We’re committed to improving our ecosystems, quality of life, and communities for the better.
Our passion and commitment to the integration of innovative science and engineering drive us to exceed on behalf of every client.
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Celebrating two decades of collaboration and innovation within the floodplain management community, the conference brought together more than 500 practitioners, researchers, agency staff, and industry leaders from across the Northeast. As the region’s premier floodplain management event, the NJAFM conference serves as a hub for sharing cutting-edge tools, best practices, and real-world strategies that help communities reduce flood risk, adapt to changing climate conditions, and build long-term resilience. Over the course of two days, participants attended educational sessions, hands-on training, and networking events centered on the theme: “NJAFM at 20 Years: Celebrate the Past, Focus on the Future.” Princeton Hydro was excited to return as a conference sponsor, exhibitor, and session presenter. Understanding the Role of Floodplain Management Floodplain management is a multidisciplinary practice that integrates planning, engineering, ecological science, and public policy to reduce flood risk while preserving the natural functions of riverine and coastal systems. At its core, it involves understanding how water moves across a landscape, identifying areas vulnerable to flooding, and implementing measures that protect people, infrastructure, and ecosystems. Floodplains provide a range of essential functions. Hydrologically, they convey, store, and infiltrate water during storm events, supporting natural flood attenuation, erosion control, and groundwater recharge. Ecologically, they contribute to biodiversity by providing habitat, migration corridors, and spawning areas for fish and wildlife. From a community perspective, well-managed floodplains can offer recreational value, improve water quality, and enhance the aesthetic and economic vitality of local neighborhoods. Modern floodplain management relies on both structural and non-structural approaches. Structural measures may include engineered solutions such as levees, floodwalls, culvert improvements, or stormwater system upgrades. Non-structural tools often involve land-use planning, flood-resilient building standards, conservation of open space, and community engagement programs that help residents understand risk and adopt best practices. Princeton Hydro works with municipalities, state agencies, nonprofit organizations, and watershed groups to develop and implement comprehensive floodplain management strategies across the region, emphasizing strategies that balance flood risk reduction with ecological enhancement, ensuring that floodplain management supports both resilient communities and healthy, functioning watersheds. [gallery link="none" columns="2" size="large" ids="18742,18741"] Pictured above: before and after photos from the Floodplain Restoration and Urban Wetland Creation project in Bloomfield Township, New Jersey. By removing a little over four acres of upland historic fill in this densely developed area and converting it into 4.2 acres of a functioning floodplain wetland, the project restored valuable ecological functions, enhances wetland and riparian zone habitat, and increases flood storage capacity for urban stormwater runoff. Technical Sessions Led by Princeton Hydro Our team led two workshops at the NJAFM 20th Annual Conference: Urban Flood and Habitat Resilience in the Lower Darby Creek Watershed Christiana Pollack, CERP, CFM, GISP, Princeton Hydro’s Director of Restoration and Resilience, presented on strategies to address chronic flooding and climate-driven impacts in Eastwick and Tinicum Township, Philadelphia. Her talk highlighted a two-year technical assessment commissioned by The Nature Conservancy in Pennsylvania and the John Heinz National Wildlife Refuge, and led by Princeton Hydro. The project combines integrated field data collection, advanced hydrologic and hydraulic modeling, and rigorous alternatives analysis to evaluate nature-based solutions. These include wetland creation or enhancement, stream and floodplain reconnection, and stormwater management retrofits, with the ultimate goal of restoring natural hydrologic function, reducing flood risk, and strengthening habitat and community resilience. Read more about the project here. Are You Hesitant to Pursue a Stormwater Utility? Elizabeth Treadway of WSP USA and Dr. Clay Emerson, PhD, PE, CFM, Senior Technical Director of Engineering at Princeton Hydro, led a session on the practical, legal, and financial considerations of establishing a stormwater utility, an increasingly vital tool for sustainable infrastructure funding. Participants learned:
Princeton Hydro was proud to participate in the New Jersey Association for Floodplain Management (NJAFM) 20th Annual Conference and Exhibition, held this fall in Atlantic City, NJ. Celebrating two decades of collaboration and innovation within the floodplain management community, the conference brought together more than 500 practitioners, researchers, agency staff, and industry leaders from across the Northeast.
As the region’s premier floodplain management event, the NJAFM conference serves as a hub for sharing cutting-edge tools, best practices, and real-world strategies that help communities reduce flood risk, adapt to changing climate conditions, and build long-term resilience. Over the course of two days, participants attended educational sessions, hands-on training, and networking events centered on the theme: “NJAFM at 20 Years: Celebrate the Past, Focus on the Future.”
Princeton Hydro was excited to return as a conference sponsor, exhibitor, and session presenter.
Floodplain management is a multidisciplinary practice that integrates planning, engineering, ecological science, and public policy to reduce flood risk while preserving the natural functions of riverine and coastal systems. At its core, it involves understanding how water moves across a landscape, identifying areas vulnerable to flooding, and implementing measures that protect people, infrastructure, and ecosystems.
Floodplains provide a range of essential functions. Hydrologically, they convey, store, and infiltrate water during storm events, supporting natural flood attenuation, erosion control, and groundwater recharge. Ecologically, they contribute to biodiversity by providing habitat, migration corridors, and spawning areas for fish and wildlife. From a community perspective, well-managed floodplains can offer recreational value, improve water quality, and enhance the aesthetic and economic vitality of local neighborhoods.
Modern floodplain management relies on both structural and non-structural approaches. Structural measures may include engineered solutions such as levees, floodwalls, culvert improvements, or stormwater system upgrades. Non-structural tools often involve land-use planning, flood-resilient building standards, conservation of open space, and community engagement programs that help residents understand risk and adopt best practices.
Princeton Hydro works with municipalities, state agencies, nonprofit organizations, and watershed groups to develop and implement comprehensive floodplain management strategies across the region, emphasizing strategies that balance flood risk reduction with ecological enhancement, ensuring that floodplain management supports both resilient communities and healthy, functioning watersheds.
Pictured above: before and after photos from the Floodplain Restoration and Urban Wetland Creation project in Bloomfield Township, New Jersey. By removing a little over four acres of upland historic fill in this densely developed area and converting it into 4.2 acres of a functioning floodplain wetland, the project restored valuable ecological functions, enhances wetland and riparian zone habitat, and increases flood storage capacity for urban stormwater runoff.
Our team led two workshops at the NJAFM 20th Annual Conference:
Christiana Pollack, CERP, CFM, GISP, Princeton Hydro’s Director of Restoration and Resilience, presented on strategies to address chronic flooding and climate-driven impacts in Eastwick and Tinicum Township, Philadelphia. Her talk highlighted a two-year technical assessment commissioned by The Nature Conservancy in Pennsylvania and the John Heinz National Wildlife Refuge, and led by Princeton Hydro. The project combines integrated field data collection, advanced hydrologic and hydraulic modeling, and rigorous alternatives analysis to evaluate nature-based solutions. These include wetland creation or enhancement, stream and floodplain reconnection, and stormwater management retrofits, with the ultimate goal of restoring natural hydrologic function, reducing flood risk, and strengthening habitat and community resilience. Read more about the project here.
Elizabeth Treadway of WSP USA and Dr. Clay Emerson, PhD, PE, CFM, Senior Technical Director of Engineering at Princeton Hydro, led a session on the practical, legal, and financial considerations of establishing a stormwater utility, an increasingly vital tool for sustainable infrastructure funding. Participants learned:
The session also addressed common challenges such as aging infrastructure, rapid development, and the growing frequency of severe storm events driven by climate change. Stormwater feasibility studies were highlighted as a key resource for evaluating costs and benefits before moving forward.
Managing stormwater effectively is essential for resilient infrastructure and community safety. Click here to learn about a Stormwater Utility Investigation & Feasibility Study we conducted for the Town of Hammonton, New Jersey.
Throughout the conference, our team was able to connect with planners, municipal officials, engineers, and local leaders at our exhibitor booth. These conversations offered valuable opportunities to discuss project experiences, share resources, and learn from others working to advance resilience across New Jersey.
Princeton Hydro is proud to be part of this community and remains committed to advancing science-based, equitable, and sustainable approaches to reducing flood risk. We look forward to continuing our partnership with NJAFM and supporting clients and communities in building a safer, more resilient future.
The Watershed Institute’s Annual Conference brings together municipal representatives, engineers, environmental professionals, watershed advocates, business leaders, and community members to advance the best available information and techniques for protecting and restoring watersheds. The program consists of a keynote discussion, exhibits, poster sessions and presentations that combine science, policy, and practical applications.
This year’s conference, focused on stormwater management in New Jersey, Municipal Separate Storm Sewer System (MS4) permit requirements, regional solutions to address stormwater runoff and flooding, environmental justice, and the need for community-wide action.
Princeton Hydro, a proud sponsor of the conference, led two presentations:
This presentation, given by Princeton Hydro Senior Technical Director of Ecological Services Dr. Fred Lubnow and One Water Consulting, LLC Principal Jim Cosgrove P.E., provided a basic understanding of Total Maximum Daily Loads (TMDLs), how they’re connected to Watershed Implementation Plan (WIP) requirements, and addressed how towns can best utilize Waste Load Allocations in the development of a WIPs.
This presentation was led by three members of the Princeton Hydro team: Senior Technical Director of Engineering Dr. Clay Emerson P.E., CFM; Vice President, Founding Principal Mark Gallagher; and Senior Director of Ecological Services Dr. Fred Lubnow. Participants learned about how to develop regional, multi-municipality plans for improving water quality and reducing flooding.
Other presentation topics included, “Understanding Water Quality in New Jersey,” “Stormwater Utilities for Community Members,” and “Youth Advocacy – Engaging the Next Generation in MS4.” You can view all the presentations from the 6th Annual Conference by clicking below:
Princeton Hydro is recognized as a leader in innovative, cost-effective, and environmentally sound stormwater management green infrastructure. We've been incorporating green infrastructure into our engineering designs since before the term was regularly used in the stormwater lexicon. Click here to learn how we designed a green infrastructure stormwater management system, on a 55-acre corporate campus, that is capable of containing on site nearly all the stormwater runoff generated by storm events up to and including a 100-year frequency, 24-hour duration storm:
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.
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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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