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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 ) [1] => 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 ) [2] => 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:
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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The City of Elizabeth, the fourth most populous in New Jersey, is not exactly the first place that comes to mind when envisioning a wild landscape. This bustling urban area is well known for its Port Newark-Elizabeth Marine Terminal and the Philips 66 Bayway Refinery, and sits at the intersection of several major roadways like the NJ Turnpike and the Goethals Bridge. The landscape, which was once teeming with dense wetlands and associated habitats, is now heavily urbanized with a vast mix of residential, commercial, and industrial properties. The largely channelized Elizabeth River courses through the city for 4.2 miles before draining into the Arthur Kill waterway. However, in this 14-square mile city, native flora and fauna are taking root again thanks to ecological restoration and mitigation efforts.
Urban landscapes like Elizabeth can pose significant challenges for restoration efforts, but they also provide an array of opportunity for significant ecological uplift.
In 2004, Princeton Hydro was retained to restore an 18-acre site adjacent to the Elizabeth Seaport Business Park, which is located in an area that was once part of a large contiguous wetland system abutting Newark Bay. The site was comprised of a significantly disturbed mosaic of wetland and upland areas and a monoculture of Phragmites australis, also known as Common Reed, on historic fill. Historic fill consists of non-native material, historically placed to raise grades, and typically contains contaminated material not associated with the operations of the site on which it was placed.
The highly invasive Phragmites australis had overtaken most of the wetland areas, and the upland woodland areas only contained four tree species, mostly Eastern Cottonwood, with very low wildlife value. The 18-acre site had huge potential but was significantly degraded and was being vastly underutilized. Overall, the mitigation plan focused on the enhancement of existing wetland and transition areas to increase the area’s wildlife value through the establishment of a more desirable, diverse assemblage of native species subsequent to eradication of non-native-invasive species.
The freshwater wetland aspect of the mitigation plan, which included inundated emergent, emergent, and forested habitat, was designed to be a combination of wetland creation (2.40 acres) and enhancement (8.79 acres), emphasizing the establishment of more species rich wetlands in order to increase biodiversity and improve the site’s wildlife food value.
The upland forest aspect of the mitigation plan involved the enhancement of 5.40 acres and creation of 1.45 acres of upland forest to foster the development of a species rich and structurally complex upland forest. The upland areas targeted for enhancement/creation consisted of areas where woody vegetation was lacking or forested areas that were dominated by eastern cottonwood.
The project team worked to remove Phragmites australis from the site utilizing a combination of herbicide and mechanical removal techniques. Once the Phragmites australis was cleared, the team installed 27,000 two-inch native herbaceous plant plugs in the wetland portions of the mitigation site, and 2,705 native trees/shrubs throughout the site.
In order to ensure the continued success of the mitigation project, monitoring is regularly conducted at the site. A monitoring report conducted at the end of 2019 revealed a plethora of well-established habitat areas, a diverse community of plant and tree species, and a thriving, highly-functional landscape.
Presently, the Elizabeth Seaport Business Park Mitigation Site boasts a variety of productive wildlife habitats that are rare in a highly urbanized setting and provides valuable ecosystem services, including sediment retention and roosting, foraging, and nesting opportunities for both resident and migratory bird species with over 150 bird species identified within the mitigation site.
This project serves as an example of how degraded urban areas can be successfully rehabilitated and the land’s natural function restored and enhanced. If you'd like to learn more about this project from our Natural Resources Senior Project Manager Michael Rehman, check out the video of his presentation at the 2020 Delaware Wetlands Conference below.
If you're interested in learning more about our wetland restoration and mitigation services, go here!
The City of Linden, located 13 miles southwest of Manhattan in Union County, New Jersey, is a highly urbanized area with a complex mix of residential, commercial, and industrial land uses. Originally settled as farmland on broad marshes, the City has deep roots in industrial production that emerged in the 19th century, and its easily accessible location on the Arthur Kill tidal straight helped fuel this industrial development.
Now, the City of Linden, which is home to more than 40,000 people, is considered a transportation hub: it has three major highways running through it (the New Jersey Turnpike, Route 1, and Route 27); its rail station provides critical commuter and industry access; the Linden Municipal Airport is a gateway to the NY/NJ metropolitan area; and its access point on the Arthur Kill is used by shipping traffic to the Port Authority of NY and NJ.
Unfortunately, the industrial boom left a legacy of pollution in the city, so much, that the Tremley Point Alliance submited an official Envionmental Justice Petition to the state. In 2005, the New Jersey Environmental Task Force selected the community for the development of an Environmental Justice Action Plan and listed it as one of six environmental justice communites in New Jersey.
Like other communities in the Arthur Kill Watershed, Linden also suffers severe flooding from heavy rains and storms with one of the significant sources of flood water coming from stormwater runoff. Due to a high percentage of impervious cover from houses, roadways, and sidewalks, even small rain events generate a significant amount of stormwater runoff. Over time, these conditions have been exacerbated by the historic loss of coastal wetlands and outdated infrastructure. Nuisance flooding is especially problematic as runoff cannot drain from the area at a sufficient rate to prevent flooding during normal or elevated tidal conditions. Very simply, heavy rainfall is one factor contributing to recurring flooding.
In 2012, Hurricane Sandy caused wide-spread destruction throughout New Jersey and the entire eastern seaboard. The City of Linden was hard hit, and the City’s Tremley Point neighborhood was especially storm-ravaged. Tremley Point, a low-lying community of about 275 homes located at the headwaters of Marshes Creek and in the 100-year floodplain of the Rahway River, is regularly flooded during normal rain events. During Hurricane Sandy, local news outlets reported that a 15-foot tidal surge overtook Tremley Point homes, destroyed roads, and washed up hazardous material such as a 150-gallon diesel tank.
To help communities like Tremley Point recover, the New Jersey Department of Environmental Protection (NJDEP) launched the Blue Acres program under which NJDEP purchases homes from willing sellers at pre-Sandy market values, so residents in areas of repetitive and catastrophic flooding can rebuild their lives outside flood-prone areas. Structures are demolished and the properties are permanently preserved as open space for recreation or conservation purposes. The program began in 1995 and expanded with federal funding after Sandy. The goal of the Blue Acres Program is to dramatically reduce the risk of future catastrophic flood damage and to help families to move out of harm’s way.
As part of the NJDEP Blue Acres Program, Princeton Hydro, in collaboration with the City of Linden, Rutgers University, NJDEP, Phillips 66, National Fish and Wildlife Foundation, New Jersey Corporate Wetlands Restoration Partnership, and Enviroscapes, has undertaken one of the first ecological restoration projects within Blue Acres-acquired properties, which are located in the Tremley Point neighborhood. This project increases storm resiliency by reducing flooding and stormwater runoff by improving the ecological and floodplain function within the former residential properties acquired by the NJDEP Blue Acres Program.
The project includes the development and implementation of an on-the-ground green infrastructure-focused floodplain enhancement design involving the restoration of native coastal floodplain forest and meadow, as well as floodplain wetlands. The restored area provides natural buffering to storm surge and enhances floodplain functions to capture, infiltrate, store, and slow excess stormwater to reduce the risk of future flood damage. In addition, it restores natural habitat and provides public recreation access on NJDEP Blue Acres property.
The design includes re-planting the parcels and the installation of a walking path through part of the area. It also includes the creation of a floodplain bench for the adjacent drainage ditch, an unnamed tributary to Marshes Creek. A floodplain bench is a low-lying area adjacent to a stream or river constructed to allow for regular flooding in these areas. Site improvements include grading of the floodplain bench and minor depressional area; 6-12-inches of tilling, soil amendment, and planting within the planting area; and construction of the gravel pathway.
The project will result in valuable environmental and community benefits to the area, including an annual reduction in stormwater runoff of 4.1 million gallons. This represents a 45% reduction in stormwater runoff. Restoration of the floodplain will also help reduce community vulnerability to storms. The hope is that this project will be a model that fosters more floodplain restoration projects in the future.
For more information on the Blue Acres Program, please visit the DEP website.
There are lots of things we can do to preserve our precious water resources. Reducing stormwater pollution in our neighborhoods is something everyone can take part in. Storm drain cleaning is a great place to start!
Urbanization has fundamentally altered the way that water moves through the landscape. Stormwater that doesn’t soak into the ground runs along streets and parking lots and picks up pollutants. Much of the pollution in our nation’s waterways comes from everyday materials like fertilizers, pesticides, motor oil, and household chemicals. Rainwater washes these substances from streets, yards and driveways into storm drains.
It’s a common misconception that storm drains lead to wastewater treatment plants. In actuality, storm drains rarely lead to treatment plants and instead stormwater systems carry untreated water directly to the nearest waterway. This polluted runoff can have negative impacts on water quality, overstimulate algal growth (both toxic and non-toxic), harm aquatic species and wildlife, and cause trash and debris to enter our lakes, streams, rivers and oceans.
We can all do our part to improve and preserve water resources in our community and beyond! Keeping neighborhood storm drains cleaned is one simple step. Removing debris that collects in nearby stormwater catch basins, storm drains and along curbs promotes cleaner runoff, reduces the potential for flooding, and decreases the amount of pollution and trash entering our waterways.
Follow these simple steps for DIY storm drain cleaning:
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.
Are you a consultant, planner, municipal representative, community leader, or project manager seeking to learn more about Green Stormwater Infrastructure & Management Techniques? This one-day course is for YOU!
Green infrastructure techniques have increasingly become the “go to” strategy to address flooding, water quality, and environmental impacts caused by stormwater runoff. Whether it be rain gardens or regional bioretention basins, infiltration basins or other large-scale bio engineered BMPs, green infrastructure is being implemented everywhere from suburban subdivisions to urban redevelopment sites. Unfortunately, while growing popular, these techniques are often misapplied, improperly constructed, or inadequately maintained.
This innovative one-day class focuses on the proper design and implementation of green infrastructure BMPs, as well as their special maintenance requirements. The course curriculum includes interactive presentations, case studies and project examples.
Dr. Stephen Souza, Princeton Hydro Co-Founder and President of Clean Waters Consulting, LLC, is the faculty coordinator for the course, which also features a lecture by Princeton Hydro's Green Infrastructure Practice Area Leader Dr. Clay Emerson, PE, CFM.
Princeton Hydro is proud to partner with Montclair State University and take part in this valuable continuing professional education course. We hope to see you there!
Walking through a park isn’t always a walk in the park when it comes to conducting stormwater inspections. Our team routinely spots issues in need of attention when inspecting stormwater infrastructure; that’s why inspections are so important.
Princeton Hydro has been conducting stormwater infrastructure inspections for a variety of municipalities in the Mid-Atlantic region for a decade, including the City of Philadelphia. We are in our seventh year of inspections and assessments of stormwater management practices (SMPs) for the Philadelphia Water Department. These SMPs are constructed on both public and private properties throughout the city and our inspections focus on areas served by combined sewers.
Our water resource engineers are responsible for construction oversight, erosion and sediment control, stormwater facilities maintenance inspections, and overall inspection of various types of stormwater infrastructure installation (also known as “Best Management Practices” or BMPs).
Our knowledgeable team members inspect various sites regularly, and for some municipalities, we perform inspections on a weekly basis. Here’s a glimpse into what a day of stormwater inspection looks like:
The inspector starts by making sure they have all their necessary safety equipment and protection. For the purposes of a simple stormwater inspection the Personal Protection Equipment (PPE) required includes a neon safety vest, hard hat, eye protection, long pants, and boots. Depending on the type of inspection, our team may also have to add additional safety gear such as work gloves or ear plugs. It is recommended that inspectors hold CPR/First Aid and OSHA 10 Hour Construction Safety training certificates.
Once they have their gear, our inspection team heads to the site and makes contact with the site superintendent. It’s important to let the superintendent know they’re there so that 1) they aren’t wondering why a random person is perusing their construction site, and 2) in case of an emergency, the superintendent needs to be aware of every person present on the site.
Once they arrive, our team starts by walking the perimeter of the inspection site, making sure that no sediment is leaving the project area. The team is well-versed in the standards of agencies such as the Pennsylvania Department of Environmental Protection, the Pennsylvania Department of Transportation, the New Jersey Department of Environmental Protection, and local County Soil Conservation Districts, among others. These standards and regulations dictate which practices are and are not compliant on the construction site.
After walking the perimeter, the inspection team moves inward, taking notes and photos throughout the walk. They take a detailed look at the infrastructure that has been installed since the last time they inspected, making sure it was correctly installed according to the engineering plans (also called site plans or drainage and utility plans). They also check to see how many inlets were built, how many feet of stormwater pipe were installed, etc.
If something doesn’t look quite right or needs amending, our staff makes recommendations to the municipality regarding BMPs/SMPs and provides suggestions for implementation.
One example of an issue spotted at one of the sites was a stormwater inlet consistently being inundated by sediment. The inlet is directly connected o the subsurface infiltration basin. When sediment falls through the inlet, it goes into the subsurface infiltration bed, which percolates directly into the groundwater. This sediment is extremely difficult to clean out of the subsurface bed, and once it is in the bed, it breaks down and becomes silt, hindering the function of the stormwater basin.
To remedy this issue, our inspection team suggested they install stone around the perimeter of the inlet on three sides. Although this wasn’t in the original plan, the stones will help to catch sediment before entering the inlet, greatly reducing the threat of basin failure.
Once they’ve thoroughly inspected the site, our team debriefs the site superintendent with their findings. They inform the municipality of any issues they found, any inconsistencies with the construction plans, and recommendations on how to alleviate problems. The inspector will also prepare a Daily Field Report, summarizing the findings of the day, supplemented with photos.
In order to conduct these inspections, one must have a keen eye and extensive stormwater background knowledge. Not only do they need to know and understand the engineering behind these infrastructure implementations, they need to also be intimately familiar with the laws and regulations governing them. Without these routine inspections, mistakes in the construction and maintenance of essential stormwater infrastructure would go unnoticed. Even the smallest overlook can have dangerous effects, which is why our inspections team works diligently to make sure that will not happen.
Our team conducts inspections for municipalities and private entities throughout the Northeast. Click here to read about a stormwater utility investigation and feasibility study we completed in the Town of Hammonton, New Jersey.
People generally think of green infrastructure as an eco-friendly way to handle stormwater runoff. While many green infrastructure elements are planned and managed specifically for stormwater control, the capabilities and benefits are far reaching. In this piece, we’ll provide an in-depth look at all that green infrastructure encompasses, best practices, and real-world examples of green infrastructure projects in action.
Defined as an approach to water management that protects, restores, or mimics the natural water cycle, green infrastructure can be implemented for large scale projects and small scale projects alike.
Unlike conventional, or “gray” infrastructure, green infrastructure uses vegetation, soil, and other natural components to manage stormwater and generate healthier urban environments. Green infrastructure systems mimic natural hydrology to take advantage of interception, evapotranspiration and infiltration of stormwater runoff at its source. Examples include permeable pavers, rain gardens, bioretention basins, rain barrels, and tree boxes.
Green infrastructure provides various benefits, including cleaning and conserving water, reducing flooding, improving public health, providing jobs, beautifying neighborhoods, supporting wildlife and providing economic benefits at both the larger community and individual household level. Let’s take a closer look at some of the primary benefits:
Prevents Flooding: By absorbing and slowing the flow of water, green infrastructure can reduce the burden on storm sewer systems and mitigate localized flooding.
Saves Money: While some green infrastructure designs may require the same or greater initial investment than conventional strategies, green design methods provide a big return in reducing costs over the long-term.
Improves Water Quality: Through natural absorption and filtration processes, green infrastructure significantly reduces stormwater runoff volume, decreases the pollutants and particulates within the stormwater, and improves the quality of the runoff flowing into surrounding water bodies.
Improves Air Quality: Green infrastructure techniques like tree boxes, green roofs and vegetative barriers have long been associated with improving air quality. Urban tree boxes help shade surfaces, effectively putting moisture into the air while reducing greenhouse gases. Trees mitigate heat and air pollution, both cooling and cleaning the air.
Enhances Aesthetics: Many green infrastructure practices utilize native plants and trees to improve runoff absorption and reduce stormwater pollution. This vegetation can provide a sound barrier or privacy screen for properties, and enhances the overall aesthetics of the surrounding environment.
Increases Property Values: Research shows that property values increase when trees and other vegetation are present in urban areas. Planting trees can increase property values by as much as 15%.
With the use of proper design techniques, green infrastructure can be applied almost anywhere and is especially beneficial in urban areas. In developed environments, unmanaged stormwater creates two major issues: one related to the volume and timing of stormwater runoff (flooding) and the other related to pollutants the water carries. Green Infrastructure in urban environments can recharge groundwater, decrease runoff, improve water quality, and restore aquatic habitats while controlling flooding.
Across the United States, more than 700 cities utilize combined sewer systems (CSS) to collect and convey both sanitary sewage and stormwater to wastewater treatment facilities. During dry weather, all wastewater flows are conveyed to a sewage treatment plant where it receives appropriate treatment before it is discharged to the waterway. However, during heavy rainfall or significant snowmelt, the additional flow exceeds the capacity of the system resulting in a discharge of untreated sewage and stormwater to the waterway; this discharge is referred to as a combined sewer overflow (CSOs). For many cities with CSS, CSOs remain one of the greatest challenges to meeting water quality standards. Green infrastructure practices mimic natural hydrologic processes to reduce the quantity and/or rate of stormwater flows into the CSS.
New Jersey, as part of the 2012 USEPA’s Integrated Municipal Stormwater and Wastewater Planning Approach Framework, utilized green infrastructure as one of the main components in managing its CSS and reducing CSOs. Because of the flexibility of green infrastructure in design performance, it can reduce and mitigate localized flooding and sewer back-ups while also reducing CSOs. An integrated plan that addresses both overflows and flooding can often be more cost-effective than addressing these issues separately. New Jersey, in addition to meeting its CSO reduction goals, is using green infrastructure throughout the sewershed to build resilience to large storm events and improve stormwater management.
Philadelphia takes advantage of numerous green stormwater infrastructure programs such as Green Streets, Green Schools, and Green Parking. There are a wide variety of green infrastructure practices that Philadelphia is using to decrease stormwater runoff throughout the entire city. After just five years of implementing the Green City, Green Waterplan, Philadelphia has reduced the stormwater pollution entering its waterways by 85%. Using over 1,100 green stormwater tools (i.e. CSO, living landscapes, permeable surfaces, etc.), in just one year, Philadelphia was able to prevent over 1.7 billion gallons of polluted water from entering their rivers and streams.
New York City is using a green infrastructure program, led by its Department of Environmental Protection, that utilizes multiple green infrastructure practices to promote the natural movement of water while preventing polluted stormwater runoff from entering sewer systems and surrounding waterbodies. While attaining this goal, the green infrastructure also provides improvements in water and air quality, as well as improves the aesthetics of the streets and neighborhoods. According to the NYC Green Infrastructure Plan, “By 2030, we estimate that New Yorkers will receive between $139 million and $418 million in additional benefits such as reduced energy bills, increased property values, and improved health.”
Green infrastructure techniques are extremely beneficial on every scale. Residential homes and neighborhoods can benefit from the implementation of green infrastructure in more ways than many people realize. There are a wide variety of green infrastructure projects that can be completed with a relatively small time and financial investment. Many of us at Princeton Hydro have incorporated green infrastructure practices into our homes and properties. Here’s a look at some of those projects in action:
Dr. Steve Souza, a founding principal of Princeton Hydro, installed rain gardens throughout his property utilizing native, drought-resistant, pollinator-attracting plants. The rain gardens are designed to capture and infiltrate rainwater runoff from the roof, driveway, patio and lawn.
Princeton Hydro's President Geoffrey Goll, P.E. built an infiltration trench in his backyard. An infiltration trench is a type of best management practice (BMP) that is used to manage stormwater runoff, prevent flooding and downstream erosion, and improve water quality in adjacent waterways.
Since its inception, Princeton Hydro has been a leader in innovative, cost-effective, and environmentally sound stormwater management systems. Long before the term “green infrastructure” was part of the design community’s lexicon, the firm’s engineers were integrating stormwater management with natural systems to fulfill such diverse objectives as flood control, water quality protection, and pollutant reduction. Princeton Hydro has developed regional nonpoint source pollutant budgets for over 100 waterways. The preparation of stormwater management plans and design of stormwater management systems for pollutant reduction is an integral part of many of the firm’s projects.
Interested in working with us on your next Green Infrastructure project? Contact us here.
Tucker is a Civil and Environmental Engineering major at Rowan University focusing on Water Resources Engineering. He is the President and player of the Rowan University Men's DII Ice Hockey Team. His Junior Clinic experience includes the study of Bio-Cemented sand and the Remote Sensing of Landfill Fires. In the future, Tucker hopes to work on creating a more sustainable environment. Tucker enjoys playing ice hockey, being with friends and family, and exercising.
Clay’s areas of expertise include hydrologic and hydraulic analysis, stormwater management and infiltration, nonpoint source (NPS) pollution, watershed modeling, groundwater hydrology/modeling, and water quality and quantity monitoring at both the individual site and watershed scales. His educational and work experience includes a substantial amount of crossover between engineering and environmental science applications. He has specific expertise in the field of stormwater infiltration and has conducted extensive research on the NPS pollution control and water quantity control performance of stormwater BMPs. He regularly disseminates his monitoring results through numerous peer-reviewed journal publications, magazine articles, and presentations.
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