Research

The potential impacts of dynamic environmental conditions on military training and associated infrastructure are a growing challenge to our nation’s military readiness and U.S. Department of Defense (DoD) stewardship of its natural resources for warfare. DoD lands in the United States and abroad include a large number of installations in coastal settings that are most vulnerable to dynamic environmental drivers (e.g., rising sea level, increased temperatures, extended periods of drought or flood conditions, extreme storm events [i.e., tropical cyclones, Nor’easters].

To better manage DoD lands and their infrastructure and natural resource assets, it is imperative that installation managers have accurate research findings to inform their management decisions and prepare for future contingencies necessitated by these dynamic environmental drivers. In addition, installations will be faced with managing the tradeoffs between warfare preparedness as ecosystem service dependencies change associated with alterations to how water resources interact with soil and morphology at the coastal land margin. To balance military training and testing needs and sustainable natural resources management, installation managers need easy-to-use decision-support tools based upon dynamic computation models of landscape dynamics to assist them in making often complex, ecosystem-based management decisions.

• Task 1. Selecting and Monitoring Soil and Morphological Types Representative of Coastal Military Operations
• Task 2. Dynamic Computational Models of Tides, Surge and Winter Storms that Support Military Operations
• Task 3. Dynamic Computational Models of Ecogeomorphology and Ecosystem Dynamics that Support Military Operations
• Task 4. Dynamic Computational Models of Watershed Hydrology, Channel Flow, and Surface Exchange that Support Military Operations
• Task 5. Integrated Dynamic Computational Models for the Flood Transition Zone that Support Military Operations
• Task 6. Dynamic Ecosystem Design for more Resilient Military Operations

• Robert Twilley
• Clint Willson
• Chris Kees
• Peter Bacopoulos
• Andre Rovai
• Navid Jafari
• Celalettin Emre Ozdemir
• Kory Konsoer
• Shu Gao

The LSU Anticipating Threats to Natural Systems (ACTIONS) project funded by the Army is providing domain awareness of potential physical and chemical hazards in vulnerable natural terrestrial systems caused by flooding and coastal storm surges. The Collaborative Ecosystem Design technical approach of ACTIONS will be a tool in the Engineering with Nature® (EWN®) toolbox to inform military design strategies that incorporate ecosystem services (environmental, economic, social) to support mission resilience. Some of the terrains most susceptible to these challenges are coastal, and often co-located with military installations, megacities/urban zones, and industrial activities. DEEDS utilizes the science and technology produced in ACTIONS to develop engineering practices that make use of ecosystem design solutions, thus creating more sustainable future coastal terrains that directly support the resilience of military missions, operations, and land-use.

DEEDS embraces the Army’s EWN (Engineering With Nature) initiative within the U.S. Army Corps of Engineers and within the Coastal Ecosystem Design Studio at LSU. Military operations that have been impacted by coastal hazards and are in the process of rebuilding using EWN® approaches will be the focus of these continued efforts in DEEDS, such as Tyndall Air Force Base and other coastal zone bases impacted with more frequent flooding events. The collaboration proposed promotes innovative knowledge to improve national security, support military mission resilience, the resilience of communities around military installations, and economies of coastal states. Collaborative ecosystem designs will provide solutions in how alterations in soils, terrains, landscapes, and ecosystems affect military operations, personnel, and infrastructure on both short- and long-term time scales, including buildings, bridges, roads, and flood protection structures.

• Task 1. Designs and renderings of nature-based solution (NBS) for infrastructure and operations will be catalogued based on coastal typologies of the Gulf of Mexico that can contribute to reducing flood risks and generating environmental co-benefits at military operations. The library of NBS designs and prototypes will provide information that can be used in decision tools and expert systems based on robust project history associated with flood protection and ecosystem restoration in the Gulf of Mexico region.
• Task 2. Ecosystem designs of mangrove forests with traditional flood damage risk reduction assessments and co-benefits of blue carbon sequestration and water quality remediation.
• Task 3. Ecosystem designs of diverted sediment placement with large river management operations enhance flood risk reduction and produce environmental co-benefits with wetland platform formation.
• Task 4. Ecosystem designs of direct sediment placement to enhance flood risk reduction and environmental co-benefits with wetland platform formation.  
• Task 5. Ecosystem designs of environmental levees in combination with sediment placement as synergy for flood risk reduction and environmental co-benefits
• Task 6: Education and Outreach of NBS Designs: Student Training, Public Outreach and University Participation

• Robert Twilley
• Clint Willson
• Chris Kees
• Traci Birch
• Carol Friedland
• Peter Bacopoulos
• Andre Rovai
• Navid Jafari
• Celalettin Emre Ozdemir
• Kory Konsoer
• Shu Gao
• Fabiana Trinadade de Silva

In August 2016, a low-pressure system dropped 22-31" of rain in two days across Louisiana's capital region. Resultant flooding took 13 lives and caused damage to an estimated 156,000 structures. The region was brought to a standstill due to multi-day closures of I-10 and I-12, leading to transportation and economic disruption across the Gulf Coast. Touted as a "one-in-1,000-year flood" this was the third such event in 2016 to hit the southeastern US, and one of nine since 2010 (NOAA NWS, 2016). Climate change predictions indicate these severe precipitation events are likely to increase in frequency and intensity in the future (Prein et al., 2016).

Risks to inland communities in south Louisiana compound ongoing threats to coastal areas from extremely shallow topography, sea-level rise, land loss, and increased tropical storm intensities. Louisiana has lost nearly 1,900 square miles of coastal wetlands and is currently experiencing a land loss rate of over 16 square miles annually. As sea levels rise and shorelines erode, there is a growing recognition that retreat from the coast is preferred or required given significant fiscal, infrastructural, and social constraints on coastal settlement (CPRA 2012, LA OCD, 2015). The increasing convergence of inland and coastal communities (through coastal erosion, sea-level rise, rural to urban migration, and other factors) is a phenomenon Louisiana is experiencing on an unparalleled scale, though the issue is not unique to the state. Following the storms of the last decade, many residents moved away from the sea to reduce their risk - only to be flooded repeatedly from rain events over inland watersheds. 

Inland from the Coast is a multi-disciplinary research endeavor that uses environmental conditions modeling and community wellbeing research to inform building, community, and landscape design for ongoing flood recovery and long-term resilience across the greater Baton Rouge inland-coastal region. This project recognizes that effective stormwater management acknowledges and complements connections at all scales, ie: block, neighborhood, city, parish, and region. The project links university researchers with professional architects, landscape architects, planners, policy-makers, and community members to:

1. improve understanding of inland-coastal environmental conditions and vulnerabilities, 
2. define current and future community health + wellbeing, and
3. develop design and planning best practices for reducing risk and increasing regional adaptive capacity.

The project goal is to create a framework to restore and enhance community wellbeing in the face of extreme weather and climate change, and support adaptation strategies for sustainable futures. Climate change undermines the stability that communities have traditionally assumed existed. Projecting future environmental conditions, allowing communities to prioritize those elements of the community necessary for wellbeing, and applying both measures to improve the community response can vastly improve the future resilience of communities and the health of residents even as climate change brings greater risk. 

Community-based Reports

• Healthy & Resilient Baker
• Denham Springs Resilience

LSU Design Studio Books

• The Hungry River: Designing a Future for the Amite River’s Former Sand and Gravel Mines
• Spring Up! Denham Springs Masterplan
• Seeding the Sequence: Establishing Resilient Civic and Environmental Systems in the Gravel Mines of the Amite River

Other Resources

• Historical Changes in Planform Geometry of the Amite and Comite Rivers and Implications on Flood Routing
• Effects of Historical Land-use Change on Surface Runoff and Flooding in the Amite River Basin, Louisiana, USA Using Coupled 1D/2D HEC-RAS–HEC-HMS Hydrological Modeling
• A conceptual framework for phase-dependent, composite flood risk index (FRI) curves based on the relationship between temporal probability of flood occurring (PH) and flood vulnerability index (FVI) along with maps of FVI within the Amite River Basin based on the August 2016 Flood.

Principle investigators

• Traci birch
• Clint Wilson

Researchers

• Jeff Carney
• Katie Cherry
• Craig Colten
• Melissa Daigle
• Scott Hagen
• Brendan Harmon
• Aimee Moles
• Kim Mosby
• Marla Nelson
• Niki Pace
• Nicholas Serrano
• Rachelle Trahan
• Robert Twilley
• Jim Wilkins

Students

• Alec Cowles
• Adam Cox
• Austin Guerin
• Lindsey Henriques
• Debbie La Rue, AICP
• Dylan Roth

The Baton Roots farm and public art program at BREC Howell Community Park touches the lives of hundreds if not thousands of people, resulting in tens of thousands of pounds of food distributed to members of the community and thousands of hours of healthy outdoor activities, particularly important amidst a global pandemic.

The Recreation and Park Commission (BREC) for the Parish of East Baton Rouge connects people to parks and nature in Greater Baton Rouge area.  The system includes 180+ parks representing a wide variety of facilities such as an award-winning zoo, a performing arts center, an arboretum, an observatory, a swamp nature center, an equestrian park, a botanical park, a water park, a botanical garden, and five golf courses.  Since 2004 BREC has constructed dog parks, an aquatics center, an ever-growing off-road greenway trails system, fishing ponds and procured two mobile recreation units to serve play deserts in the area BRED covers. Howell Park in North Baton Rouge is part of this network and through a Cooperative Endeavor Agreement BREC has provided land access for Baton Roots.

Taking a holistic approach to community health, Baton Roots at BREC Howell Park envisions a world where local people are deeply rooted to the food they consume. The Baton Roots community farm brings access to healthy foods, outdoor experiences, and agriculture education to an area burdened by poverty, low-performing schools, crime, and unemployment. Infusing public art with fresh food access, Baton Roots works to improve quality-of-life, public safety, and economic development through year-round agriculture, health, and arts programming. Baton Roots’ hands-in-the-dirt approach works with communities to bring fresh and healthy food, grown in a visually stimulating and eco-friendly environment.

• Multiple community engagement opportunities to ensure the voices of local residents were heard
• Master Plan Report, including detailed visualizations of key components of the aspirational Baton Roots Arts Farm
• Architectural Plans for a Community Center at Howell Park (design studio taught by Kris Palagi)
• Reports on Food Insecurity in Baton Rouge (Urban Planning Course taught by Dr. Traci Birch)

Research Team

Nicholas Serano, Assistant Professor in Landscape Architecture at LSU, served as Primary Investigator and

Kris Palagi, Assistant Professor in Architecture at LSU, served as Co-PI. Louisiana State University faculty and students worked through several courses during the 2020-2021 academic year to guide them through design development. These included architecture students in ARCH 5001 and 7006, landscape architecture students in LA 3002 and 7041, and civil engineering students in CE 4260. Supporting faculty include Kathleen Bogaski, Nicholas Serrano, Tara Street, Soo Jo, Kris Palagi, and Clint Willson. The final content of this report was created by summer research assistants: Shade Winfrey, Adam Miller, Peyton Mahoney, Josh Crawford.  Mary Bergeron provided administrative support on the project.

Led by the LSU Coastal Ecosystem Design Studio, many groups and individuals contributed to the overall success of the project:

• BREC, including Superintendent Corey Wilson, Assistant Superintendent of Planning Reed Richard, Assistant Superintendent of Recreation Brandon Smith, Andrea Roberts, Angela Harms, Brett Wallace, Rhett Butler, and RaHarold Lawson
• Baton Roots program leadership, including Mitchell Provensal and SK Groll
• Baton Roots community partners: BREC, Healthy BR, Geaux Get Healthy, Southern University Ag Center, LSU AgCenter, Baton Rouge Green, Louisiana Department of Agriculture and Forestry, USDA, BCBS Louisiana Foundation, Humana Foundation, Wilson Foundation, Baton Rouge Area Foundation, Aetna/CVS, Healthy Blue, Louisiana Healthcare Connections, Sprouts Healthy Communities Foundation, Rotary Club, Build Baton Rouge, ExxonMobile, EBRPHA, the American Heart Association, Louisiana 4-H Foundation, Lynne Pisto, and Jennifer and Sean Reilly.
• Faheem Majeed was the principal consulting artist on this project and was instrumental throughout the planning process.
•  Summer 2021 interns Joshua Crawford, Peyton Mahoney, Adam Miller, Dylan Roth, and Shade Winfrey

CEDS was awarded a 3-year contract to help make CPRA’s complex coastal restoration efforts easily understood by a variety of audiences, including the layperson. The purpose of the project stemmed from acknowledgement of the need to better communicate to stakeholders’ risks to Louisiana’s coast and the dramatic efforts CPRA is undertaking to safeguard the coast’s future. Visualizations include drawings, animations, diagrams, learning kiosks, publications, presentations, educational installations, and a 9,000-square foot exhibition space at the Water Campus in downtown Baton Rouge.  These visual materials enrich the communicative power of the CPRA Coastal Master Plan.

In October 2018 the LSU Coastal Sustainability Studio was selected as a Rose Award recipient by Baton Rouge chapter of the American Institute of Architects for the Center for River Studies exhibition. Rose award winners were selected by an independent jury based on design excellence.

LSU CEDS provided interior design guidance, development of visualizations and kiosk content, and ideas for presenting complex ideas to a broad audience.  

To see examples of this work or to schedule a visit, go to: lsu.edu/river

• Jeff Carney, Former Director, Coastal Sustainability Studio
• Shelby Doyle
• Jacob Mitchell
• Matthew Dunn
• Karen May
• Jori Erdman, AIA, LEED AP
• Robert Twilley, PhD
• Clint Willson, PhD, PE
• John R. White, PhD
• Elizabeth Mossop
• James Sullivan
• Courtney Barr