshine. Climate change is leading to more frequent, more intense rainstorms that drive run-off pollutants into waterways, coupled with more hot days to warm the water. These are the ideal conditions for HABs, which in recent years have appeared in more places, earlier in the summer.
With climate change and increasing nutrient pollution causing HABs to occur more often and in locations not previously affected, it's important for us to learn as much as we can about HABs so that we can reduce their harmful effects.
The number one thing individuals can do to protect their waterbodies and prevent HABs is to reduce phosphorous use and reduce nutrient loads to waters.
According to Dr. Fred Lubnow of Princeton Hydro, “Managing loads of phosphorous in watersheds is even more important as the East Coast becomes increasingly warmer and wetter thanks to climate change. Climate change will likely need to be dealt with on a national and international scale. But local communities, groups, and individuals can have a real impact in reducing phosphorous levels in local waters.”
Controlling stormwater runoff is another critical factor in improving water quality and reducing HABs. There are a number of low-cost green infrastructure techniques that can be implemented on an individual and community-wide scale. Click here to read more about green infrastructure stormwater management techniques.
In a recent Op/Ed published on NJ.com, Princeton Hydro President Geoffrey M. Goll, P.E. lists four things that residents, businesses, and local governments should do to prevent another HABs outbreak next summer:
"By making the necessary investments, we can simultaneously create jobs, reduce flood impacts, improve fisheries, maintain or increase lakefront property values, improve water quality and preserve our water-based tourism. The time to act is literally now," said Geoff. Go here, to read the full article.
Nitrogen and phosphorus are utilized by plants, which means they uptake these nutrients to sustain growth. We see this naturally occurring in wetland ecosystems where wetlands act as a natural water filtration system and can actually thrive from nutrients flowing in from external sources.
This process is replicated in floating wetland islands (FWIs), where you typically have a constructed floating mat with vegetation planted directly into the material. The plants then grow on the island, rooting through the floating mat.
Not only do FWIs assimilate and remove excess nitrogen and phosphorus out of the water, they also provide habitat for fish and other aquatic organisms; help mitigate wave and wind erosion impacts; provide an aesthetic element; and can be part of a holistic lake/pond management strategy. Because of this, FWIs are being utilized to improve water quality and control HABs in lakes and ponds throughout the country.
Princeton Hydro has designed and implemented numerous FWIs in waterbodies large and small. Go here to learn how they’re being used in Harveys Lake.
Recognizing and monitoring the changes that are taking place in our local waterways brings the problems of climate change, stormwater pollution and the resulting water quality issues closer to home, which can help raise awareness, inspire environmentally-minded action and promote positive, noticeable change.
If you spot what you believe to be HABs in your community lake, contact your local lake association right away. They, along with their lake management team, can assess the situation and determine what further actions need to be taken. For more information about HABs, click here.
The U.S. is home to thousands of lakes both natural and manmade. Lakes are incredibly important features in the landscape that provide numerous beneficial services, including domestic water supply, hydro-electric power, agricultural water supply, recreation, and tourism. They also provide essential habitat for fish, wildlife and aquatic organisms.
Lakes are complex and dynamic systems, each situated in a unique landscape context. Maintaining the ecological health of a lake is no easy feat. A lot goes on behind the scenes to maintain water quality and a balanced lake ecosystem. Successful, long-term lake management requires a proactive approach that addresses the causes of its water quality problems rather than simply reacting to weed and algae growth and other symptoms of eutrophication.
Chautauqua Magazine recently published an article about the science behind the management of Chautauqua Lake, which features our Director of Aquatic Programs Dr. Fred Lubnow. We’ve included an excerpt below. Click here to view the full article and photos:
Dr. Fred Lubnow is a scientist and director of aquatic programs at Princeton Hydro, a consulting organization based in Exton, Pennsylvania, that is often called on to support lake and watershed regions that want to develop a long-term plan for lake conservation. He says that while his firm focuses on the development of data and intelligence to inform decision making in regard to freshwater ecosystems, his work is really about coalition building. "As a scientist and a consultant, you learn over time that you are building a coalition stakeholders and determining what we can agree on to help everyone in the community," Lubnow said. Ten years ago, Princeton Hydro was hired to do some stream and inlet monitoring for various stakeholders at Chautauqua Lake. More recently, they've been contracted to conduct third-party monitoring of the impacts of the Spring 2019 herbicide applications in the south basin of Chautauqua Lake... Continue reading!
Dr. Fred Lubnow is a scientist and director of aquatic programs at Princeton Hydro, a consulting organization based in Exton, Pennsylvania, that is often called on to support lake and watershed regions that want to develop a long-term plan for lake conservation.
He says that while his firm focuses on the development of data and intelligence to inform decision making in regard to freshwater ecosystems, his work is really about coalition building.
"As a scientist and a consultant, you learn over time that you are building a coalition stakeholders and determining what we can agree on to help everyone in the community," Lubnow said.
Ten years ago, Princeton Hydro was hired to do some stream and inlet monitoring for various stakeholders at Chautauqua Lake. More recently, they've been contracted to conduct third-party monitoring of the impacts of the Spring 2019 herbicide applications in the south basin of Chautauqua Lake...
Princeton Hydro is the industry leader in lake restoration and watershed management. We have conducted diagnostic studies and have developed management and restoration plans for over 300 lakes and watersheds throughout the country. This has included work for public and private recreational lakes, major water supply reservoir, and watershed management initiatives conducted as part of USEPA and/or state funded programs. For more information about our lake management services, go here: http://bit.ly/pondlake.
Collaboration between state agencies and local organizations in Luzerne County bring in grant money to determine Hydrilla infestation levels in Harveys Lake. Treatment efforts are scheduled for 2019.
Story provided by Princeton Hydro Senior Limnologist Michael Hartshorne, and originally published in the Pennsylvania iMapInvasives Fall 2018 Newsletter
Harveys Lake, located in the Borough of Harveys Lake (Luzerne County) is a large, deep glacial lake with limited littoral (i.e., shoreline) habitat. A significant body of work has been conducted at the lake with the original Phase I: Diagnostic-Feasibility Lake study conducted in 1992 and a Total Maximum Daily Load (TMDL) issued for phosphorus in 2002.
From 2002 to present, Princeton Hydro has assisted the Borough in the restoration of the lake with a heavy focus on stormwater best management practices (BMPs) supplemented by routine, in-lake water quality monitoring. The goal of the storm water/watershed-based efforts was to reduce the lake’s existing, annual total Hydrilla (Hydrilla verticillata) phosphorus load so it’s in full compliance with the established TMDL.
Over the last 15 years, the installation of these watershed-based projects has led to improved water quality conditions; specifically, phosphorus and algae concentrations have been reduced. While water quality conditions improved Harveys Lake, it was during one of the routine, summer water quality monitoring events conducted in July 2014 that a dense stand of hydrilla was noted at the Pennsylvania Fish and Boat Commission’s public boat launch. More than likely, the plant entered the lake as a “hitchhiker” on the boat or trailer being launched from this public boat launch by someone visiting the lake.
Since the initial identification and confirmation of the hydrilla, the Borough of Harveys Lake has worked in conjunction with the Harveys Lake Environmental Advisory Council, the Luzerne County Conservation District, the Pennsylvania Department of Environmental Protection, and Princeton Hydro to secure funding for additional surveys to determine the spatial extent and density of growth followed by an aggressive eradication plan.
Grant funds already allocated to Harveys Lake under the state’s Non-Point Source Pollution Program were used to conduct a detailed boat-based and diving aquatic plant survey of Harveys Lake to delineate the distribution and relative abundance of the hydrilla in 2014. During these surveys, the distribution of the hydrilla was found to be limited to the northern portion of the lake with the heaviest densities just off the boat launch with plants observed growing in waters 20-25 feet deep.
A follow-up survey had shown hydrilla coverage to increase from 38% of surveyed sites to 58% of sites in 2016 with hydrilla now present at the lake’s outlet area. Spatial coverage of hydrilla increased from approximately 50 acres in 2014 to 210 acres in 2016, an increase of 160 acres.
In hopes of preventing hydrilla escaping into the lake’s outlet stream, the Borough of Harveys Lake funded an emergency treatment of the two-acre outlet area in 2016 utilizing the systemic herbicide Sonar® (Fluridone). A follow-up treatment of 159 acres was conducted in 2017, again utilizing the Fluridone-based systemic herbicide.
The next treatment, which will attempt to cover the majority of the littoral habitat covered by hydrilla, is scheduled for late spring/early summer of 2019. It should be noted that Sonar® is being applied at a low concentration that is effective at eradicating the hydrilla, but will not negatively impact desirable native plant species.
The treatments conducted to date have documented some reductions in the vegetative coverage of hydrilla as well as tuber production relative to the original plant surveys conducted in 2016. However, it is recognized that it will take multiple years of treatment to eradicate this nuisance plant from the lake, as well as a highly proactive, interactive program to educate residents as well as visitors to the lake in preventing the re-introduction of this or other invasive species to Harveys Lake.
The successful, long-term improvement of a lake or pond requires a proactive management approach that addresses the beyond simply reacting to weed and algae growth and other symptoms of eutrophication. Our staff can design and implement holistic, ecologically-sound solutions for the most difficult weed and algae challenges. Visit our website to learn more about Princeton Hydro's lake management services: http://bit.ly/pondlake
Michael Hartshorne's primary areas of expertise include lake and stream diagnostic studies, TMDL development, watershed management, and small pond management and lake restoration. He is particularly skilled in all facets of water quality characterization, from field data collection to subsequent statistical analysis, modeling, technical reporting, and the selection and implementation of best management practices. He has extensive experience in utilizing water quality data in concert with statistical and modeling packages to support load reduction allocations for the achievement of water quality standards or tailored thresholds set forth to reduce the rate of cultural eutrophication. He also has significant experience in conducting detailed macrophyte, fishery, and benthic surveys.
The Lake Hopatcong Foundation (LHF) recently launched its newest initiative - a floating classroom. The custom-built 40-foot education vessel, named 'Study Hull', gives students an interactive, hands-on education experience to explore Lake Hopatcong, learn about freshwater ecology, and learn how to protect the watershed.
During its maiden voyage field trip, which was held on May 21, fourth-graders from Nixon Elementary and Kennedy Elementary schools utilized the boat’s laboratory instruments to study water hydrology, temperatures, plankton, and dissolved oxygen levels. They performed a series of tests and experiments designed to help them learn about the general health of the lake. They used Secchi Disks to determine the depth to which light is able to penetrate the water's surface. They also learned about runoff and nonpoint source pollutants, how to protect the lake’s water quality, and how to be good stewards of the water.
Princeton Hydro helped the LHF design a teaching curriculum on water quality. Dr. Jack Szczepanski, Senior Aquatics Scientist, and Christopher L. Mikolajczyk, CLM, Senior Project Scientist, trained the staff and volunteers on the curriculum and demonstrated various water quality monitoring techniques that can be conducted with the students.
“We’re really proud to be a part of this exciting initiative,” said Mikolajczyk. “It’s really important to get kids interested in science at an early age and teach them about their surrounding environment – where their drinking water comes from, how it gets polluted, the impacts pollution has on the lake’s ecosystem, and what steps can be made to protect the lake’s water quality. We're hoping the floating classroom field trip program will make a lasting, valuable impression with these kids.”
In the first year of operation it is expected that the Study Hull will host 1,000 fourth grade students. The long-term goal is to develop lesson plans for students in every grade from kindergarten through high school. Starting in July, the LHF is also offering the public tours of the floating classroom on Mondays at Hopatcong State Park.
The purchase of the floating classroom was made possible by financial support from USATODAY Network’s “A Community Thrives” program, which awarded the LHF with a $50,000 grant. The program recognizes three categories: arts and culture, education, and wellness. In each category, the first place winner received a $100,000 grant and the second and third place winners received $50,000 grants. The James P. Verhalen Family Foundation and the Szigethy Family also provided significant donations to help bring the floating classroom to life.
The LHF and Princeton Hydro are longtime partners. Starting back in 1983, Princeton Hydro’s Dr. Stephen Souza conducted the USEPA funded Diagnostic Feasibility study of the lake and then authored the Lake Hopatcong Restoration Plan. That document continues to be the backbone of why and how to restore the lake, manage the watershed, reduce pollutant loading, and address invasive aquatic plants and nuisance algae blooms.
Lake Hopatcong has one of the longest, continuous, long-term ecological databases in New Jersey; almost 30 years of consistently collected water quality data. The data is crucial in assessing the overall ecological health of the lake and proactively guiding its management, identifying and addressing emerging threats, documenting project success (a mandatory element of funding initiatives) and confirming compliance with New Jersey State Water Quality standards.
Princeton Hydro’s most recent work for Lake Hopatcong includes the implementation of green infrastructure stormwater management measures, installation of floating wetland islands to improve water quality, and invasive aquatic plant species management programs, community educational training, and surveys.
For more information about the Lake Hopatcong Foundation or the floating classroom, click here. For more information about Princeton Hydro’s lake management services, go here.
The Western New York Harmful Algal Blooms (HABs) Summit, the last of four Statewide HABs summits, was held last month in Rochester, NY. The summits kicked off Governor Cuomo’s $65 million initiative to protect the NY State’s lakes, ponds and reservoirs, and those that rely on these waterbodies for recreation and drinking water, from the ecological and health impacts associated with HABs.
"Protecting New York's natural resources is key to ensuring residents have access to safe water, and through this collaborative summit, we are addressing the growing threat of harmful algal blooms," said Governor Cuomo in a recent press release.
Each regional summit involved a day-long session of expert presentations and panel discussions on a variety of HAB related topics, and culminated in an evening session, which was open to the public and provided community members an opportunity to learn more about the Governor’s initiative and pose questions to NYSDEC about HABs and the management of HABs. The evening sessions were available to view via a live online stream as well.
For each summit, the Governor invited regional experts to participate along with NYSDEC and Department of Health experts. The experts were brought together to initiate the development of tailored HAB action plans. Although the focus was placed on the management of Governor Cuomo’s 12 priority waterbodies, the goal was to identify HAB management plans applicable for all of the State’s waterbodies, large or small. The discussions that evolved through the four summits set the stage to inform decisions related to preventing and properly responding to HABs across the state.
Participating by the invitation of Governor Cuomo and the NYSDEC in last month’s Western New York Summit were:
During the Western New York Summit, Dr. Souza, Princeton Hydro co-founder, provided insight on the causes of HABs and, in particular, discussed the management techniques that have been successfully implemented by Princeton Hydro to combat the onset and mitigate the impacts of HABs.
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