Hazard Mitigation Technical Assistance Program Contract No. EMW-2000-CO-0247 Task Order 447 Hurricane Rita Rapid Response Wind Water Line (WWL) Data Collection – Louisiana FEMA-1607-DR-LA Final Report February 28, 2006 Submitted to: Federal Emergency Management Agency Region VI Denton, TX Graphic: Department of Homeland Security\FEMA logo Prepared by: URS Group, Inc. 200 Orchard Ridge Drive Suite 101 Gaithersburg, MD 20878 Table of Contents Abbreviations and Acronyms ii Glossary of Terms iii Background 1 Overview of Impacts in Louisiana 2 Purpose 5 Methodology 8 Findings and Observations 19 Conclusions 23 Appendices Appendix A: Wind Water Line Data Points Appendix B: Photographs Appendix C: Debris Line and Inundation Mapping Summary Appendix D: Notes on Analysis of Wind Line Data Points Appendix E: Wind Water Line Maps List of Figures Figure 1: Hurricane Rita Storm Track 2 Figure 2: FEMA-1607-LA Disaster Declaration 4 Figure 3: Study Area 6 Figure 4: Wind Water Line Illustration (Profile View/Plan View) 9 Figure 5: Example Debris Field 10 Figure 6: Example Water Marks 10 List of Tables Table 1: Parishes Designated Only for Public Assistance, Categories A and B Only 3 Table 2: Parishes Designated Only for Public Assistance, All Categories 3 Table 3: Parishes Designated for Both Individual Assistance and Public Assistance, Categories A and B Only 3 Table 4: Parishes Designated for Both Individual Assistance and Public Assistance, All Categories 3 Table 5: WWL Data Points in Calcasieu Parish 14 Table 6: Wind Water Line Findings 19 ABBREVIATIONS AND ACRONYMS Acronyms and Explanations CDT Central Daylight Time (daylight savings time zone) CHWM Coastal High Water Mark DEM Digital Elevation Model EDT Eastern Daylight Time (daylight savings time zone)FEMA Federal Emergency Management AgencyFIRM Flood Insurance Rate Map GIS Geographic Information SystemGPS Global Positioning SystemHMGP Hazard Mitigation Grant Program HMTAP Hazard Mitigation Technical Assistance ProgramHWM High Water Mark IA Individual Assistance km Kilometers kts Knots LiDAR Light Detection and Ranging mb Millibar mph Miles Per HourNAD 83 North American Datum of 1983 NAVD 88 North American Vertical Datum of 1988 NFIP National Flood Insurance Program NGVD 29 National Geodetic Vertical Datum of 1929 NUAR Not Used After ReviewPA Public Assistance PNP Private Non-Profit RHWM Riverine High Water Mark SOC State Operations Center USGS U.S. Geological Survey UTM Universal Transverse Mercator WWL Wind Water Line GLOSSARY OF TERMS Word Definition ArcCatalogฎ - Software application from ESRI that organizes and manages all GIS information such as maps, globes, data sets, models, metadata, and services. ArcGISฎ - The comprehensive name for the current suite of GIS products produced by ESRI that are used to create, import, edit, query, map, analyze, and publish geographic information. ArcViewฎ - A software application from ESRI that provides extensive mapping, data use, and analysis, along with simple editing and geoprocessing capabilities.Base map - A map or chart showing certain fundamental information, used as a base upon which additional data of a specialized nature are compiled or overprinted. Contour data - Ground elevation data displayed as continuous lines for given elevations. Contour lines - Lines that connect a series of points of equal ground elevation and are used to illustrate topography, or relief, on a map. Data point - A point associated with a discrete geographic location where data pertaining to the study were collected. Debris line - Defines the extent of flooding where debris such as parts of houses, docks, cars, or other non-natural material is generally carried by floodwaters with some velocity and is then dropped as the floodwaters lose velocity and begin to recede.Disaster declaration - The formal action by the President to make a state eligible for major disaster or emergency assistance under the Stafford Act.Emergency protective measures - Actions taken by Applicants before, during, and after a disaster to save lives, protect public health and safety, and prevent damage to improved public and private property.Flood recovery map - High-resolution maps that show flood impacts, including high water mark flood elevations, flood inundation limits, the inland limit of waterborne debris (trash lines), and storm surge elevation contours based on the high water marks. The maps also show existing FEMA Flood Insurance Rate Map (FIRM) flood elevations for comparison to hurricane data.Geodatabase - The geodatabase provides the common data access and management framework for ArcGIS. Geodatabases organize geographic data into a hierarchy of data objects. These objects are stored in feature classes, object classes, and feature datasets. An object class is a table in the geodatabase that stores nonspatial data. A feature class is a collection of features with the same type of geometry and the same attributes. A feature dataset is a collection of feature classes sharing the same spatial reference.Hazard Mitigation Grant Program - Provides grants to States and local government to implement long-term hazard mitigation measures after a major disaster declaration. The purpose of the program is to reduce the loss of life and property due to natural disasters and to enable mitigation measures to be implemented during the immediate recovery from a disaster. High Water Mark - Indicators of high water levels found on the ground or on structures. Examples are debris lines, wrack lines, and mud lines. Individual Assistance - Federal assistance provided to families or individuals following a major disaster or emergency declaration. Under a major disaster declaration, assistance to individuals and families is available through grants, loans, and other services offered by various Federal, state, local, and voluntary agencies.Inundated - Flooded or covered with water.Inundation polygon - Aerial extent of flooding as shown by polygon feature in ArcGIS. Knot - A unit of speed, 1 nautical mile per hour, approximately 1.85 kilometers (1.15 statute miles) per hour. LiDAR - LiDAR (Light Detection and Ranging or Laser Imaging Detection and Ranging) is a technology that determines distance to an object or surface using laser pulses. Like the similar radar technology, which uses radio waves instead of light, the range to an object is determined by measuring the time delay between transmission of a pulse and detection of the reflected signal. Millibar - A unit of atmospheric pressure equal to 1/1,000 of a bar. Standard atmospheric pressure at sea level is about 1,013 millibars. Mitigation - Any measure that will reduce or eliminate the long-term risk to life and property from a disaster event. Mud line Type of high water mark found on structures. Occurs when suspended solids carried by floodwaters are deposited along the walls, doors, etc. of structures leaving an indicator of the peak flood level. National Flood Insurance Program - The Federal program created by an Act of Congress in 1968 that makes flood insurance available in communities which enact and enforce satisfactory floodplain management regulations. National Geodetic Vertical Datum of 1929 - Vertical control datum that was widely used in the U.S. prior to the establishment of NAVD 88. North American Datum of 1983 - Horizontal datum used as the standard map coordinate system default by the majority of GPS devices. North American Vertical Datum of 1988 - The most widely used vertical control datum in the U.S. today, it was officially established in 1991 by the minimum-constraint adjustment of the Canadian-Mexican-U.S. leveling observations. Orthorectified - Orthorectification removes the effects of relief displacement and imaging geometry from aerial photographs.Polygon - A polygon, in ArcGIS, is a shape defined by one or more rings, where a ring is a path that starts and ends at the same point. If a polygon has more than one ring, the rings may be separate from one another or they may nest inside one another, but they may not overlap. Public Assistance - Federal assistance provided to state and local government, Native American Tribes, and certain non-profit organizations after a disaster declaration. The assistance is for the repair, replacement, or restoration of disaster-damaged, publicly owned facilities and the facilities of certain Private Non-Profit (PNP) organizations. The Federal share of assistance is not less than 75 percent of the eligible cost for emergency measures and permanent restoration. The State determines how the non-Federal share (up to 25 percent) is divided among the applicants. Riverine flooding - Occurs when rivers and streams overflow their banks. Seed file - Seed files are used within software applications and serve as templates in which standard file parameters are set to predetermined standards. Shapefile - Shapefiles store geographic features and their attributes. Geographic features in a shapefile can be represented by points, lines, or polygons (areas). Storm surge - Onshore rush of water piled higher than normal as a result of high winds on an open water body’s surface. It occurs primarily along the open coast, and can destroy houses, wash away protective dunes, and erode soil. Topographic quadrangle maps - A standard map size and scale used by the U.S. Geological Survey to show topography, roads, and landmarks. Water mark - A mark, usually on structures, left by floodwaters. Wind Water Line - An approximate boundary to delineate the inland extent of the area where structures were damaged as a result of flooding from storm surge from a particular event. Landward of the line, most of the damage is attributable to winds and/or wind-driven rain. Sometimes, the Wind Water Line is located along the debris line, but in some cases, inundation and flood damage extends beyond the area where major debris was deposited. Wrack line - Defines the extent of flooding where organic type debris such as grass and weeds are carried by floodwaters and then dropped as the floodwaters recede. Background The 18th tropical depression of the 2005 Hurricane Season formed on September 17 to the east of the Turks and Caicos Islands. It then became the 17th tropical storm of the season on September 18 less than a day after forming and was named Rita. On September 18, a mandatory evacuation was ordered for the entire Florida Keys. As Rita moved westward over the next couple days, it was slow to become a hurricane. National Hurricane Center (NHC) discussions issued early on September 20 indicated that while some wind measurements suggested Rita might have surface level wind speeds of 74 miles per hour (mph), or 144 knots, the lack of a complete eyewall did not support the hurricane designation. Therefore, the NHC continued to designate Rita as a tropical storm with 70 mph (136 knots). However, Rita did gain strength and by 11:00 a.m. EDT on September 20, it was designated a Category 2 strength hurricane with 100 mph (194 knots) maximum sustained winds. Rita stayed a Category 2 for the rest of the day on September 20, but began increasing in intensity rapidly on September 21. By 5:00 p.m. EDT on September 21, Hurricane Rita was a Category 5 storm with maximum wind speeds of 165 mph (321 knots). Rita continued to strenghten and by the night of September 21, its maximum sustained winds had increased to 175 mph (340 knots) with an estimated minimum pressure of 897 millibars (mb). After peaking with steady winds of 175 mph (340 knots), Rita made landfall on September 24, between Sabine Pass, TX, and Johnson’s Bayou, LA, as a Category 3 hurricane with windspeeds of 120 mph (233 knots) and a storm surge of 10 feet, or 3 meters (m). Figure 1 shows Rita’s path beginning on September 18, 2005 and ending on September 25 a day after making landfall. Figure 1: Graphic of Hurricane Rita Storm Track Source: http://cimss.ssec.wisc.edu/tropic/archive/2005/storms/rita/rita.html Overview of Impacts in Louisiana On September 24, 2005, the President authorized a disaster declaration for several Louisiana parishes (FEMA-1607-DR-LA). Through subsequent amendments, all 64 of Louisiana’s parishes were eventually included in the declaration, which provided the necessary assistance to meet immediate needs and to help Louisiana recover as quickly as possible through the following means: Public Assistance (PA): includes supplemental Federal disaster grant assistance for the repair, replacement, or restoration of disaster-damaged publicly owned facilities, and the facilities of certain private non-profit (PNP) organizations. There are seven subcategories (A-G) within this designation under two work types: emergency work and permanent work. Unless otherwise noted, Public Assistance will include all categories under both work types. However, often only the emergency work categories are designated, which include Category A, debris removal, and Category B, emergency protective measures. Individual Assistance (IA): includes cash grants of up to $26,200 per individual or household for housing (hotel or motel expenses reimbursement, rental assistance, home repair and replacement cash grants, and permanent housing construction assistance in rare circumstances) and other needs (medical, dental, and funeral costs; transportation costs; and other disaster-related needs). Hazard Mitigation Grant Program (HMGP): funds projects that will reduce or eliminate losses from future disasters by providing a long-term solution to a problem. Eligible applicants include State and local governments, Indian tribes or other tribal organizations, and certain non-profit organizations. FEMA can fund up to 75 percent of the eligible costs of each project, and the State or grantee must provide a 25 percent match. All Louisiana Parishes are eligible for HMGP funds. Tables 1 through 4 provide listings of which designation(s) each parish received for IA and PA. Figure 2 shows these designations graphically. Table 1: Parishes Designated Only for Public Assistance, Categories A and B Only Assumption Avoyelles Bienville Bossier Caddo Caldwell Catahoula Claiborne Concordia East Baton Rouge East Carroll East FelicianaFranklin Grant Iberville Jackson La Salle Lincoln Madison Morehouse Orleans Ouachita Point Coupee Red River Richland St. Bernard St. Charles St. Helena St. James St. John the Baptist Tangipahoa Tensas Union Washington Webster West Carroll West Feliciana Winn Table 2: Parishes Designated Only for Public Assistance, All Categories De Soto Natchitoches Rapides Table 3: Parishes Designated for Both Individua Assistance and Public Assistance, Categories A and B Only Ascension Jefferson Lafourche Livingston Plaquemines St. Martin St. Tammany West Baton Rouge Table 4: Parishes Designated for Both Individual Assistance and Public Assistance. All Categories Acadia Allen Beauregard Calcasieu Cameron Evangeline Iberia Jefferson Davis Lafayette Sabine St. Landry St. Mary Terrebonne Vermillion Vernon Figure 2: Graphic of FEMA-1607-DR-LA Disaster Declaration According to reports on the website for Wikipedia (http://en.wikipedia.org) which cites several established news sources including CNN, in southwestern Louisiana, severe damage was reported. In Cameron Parish, communities including Hackberry, Cameron, Creole, Grand Chenier, and Holly Beach either suffered heavy damages, or destruction. In Calcasieu County, a casino boat and several barges, floated unmoored in Lake Charles and damaged a bridge spanning Interstate 10 across the Calcasieu River. In the Lake Charles area, floodwaters reportedly rose to 6 to 8 feet. According to FEMA’s Public Information Officer (PIO) for Louisiana, Cameron, Calcasieu, and Vermilion Parishes sustained heavy damage to infrastructure. Widespread flooding was reported along other coastal parishes further east, including Terrebonne Parish where virtually every levee was breached. The levee system in New Orleans was already heavily damaged from Hurricane Katrina before heavy rains from Rita began to fall on the city. Along the damaged Industrial Canal levee, rising water was already pushing through two of the levees’ patched breaches by approximately 9:00 a.m. CDT on September 23, and into the already devastated Ninth Ward. By 11:00 a.m. CDT, water was reportedly waist-deep. By late afternoon, water was pouring through another patched breach in the London Avenue Canal and into the Gentilly neighborhood. By the night of September 24, water from a 150-foot wide breach in the Industrial Canal levee resulted in flooding of up to 8 feet in some areas of the Ninth Ward. In New Orleans, there was also extensive damage to the Louis Armstrong New Orleans International Airport and to the city’s electrical system. In Baton Rouge, approximately 30 bridges were damaged as a result of Rita. Purpose After a hurricane impacts a coastal area with significant flooding, it is imperative that data be collected to document the event to assist in response, recovery, and mitigation efforts, and to improve disaster preparedness and prevention efforts for future disasters. Wind Water Line (WWL) data collection is an initial step in accurately documenting an event. These data help place the event in historical perspective and improve the ability to estimate current flood risk and future event prediction. Collection of site-specific flood inundation data along rivers, bays, and coasts has numerous applications. The Federal Emergency Management Agency’s (FEMA’s) National Flood Insurance Program (NFIP) requires data to identify flood damages to provide a valid basis for establishing eligibility of flood insurance benefits. Information for insurance purposes is time-critical because the flood insurance and homeowner insurance claims cannot be concluded until the cause of damage is established. The WWL data provide a basis for delineating areas subject to flooding and help to identify approximate boundaries between areas where damages are due to flooding and wind versus areas of wind-only damages. FEMA uses these data to provide inundation boundaries and information on the flooding extent along the affected shoreline areas. Other FEMA programs that directly benefit from post-disaster flood data collection include: Human Services: provides advice to individuals on how to use Federal grants to increase their homes’ flood resistance; Public Assistance (PA): identifies appropriate flood mitigation measures to pursue when providing Federal grants to repair publicly owned infrastructure; and Hazard Mitigation Grant Program (HMGP): ensures that accurate benefit/cost analysis is performed. The purpose of the Wind Water Line (WWL) Study is to determine the inland extent of damages caused by storm surge-induced flooding, and to differentiate this area from those farther inland where damages were primarily the result of wind forces. By delineating the WWL, an approximate boundary is created between areas where both storm surge-induced flooding and wind forces caused damage to structures from those areas where wind forces were the primary cause of damages to structures and surge flooding did not have a significant impact. Sometimes, the Wind Water Line is located along the debris line, but in some cases, inundation and flood damages extend beyond the area where major debris was deposited. The WWL study extended from the northern portion of the Gulf Coast of Texas eastward through southwestern Louisiana. This report focuses on the determinations based on data collected in Louisiana, where the entire coastline was studied. Figure 3 shows the WWL Study Area within Louisiana. Figure 3: Graphic of Study Area Overview of Related Projects URS Corporation, with support from Government Services Integrated Process Team, LLC (GSIPT), was tasked by FEMA under their existing Hazard Mitigation Technical Assistance Program (HMTAP) contract to assist in disaster recovery efforts for Hurricane Rita. Assistance provided by this Task Order included data collection and visual survey of the debris line and the extent of flooding to identify the WWL. After Hurricane Rita, FEMA issued several task orders under the HMTAP contract called Rapid Response Task Orders. Generally, the purpose of these task orders is to allow FEMA contractors to move quickly into disaster stricken areas to collect perishable data for use in defining the parameters of the event that then can be used for future studies and flood mitigation activities. In addition to the Wind Water Line Task Order, there are several other types of Rapid Response Task Orders, including Aerial Imagery Data Collection, Coastal High Water Mark (CHWM) Surveys, and Riverine High Water Mark (RHWM) Surveys. High Water Mark Survey findings are used to define the extent of flooding and therefore can be used in conjunction with field findings from Wind Water Line task orders to determine the extent of the WWL. Aerial imagery is also used to estimate the WWL; post-event imagery can be used to identify areas affected by flood damages as well as the approximate inland extent of storm surge flooding. In response to Rita, HMTAP Task Order 447, Rapid Response, Hurricane Rita Wind Water Line – LA was issued and is the focus of this report. In addition, HMTAP Task Order 443, Rapid Response, Aerial Radar – Texas and Louisiana; HMTAP Task Order 445, Rapid Response, Hurricane Rita Coastal High Water Mark Survey – LA; and HMTAP Task Order 450, Rapid Response, Hurricane Rita Riverine High Water Mark Survey – LA were also issued. An overview of these task orders is provided below: Under Task Order 443, Rapid Response, Aerial Radar – Texas and Louisiana, cartographic analysts were tasked with using post-event aerial imagery to delineate areas affected by flooding along the western edge of Louisiana’s Gulf Coast and the northeast portion of Texas’ coastline. Through Task Order 445, Rapid Response, Hurricane Rita Coastal High Water Mark Survey - LA, field crews collected perishable HWM data at field observation point locations. The crews looked for evidence of the peak elevation of flooding caused by storm surge, then inventoried and surveyed these elevations. Peak flood elevations in coastal Louisiana were recorded at several locations as part of this task order. This data can be used to help determine the extent of flooding. For Task Order 450, Rapid Response, Hurricane Rita Riverine High Water Mark Survey – LA, field crews also collected high water mark data at field observation point locations. Field crews for the RHWM survey focused on areas of overbank flooding where heavy and/or prolonged precipitation resulted in an exceedance of the capacity of rivers and streams to keep floodwaters within their banks. Peak flood elevations for riverine type flooding were surveyed and recorded as part of this task order. Riverine HWMs can be used to help delineate the extent of surge flooding by showing where riverine flooding predominates. In addition, comparison of WWL data with the impacts projected by modeled storm events provides insight into how well numerical models simulate a specific event (e.g., coastal storm surge, riverine flooding). When coupled with sufficient data density and observational information, it is possible to create flood recovery maps, which are high-resolution maps that show flood impacts, including HWM flood elevations, flood inundation limits, the inland limit of waterborne debris (trash lines), and storm surge elevation contours based on the HWMs. These event-related data can be used in conjunction with or, in some cases, instead of, effective Flood Insurance Rate Map (FIRM) data to establish recommended coastal flood elevations for redevelopment and rebuilding purposes. In Louisiana, data collected through several HMTAP rapid response Task Orders are being used in Task Order 436 Flood Data Analysis - Louisiana, to develop the Hurricane Rita Surge Inundation and Advisory Base Flood Elevation Maps, commonly referred to as “Rita Recovery Maps.” Specifically, the Rita Recovery Maps were created from data from this WWL Task Order, Rapid Response, Hurricane Rita Coastal High Water Mark Survey – Louisiana and Task Order 450, Rapid Response, Hurricane Rita Riverine High Water Mark Survey – LA. The data are being used to develop event-related themes that document the storm’s impacts along the Louisiana coast where HWMs showed that Rita's surge flooding was greater than that of Katrina. Superimposed on the event themes will be Advisory Base Flood Elevations (ABFEs), determined from a flood-frequency analysis of several hurricanes that have affected the area. The Rita Recovery Maps will help to guide decisions about reconstruction in the areas affected by surge flooding from Hurricane Rita (where this surge flooding was greater than caused by Hurricane Katrina) along Louisiana’s coastal floodplain. Methodology There were two basic elements to this project: field data collection and WWL mapping. While field crews worked to collect data in the weeks following Hurricane Rita, the WWL mapping process occurred after the data had been collected and involved interpretation and analysis of data from several sources. Data Collection Methodology URS field crews were mobilized within seven days of the disaster declaration. Field teams tasked with locating HWMs, marking them, and performing general data collection were called ‘flaggers’ and they began field work on October 1, 2005 continuing through October 19. Surveying teams followed the flaggers surveying the already identified points from October 27 through December 5. Data collection for Task Order 447, Rapid Response, Hurricane Rita Wind Water Line – LA was performed in tandem with data collection for Task Order 445, Rapid Response, Hurricane Rita Coastal High Water Mark Survey – LA and Task Order 450, Rapid Response, Hurricane Rita Riverine High Water Mark Survey – LA. The WWL points, which are also located by identifying water marks on structures or debris or wrack lines, doubled as HWMs. WWL points are used to define the extent inland of where there is damage to structures caused by surge flooding. Thus the points generally form a line showing the approximate inland limit of surge flooding. The Wind Water Line is so called because landward of the line in coastal areas, damage to structures is usually limited to wind damage, which includes direct rain damage where the envelope of the structure may have been compromised by high wind damage. Seaward of the line, damage is the result of surge-induced flooding with wind forces contributing as well (see Figure 4). Figure 4: Graphic of Wind Water Line Illustration (Profile View/Plan View) Each field crew was tasked with identifying and documenting the WWL and collecting pertinent data points along the coastlines. The WWL were documented using a standardized flagger form to collect detailed information about the point. To define points along the WWL, field crews visited areas of known flood damage. Traveling away from the coast to the edge of damage, they attempted to locate debris fields (see Figure 5) or water marks close to the ground, and to trace them along topographic features to determine the extent of flooding (see Figure 6) and flood damages. Figure 5: Photo Example Debris Field Figure 6: Photo of Example Water Marks Note: This HWM illustrates the concept of a water mark on a structure, but would be too high to be considered a WWL data point. Field crews notified County Emergency Managers prior to the start of fieldwork in order to obtain all available information about the location and extent of damage to structures in the county. Areas identified by County Emergency Managers as having been damaged and/or having higher flood levels were given greater attention. Generally, WWL data were collected every two to four miles in developed areas inland. However, in areas with significant damage to structures from flooding along the coastlines, the density of data points was sometimes higher. Similarly, there were certain stretches of coastline where field crews could not take data points because these areas could not be accessed (no roads, thick vegetation, or swampy areas, etc.) or because there was no clear physical evidence to define a WWL point. The following data were collected at each observed WWL point: Address (if the point was near an addressable structure); Latitude/longitude reading, taken in North American Datum (NAD) 1983, which is used as the standard map coordinate system default by the majority of Global Positioning System (GPS) devices; Location description (e.g., neighborhood or other descriptive name); Date data point was taken; Type of data point, including debris line, water mark, wrack line (indicates the high tide mark), etc.; Type and severity of observed wind damage; Flood source; Approximate flood depth (if water mark data point); and Digital photographs (named according to the WWL point identification number; see Appendix B). Note: The SD memory cards containing some of the images became corrupt, and as such, the images on them were unrecoverable. For this reason, images for 25 of the WWL points are not available. The data points were labeled with HWM IDs. These alphanumeric labels consist of four letters: the first letter indicates the storm name, the second and third letters are the state abbreviation, and the fourth letter is either a ‘C’ for coastal or an ‘R’ for riverine type flooding. These 4 letters are followed by a two-digit code indicating the team number, and another two-digit code indicating the point number for that particular team. Therefore, a coastal flooding type data point in Louisiana for Rita that was the third point taken by Team 2 would be labeled RLAC-02-03. However, some points labeled ‘C’ were actually later determined to be riverine and likewise some points labeled ‘R’ were later determined to be coastal type flooding. Therefore, whenever there is an ‘R’ point followed by (coastal) or a ‘C’ point followed by (riverine), the flood type listed in parentheses is the correct reference. Data had to be collected quickly; as community clean-up efforts progressed, valuable debris line and water mark data were being destroyed. WWL data were entered into a database (Appendix A). Each photograph was named according to the WWL point reference number (Appendix B). After the WWL data points were compiled and checked for accuracy, they were surveyed for elevation. Geographic information systems (GIS) analysts worked with the data to make geodatabases and create associated shapefiles. Mapping Methodology To create the Wind Water Line maps, the project team relied heavily on data supplied from HMTAP Task Orders 443, Rapid Response, Aerial Radar – Texas and Louisiana; 444, Rapid Response, Hurricane Rita Coastal High Water Mark Survey – LA; and 450 Rapid Response, Hurricane Rita Riverine High Water Mark Survey – LA. Under Task Order 443, Rapid Response, Aerial Radar – Texas and Louisiana, cartographic analysts used post-event aerial imagery to delineate areas affected by flooding along the Louisiana Coast. The analysts used natural color orthorectified 3001, Inc. imagery acquired between September 30, 2005 and October 9, 2005 for southwestern Louisiana including Calcasieu, Cameron, and Jefferson Davis Parishes. They studied the imagery to locate the extent to which high velocity floodwaters, including coastal surge, pushed debris inland, and to delineate areas beyond these debris lines where floodwaters had continued to push inland and causing additional flood inundation without major debris. The analysts also delineated riverine flooding that occurred near the coast in their analysis. A GIS coverage showing the approximate extent of flooding was created as part of this task order. A summary report for this effort is provided as Appendix C. Through Task Order 445, Rapid Response, Hurricane Rita Coastal High Water Mark Survey- LA, field crews collected perishable high water mark data at field-observed, point locations. They looked for evidence of the peak elevation of flooding caused by storm surge, then inventoried and surveyed these elevations. HWM points were taken where surge directly affected flood levels, including the shoreline of open coasts, bays, and tidally influenced rivers. HWMs are formed when the water level during a storm rises to a maximum elevation and leaves marks on the interior and/or exterior walls of a structure, or debris or wrack lines along the ground. HWM field crews are responsible for identifying these marks, and recording some basic information about the data point. Survey crews then used these initial records to later relocate the points and survey them to determine the peak elevation of flooding. Under this task order, field WWL data points were used together with the information about the extent of flooding determined as part of the aerial imagery task order to determine the aerial measure of inundation based on both photointerpretation and field ground-truthed data. The inundation areas defined under Task Order 443, Rapid Response, Aerial Radar – Texas and Louisiana served as the ‘base data’ for determining the WWL, and the field data collected under this task order were compared to this base data to determine if the two data sets were in agreement. However, this base data was only available where post-event imagery was captured; the imagery was taken in southwestern Louisiana in Calcasieu, Cameron, and Jefferson Davis Parishes. In these areas, where WWL field data points did not agree with the photointerpreted flood area delineation, analyses using information about the depth of flooding and flood elevation for the WWL (and potentially for nearby HWM points) were conducted. If the flood elevation data and supporting documentation, including comments and photographs from the field crews, confirmed that the WWL point was correct, the inundation coverage was modified to agree with the field collected data and topography was used to delineate the boundaries for these modifications. Notes from these comparisons are included in tabular format in Appendix D and summarized by parish below. Where the aerial imagery, and subsequently the photointerpreted debris line and inundation area, were not available, the WWL data from the flaggers were used in conjunction with local topography to delineate the WWL. This methodology was used in all areas west of Calcasieu, Cameron, and Jefferson Davis Parishes. The local topography was obtained from the Louisiana State University website at http://atlas.lsu.edu/. It is 2-foot contour data provided to the university by the Louisiana Oil Spill Coordinator’s Office and was generated from LiDAR processed by 3001, Inc. Additionally, the extent of flooding was defined not only by the WWL points, but also from data collected as part of the HWM surveys (Task Orders 445 and 450). In some areas, it was difficult to locate WWL points due to access issues, or because there was no clear physical evidence to define a WWL point. This happened particularly in swampy areas where it was not clear how far inland the surge had moved through the swamps. In these cases, the elevation data from the HWM surveys was used to complement the WWL data. The CHWM is a measure of the peak flood elevation from surge and, when used along with reliable topography data, can help to determine an approximate WWL boundary. In these cases, CHWM points that appear to be near the edge of inundation (based on interpolation from other WWL points or boundary estimates) should be used since surge induced flood elevations generally increase towards the coastline. Additionally, in these swampy areas, a general coastal wetland coverage based on National Wetlands Inventory (NWI) data was developed to illustrate why WWL data points could not be located along portions of the southern coast of Louisiana. Assumption The WWL was created to follow the six-foot contour and include one of the two WWL points identified in Assumption Parish (RLAR-15-11). The lack of post-event imagery in this area prevented the photointerpreters from creating an inundation polygon. However, a review of the flagger forms, photos, and topography supported the delineation of the WWL to include the southern portion of Assumption Parish up to the six-foot contour. The second point (RLAR-15-09) was located in the northern portion of Assumption Parish. Topography, location, and online imagery did not provide evidence that this area was affected by coastal surge. A review of flagger forms did not conclusively support coastal flooding at this point. Calcasieu Calcasieu Parish had 24 identified WWL points. Five of the identified WWL points in the parish were located within 200 feet of the photointerpreted inundation polygon, indicating the data sets were in agreement and that no further comparison between the five points and the photointerpreted data was necessary. Table 5 summarizes the WWL points in Calcasieu Parish and the changes required to the inundation polygon. See Appendices D and E for more information. After a review of the flagger forms and photos, inundation polygon, imagery, and topography for the remaining 19 points, 5 WWL points located inside the inundation polygon were found not to represent the WWL. At these five points, the imagery and topography supported that flooding occurred further inland. Table 5: WWL Data Points in Calcasieu Parish WWL Points:RLAC-08-03 RLAC-08-04 RLAC-09-27 RLAC-12-06 Action:Leave as is Explanation:Within 200’ of the WWL and inundation polygon. WWL Points:RLAC-03-03 RLAC-07-02 RLAC-08-02 RLAC-09-14 RLAR-02-05 Action:No Action Explanation:WWL points located inside the inundation polygon. Flooding extended further inland. WWL Points: RLAC-08-01 RLAC-09-15 RLAC-09-16 RLAC-09-18 RLAC-09-41 RLAC-10-02 Action:Modify inundation polygon Explanation:Imagery and survey documentation supports extending the inundation polygon. WWL Points: DNU-RLAC-02-111 DNU-RLAC-02-141 DNU-RLAC-08-071 Note: DNU = Do Not Use. Designation given to HWM points after a QC check determined that the data point was unreliable. RLAC-04-01 RLAC-09-42 RLAC-09-43 RLAC-09-44 RLAC-09-45 RLAR-09-19 Action:After review, WWL points not used Explanation:WWL points located outside the inundation polygon. A review of the flagger forms and photos, inundation polygon, imagery, and topography found that the inundation polygon at six points should be modified. At two points (RLAC-08-01 an RLAC-09-41), it was recommended to extend the inundation polygon to follow the 14-ft contour to include these points. At another point (RLAC-09-15), it was recommended that the inundation polygon be updated to follow the 10-foot contour. The recommendation for updating the inundation polygon at WWL point RLAC-09-16 was to extend the polygon northward along the tributary. The recommendation for the WWL point RLAC-09-18 was to extend the polygon west using the imagery as a guide to include the point. The recommendation for the sixth point (RLAC-10-02) was to remove an area from the inundation polygon to account for an area of higher elevation that was above flood levels. A review of the inundation polygon, imagery, and topography, found that eight WWL points outside of the inundation polygon did not represent WWL points. Flagger forms and pictures could not support that the flooding at these eight points was due to coastal surge. In general, the WWL follows the inundation polygon; however, tributaries can be affected by flooding not related to surge. The WWL along the Sabine River, in the western portion of Calcasieu Parish, was determined to reach an elevation of 6 feet as indicated by HWM point RLAC-09-16, as well as three points in Texas: RTXC-03-07, RTXC-03-06, and RTXR-05-14 (coastal). The average elevation at these points was 6 ft NAVD 88. Along the Calcasieu Ship Channel, the WWL extended to an elevation of 8 ft NAVD 88 with HWM point RLAC-08-04 (elevation 8.4 ft NAVD 88) used as a reference. Cameron Two of the three WWL points identified in the parish (RLAC-09-12 and RLAC-10-16) were located within 200 feet of the inundation polygon and WWL. According to the flagger forms, photos, and topography, the third point (RLAC-03-02) was located along a road within the inundation polygon and WWL with lower elevations surrounding it, supporting the fact that the general area was flooded by coastal surge. The data points supported the existing debris line and inundation polygon delineation, so no changes were recommended. Iberia The WWL was delineated to follow the 8-foot contour and include the single WWL point identified in Iberia Parish (RLAC-03-05). The lack of post-event imagery in this area prevented the photointerpreters from creating an inundation polygon. However, a review of the flagger forms, photos, and topography supported the extension of the WWL to include the southern portion of Iberia Parish up to the 8-foot contour. Jefferson The area to the south of Lake Pontchartrain, including Jefferson Parish, proved difficult for flaggers to differentiate between flooding from Hurricane Rita and Hurricane Katrina. No WWL points were identified in the parish. Jefferson Davis No changes were recommended for Jefferson Davis. The one WWL point identified (RLAR-02-03) was located in the northern portion of the parish. Aerial imagery and topography provided evidence that this area was not flooded by coastal surge during the event. A review of the flagger forms and photos supported the fact that this point did not truly represent evidence of flooding due to coastal surge. Therefore, no changes were made to photointerpreted GIS coverages. Lafourche The general coastal wetland coverage included the four WWL points identified in Lafourche Parish (RLAC-15-14, RLAC-15-15, RLAC-15-16, and RLAC-15-17). Flagger forms, photos, topography, and pre-event imagery supported including this area as coastal wetlands. Lafourche Parish is extremely rural with only one road running through to the coastal area. The four WWL points identified in Lafourche Parish were located along this road. Livingston An inundation area was delineated along Lake Pontchartrain to include three of the four WWL points in Livingston Parish (RLAR-15-02, RLAR-15-04, and RLR1-15-06). Flagger forms, topography, and online imagery supported the addition of an inundation area following the 6-foot contours in the southeastern portion of Livingston Parish. However, after further analysis of riverine versus coastal flooding in the area, the limit of coastal surge was determined to be east of Livingston Parish and so the WWL did not extend into the parish. Orleans In Orleans Parish, one possible WWL point was identified (RLAC-14-23). This area was greatly affected by Hurricane Katrina, which made it difficult to differentiate whether the flooding was caused by Hurricane Katrina or Rita. The flaggers noted that the observed HWMs may have been left by Hurricane Katrina. Therefore, no inundation or WWL is shown for Orleans Parish. Plaquemines An inundation area and WWL were delineated for Plaquemines Parish to include two WWL points identified in the parish (RLAC-17-14 and RLAC-17-17). The inundation area and WWL covered the area to the south and west of the Mississippi River levees. The levees to the south of the Mississippi River, some of which were breached, and State Highway 23 were suspected of preventing floodwaters from moving to the north. Flagger forms, photos, topography, and pre-event imagery supported the mapping of an inundation area following State Highway 23. St. Bernard The area to the south of Lake Pontchartrain, including St. Bernard Parish, proved difficult for flaggers to differentiate between flooding from Hurricane Rita and Hurricane Katrina. Flaggers were not able to identify WWL points in St. Bernard parish. St. Charles In St. Charles Parish, the one WWL point identified (RLAR-15-12) was isolated from the other points and flagger notes and photos indicate that flooding did not overtop the bulkhead along Petit Lac Des Allemands. In the area to the south of Lake Pontchartrain, including St. Charles Parish, flaggers had difficultly differentiating between flooding from Hurricane Rita and Hurricane Katrina. Therefore, no inundation or WWL is shown for St. Charles Parish. St. John the Baptist The WWL was extended from Tangipahoa Parish into the northeastern portion of St. John the Baptist Parish following HWMs RLAC-13-18 and the Anderson Canal, between Lake Pontchartrain and Lake Maurepas. The WWL continued south to Interstate I-10 and veered eastward to Lake Pontchartrain. The inundation polygon continued from St. James Parish into St. John the Baptist Parish following Interstate I-10 to Lake Pontchartrain. St. Martin The one WWL point identified (RLAR-15-10) was located in the northeastern portion of the parish. Topography, location, and online imagery did not provide evidence that this area was affected by coastal surge. A review of flagger forms did not conclusively support coastal flooding at this point. Therefore, no inundation or WWL is shown for St. Martin Parish. St. Mary The inundation polygon and WWL were extended from Iberia Parish to follow the 8-foot contour and include the northwestern most point of the six WWL points identified in St. Mary Parish (RLAC-03-06). The inundation polygon transitioned from the 8-foot contour to the 6-foot contour to follow Bayou Teche and included four additional WWL points near Morgan City (RLAC-01-04, RLAC-01-05, RLAR-15-06 (coastal), and RLAR-15-08). The WWL followed the inundation polygon and was cutoff along the Lower Atchafalaya River at an elevation of 6 ft. based on RLAC-01-04. No post-event imagery was taken in St. Mary Parish, so no inundation polygon or debris line was created for this area as part of Task Order 443, Rapid Response, Aerial Radar – Texas and Louisiana. However, a review of the flagger forms, photos, and topography supported the extension of the inundation polygon and WWL to include St. Mary Parish. According to the flagger forms, photos, and topography, the remaining point in St. Mary Parish (RLAC-18-09) was located along a road surrounded by wetlands at a lower elevation. The location and surrounding wetlands supported the fact that this point should not be included in the inundation polygon. Inaccessibility and the lack of information to the east of St. Mary Parish prevented the photoanalysts from extending the inundation polygon any further east along the coast. St. Tammany A WWL was added to the Lake Pontchartrain area of St. Tammany Parish to include seven of the eight WWL points identified in the parish (RLAC-13-03, RLAC-13-04, RLAC-13-05, RLAC-13-06, RLAC-13-07, RLAC-13-08, and RLAC-13-15). Flagger forms, photos, topography, and pre-event imagery supported the addition of a WWL following the 6-foot contours in the southern portion of St. Tammany Parish. These data sources also indicated that from RLAC-13-03 east to RLAC-13-06, this line was a debris line. The eighth point in St. Tammany Parish (RLAR-20-11), located approximately 12 miles upstream on the West Pearl River, was isolated from the other points in St. Tammany Parish that are closer to the shoreline of Lake Pontchartrain. Flagger forms indicate that the source of flooding at this point was the West Pearl River and that the flooding type was riverine. Tangipahoa Parish The WWL was extended from St. Tammany Parish into the southeastern portion of Tangipahoa Parish following the 6-foot contour. The WWL extend from north to south along the west coast of Lake Pontchartrain to include CHWMs RLAC-13-17 and RLAC-03-18. The inundation polygon continued west along the 6-foot contour into Livingston Parish, but all HWMs in this area were riverine. Terrebonne The general coastal swamp coverage included the WWL point identified in Terrebonne Parish that was surrounded by wetlands (RLAC-03-07). Flagger forms, topography, and pre-event imagery supported including this area as coastal wetlands. Information was difficult to collect in Terrebonne Parish due to the lack of road access in the western section of the parish. Vermilion CHWMs were used in Vermilion Parish to delineate the WWL and inundation. To the south of White Lake in Vermilion Parish, no WWL points were identified. As post-event imagery ended approximately 17,000 feet to the east of the border between Cameron and Vermilion Parishes, no photointerpreted inundation boundaries were delineated. As the photointerpreted debris line generally followed State Highway 82, the debris line was extended to follow six CHWMs along the highway (RLAC-11-21, RLAC-11-22, RLAC-11-23, RLAC-11-27, and RLAC-11-33) and the 6- and 8-foot contours through the area. This extensionended near the CHWM point RLAC-11-25. Flagger notes and photos indicated wrack and mud lines were located along Highway 82. The land between the coast and Highway 82 is swampy and undeveloped without access. The lack of imagery in this area prevented the photointerpreters from creating an inundation polygon. However, a review of the flagger forms, photos, topography, and online imagery supported the extension of the inundation polygon to include Vermilion Parish. The inundation polygon was extended to follow the 4-foot contour and include HWM RLAR-12-06 in Vermilion Parish; however, subsequent analysis showed that this area was actually subject to riverine flooding and beyond the limits of the WWL. The inundation polygon and WWL transitioned to follow the 6-foot contour interval to include three of the eight WWL points identified in Vermilion Parish (RLAC-01-01, RLAC-01-02, and RLAC-03-01). The inundation polygon and WWL transitioned from the 6-foot contour to the 8-foot contour to include two additional WWL points (RLAC-11-24 and RLAC-01-03). The inundation polygon transitioned from the 8-foot contour to the 10-foot contour to follow a nearby tributary and include WWL point RLAR-12-09. The inundation polygon and WWL continued to follow the 8-foot contour into Iberia Parish to include RLAC-03-04. After a review of the flagger forms and photos, inundation polygon, imagery, and topography, one WWL point (RLAC-14-13) located inside the extended inundation polygon was found not to represent the WWL. At this point, the topography supported that flooding reached further inland along the inundation polygon. Map Details GIS maps of the WWL were produced at a scale of 1:24,000 (Appendix E). The maps show the location and type of each WWL data point, the debris line, and the approximate coastal inundation extent of storm surge flooding. The GIS maps are based on USGS 7.5- minute topographic quadrangle maps. It is important to note that the maps use both the debris line and extent of inundation to show the damage caused by flooding. While the debris line helps to show where higher velocity storm surge pushed debris inland, causing damage, the inundation caused by surge extends further inland and shows where less powerful and, in many cases, shallower flooding also caused damage. Together, these illustrate the extent of the WWL along coastal Louisiana. Findings and Observations The WWL, shown as the boundary of the surge inundation areas on the maps in Appendix E and as the debris line in portions of Vermillion and St. Tammany Parishes, is focused on the western and central coast of Louisiana, the southwest portion of Plaquemines Parish, and the areas around Lake Pontchartrain. Table 6 presents a summary of the flooding conditions and the location of the surge inundation for the sections of each parish included in the study. Table 6: Wind Water Line Findings Note: The point in St. Martin parish was found to not represent an accurate WWL point. Points in Lafourche, St. Charles, and Terrebonne Parishes were located in the middle of wetlands where the extent of inundation was difficult to determine due to inaccessibility. Flood levels south of Lake Pontchartrain, including Orleans Parish, were difficult to identify as most of the area had been heavily impacted by Hurricane Katrina. PARISH: Acadia LOCATION (CITY OR AREA): Southwest along the border with Jefferson Davis and Vermilion Parishes DISTANCE INLAND TO DEBRIS LINE (FT): None DISTANCE INLAND OF SURGE INUNDATION (FT): 15,100 MAJOR FLOOD SOURCES: Lake Arthur and Mermentau River MAP PANEL NAMES AND NUMBERS: Gueydan – 32 Mermentau – 19 PARISH: Assumption LOCATION (CITY OR AREA): Amelia DISTANCE INLAND TO DEBRIS LINE (FT): None DISTANCE INLAND OF SURGE INUNDATION (FT): 300 – 1,200 Note: Distance inland from channel bank of flooding source. MAJOR FLOOD SOURCES: Bayou Boeuf MAP PANEL NAMES AND NUMBERS:Amelia – 88 PARISH: Calcasieu LOCATION (CITY OR AREA): West along Texas border DISTANCE INLAND TO DEBRIS LINE (FT): None DISTANCE INLAND OF SURGE INUNDATION (FT): 700 – 15,800 Note: Distance inland from channel bank of flooding source. MAJOR FLOOD SOURCES: Sabine River MAP PANEL NAMES AND NUMBERS:Echo – 11 Orange – 23 PARISH: Calcasieu LOCATION (CITY OR AREA): North and east of Moss Lake, including Lake Charles DISTANCE INLAND TO DEBRIS LINE (FT): None DISTANCE INLAND OF SURGE INUNDATION (FT): 0 – 8,000 Note: Distance inland from channel bank of flooding source. MAJOR FLOOD SOURCES: Calcasieu River MAP PANEL NAMES AND NUMBERS:Lake Charles – 15 Moss Lake – 26 West Lake – 14 PARISH: Calcasieu LOCATION (CITY OR AREA): South along the border of Cameron Parish DISTANCE INLAND TO DEBRIS LINE (FT): None DISTANCE INLAND OF SURGE INUNDATION (FT): 103,000 – 142,000 MAJOR FLOOD SOURCES: Calcasieu Lake, Calcasieu Ship Channel, Intracoastal Waterway MAP PANEL NAMES AND NUMBERS:Black Lake – 25 Cameron Farms – 24 Echo – 11 Lake Charles SE – 28 Lake Charles SW – 27 Moss Lake – 26 Orange – 23 Sulphur – 13 Vinton – 12 PARISH: Calcasieu LOCATION (CITY OR AREA): East near Jefferson Davis Parish DISTANCE INLAND TO DEBRIS LINE (FT): None DISTANCE INLAND OF SURGE INUNDATION (FT): 900 – 12,500 Note: Distance inland from channel bank of flooding source. MAJOR FLOOD SOURCES: Bayou Lacassine MAP PANEL NAMES AND NUMBERS:Lacassine – 16 Lake Charles SE – 28 Hayes – 29 PARISH: Cameron LOCATION (CITY OR AREA): Parish-wide DISTANCE INLAND TO DEBRIS LINE (FT): 0 – 40,000 DISTANCE INLAND OF SURGE INUNDATION (FT): 47,000 – 114,000 Note: Distance inland from delineated Debris Line. MAJOR FLOOD SOURCES: Gulf of Mexico MAP PANEL NAMES AND NUMBERS: Big Constance Lake - 92 Black Lake – 25 Boudreaux Lake – 40 Browns Lake – 37 Cameron – 57 Cameron Farms – 24 Catfish Lake – 61 Collicon Lake – 62 Cow Island – 77 Creole – 59 Creoleoes – 75 Deep Lake – 78 Five Lakes – 35 Floating Turf Bayou – 79 Grand Bayou – 58 Grand Cheniere – 60 Greens Bayou – 35 Gueydan – 32 Hackberry – 38 Hayes – 29 Hog Bayou – 76 Holly Beach – 55 Johnsons Bayou – 54 Lake Arthur – 31 Lake Charles SE – 28 Lake Charles SW – 27 Lake LeBleu – 63 Lake Misere – 41 Latania Lake – 42 Latanier Bayou – 44 Mallard Bay – 43 Moss Lake – 26 Orange – 23 Orangefield – 22 Peveto Beach – 55 Port Arthur South – 52 Rollover Lake – 93 Sabine Pass – 73 Sweet Lake – 39 Texas Point – 74 Thornwell – 30 West of Greens Bayou – 34 West of Johnsons Bayou – 53 PARISH: Iberia LOCATION (CITY OR AREA): Lake Peigneur southeast to Jeanerette and south to Weeks DISTANCE INLAND TO DEBRIS LINE (FT): None DISTANCE INLAND OF SURGE INUNDATION (FT): 30,000 – 50,000 MAJOR FLOOD SOURCES: Gulf of Mexico MAP PANEL NAMES AND NUMBERS: Delcambre – 49 Hamock Lake – 84 Jeanerette – 51 Kemper – 70 New Iberia South – 50 Tigre Lagoon – 68 Weeks – 69 PARISH: Jefferson LOCATION (CITY OR AREA): Southeast border with Plaquemines Parish DISTANCE INLAND TO DEBRIS LINE (FT): None DISTANCE INLAND OF SURGE INUNDATION (FT): 0-9,200 MAJOR FLOOD SOURCES: Gulf of Mexico MAP PANEL NAMES AND NUMBERS: Lake Laurier – 99 Three Bayou Bay – 98 PARISH: Jefferson Davis LOCATION (CITY OR AREA): Southwest near Calcasieu and Cameron Parishes DISTANCE INLAND TO DEBRIS LINE (FT): None DISTANCE INLAND OF SURGE INUNDATION (FT): 720 – 26,000 Note: Distance inland from channel bank of flooding source. MAJOR FLOOD SOURCES: Bayou Lacassine MAP PANEL NAMES AND NUMBERS:Hayes – 29 Lacassine – 16 Thornwell – 30 Welsh South – 17 PARISH: Jefferson Davis LOCATION (CITY OR AREA): Southeast near Cameron, Vermilion, and Acadia Parishes DISTANCE INLAND TO DEBRIS LINE (FT): None DISTANCE INLAND OF SURGE INUNDATION (FT): 70 – 27,500 Note: Distance inland from channel bank of flooding source. MAJOR FLOOD SOURCES: Lake Arthur and Mermentau River MAP PANEL NAMES AND NUMBERS: Jennings – 18 Lake Arthur – 31 PARISH: Plaquemines LOCATION (CITY OR AREA): Venice to Phoenix DISTANCE INLAND TO DEBRIS LINE (FT): None DISTANCE INLAND OF SURGE INUNDATION (FT): 258,000 MAJOR FLOOD SOURCES: Gulf of Mexico MAP PANEL NAMES AND NUMBERS: Bastian Bay – 106 Bay Batiste – 102 Bay Coquette – 110 Bay Ronquille – 105 Buras – 107 Empire – 104 Happy Jack – 101 Lake Laurier – 99 Pass Tante Phine – 111 Phoenix – 91 Pilottown – 112 Pointe a la Hache – 100 Port Sulphur – 103 Three Bayou Bay – 98 Triumph – 108 Venice – 109 PARISH: St. John the Baptist LOCATION (CITY OR AREA): Western portion DISTANCE INLAND TO DEBRIS LINE (FT): None DISTANCE INLAND OF SURGE INUNDATION (FT): 3,200 – 24, 000 MAJOR FLOOD SOURCES: Lake Pontchartrain MAP PANEL NAMES AND NUMBERS: Laplace – 33 Manchac – 6 Ponchatoula SE – 7 Ruddock – 20 PARISH: St. Mary LOCATION (CITY OR AREA): Sorrel east to the border of Assumption Parish DISTANCE INLAND TO DEBRIS LINE (FT): None DISTANCE INLAND OF SURGE INUNDATION (FT): 48,000 – 91,000 MAJOR FLOOD SOURCES: Gulf of Mexico MAP PANEL NAMES AND NUMBERS: Amelia – 90 Centerville – 72 Ellerslie – 86 Franklin – 71 Hammock Lane – 84 Jeanerette – 51 Kemper – 70 Marone Point – 85 Morgan City – 89 North Bend – 87 Patterson – 88 Weeks – 69 PARISH: St. Tammany LOCATION (CITY OR AREA): Madisonville to northern portion of Mandeville DISTANCE INLAND TO DEBRIS LINE (FT): None DISTANCE INLAND OF SURGE INUNDATION (FT): 100 – 13,000 MAJOR FLOOD SOURCES: Lake PontchartrainMAP PANEL NAMES AND NUMBERS: Covington – 5 Madisonville – 4 PARISH: St. Tammany LOCATION (CITY OR AREA): City of Mandeville DISTANCE INLAND TO DEBRIS LINE (FT): 400 – 8,000 DISTANCE INLAND OF SURGE INUNDATION (FT): None beyond debris line MAJOR FLOOD SOURCES: Lake Pontchartrain MAP PANEL NAMES AND NUMBERS: Mandeville – 8 PARISH: St. Tammany LOCATION (CITY OR AREA): West of Mandeville to Lacombe to south of Slidell DISTANCE INLAND TO DEBRIS LINE (FT): None DISTANCE INLAND OF SURGE INUNDATION (FT): 7,000 – 20,000 MAJOR FLOOD SOURCES: Lake Pontchartrain MAP PANEL NAMES AND NUMBERS: Lacombe – 9 North Shore – 21 Slidell – 10 PARISH: Tangipahoa LOCATION (CITY OR AREA): Southern portion DISTANCE INLAND TO DEBRIS LINE (FT): None DISTANCE INLAND OF SURGE INUNDATION (FT): 25,000 – 60,000 MAJOR FLOOD SOURCES: Lake Pontchartrain MAP PANEL NAMES AND NUMBERS: Manchac – 6 Ponchatoula – 2 Ponchatoula NE – 3 Ponchatoula SE – 7 PARISH: Vermilion LOCATION (CITY OR AREA): Northwest along border with Jefferson Davis Parish DISTANCE INLAND TO DEBRIS LINE (FT): None DISTANCE INLAND OF SURGE INUNDATION (FT): 330 – 8,300 Note: Distance inland from channel bank of flooding source. MAJOR FLOOD SOURCES: Lake Arthur and Mermentau River MAP PANEL NAMES AND NUMBERS: Gueydan – 32 Lake Arthur – 31 PARISH: Vermilion LOCATION (CITY OR AREA): West of Forked Island DISTANCE INLAND TO DEBRIS LINE (FT): 32,000 –50,000 DISTANCE INLAND OF SURGE INUNDATION (FT): 37,000 – 116,000 Note: Distance inland from delineated Debris Line. MAJOR FLOOD SOURCES: Gulf of Mexico MAP PANEL NAMES AND NUMBERS: Fearman Lake – 81 Floating Turf Bayou – 79 Forked Island – 65 Forked Island NW – 45 Jacks Point Island – 64 Kaplan South – 46 Lake Le Bleu – 63 Latanier Bayou – 44 Mulberry Island West – 94 Mulberry Island East – 95 Pecan Island – 80 Rollover Lake – 93 PARISH: Vermilion LOCATION (CITY OR AREA): East of Forked Island DISTANCE INLAND TO DEBRIS LINE (FT): None DISTANCE INLAND OF SURGE INUNDATION (FT): 30,000 – 77,000 MAJOR FLOOD SOURCES: Gulf of Mexico MAP PANEL NAMES AND NUMBERS: Abbeville East – 48 Abbeville West – 47 Cheniere au Tigre – 96 Delcambre – 49 Fearman Lake – 81 Forked Island – 65 Hebert Lake – 67 Hell Hole Bayou – 97 Intracoastal City – 66 Kaplan South – 46 Mulberry Island East – 95 Pumpkin Islands – 82 Redfish Point – 83 Tigre Lagoon – 68 Damage caused by coastal storm surge was observed all along the gulf coast of Louisiana. The landfall of Hurricane Rita between Sabine Pass in Texas and Johnson’s Bayou in Louisiana placed the central and western portion of the coast within the right front quadrant of the storm. In this section of the counterclockwise wind circulation, the forward speed of the storm added to the magnitude of the wind speeds and storm surge. The wetlands that line the Louisiana coastline was able to absorb some of the impacts from the storm surge; however, it was not enough to prevent the surge from reaching inland. Due to a low elevation and very gentle slope of this coastal area, the storm surge reached 20 to 30 miles further inland along the coastline of Cameron Parish and Vermilion Parish with maximum surge elevations between 12 and 16 feet measured near the shoreline. In Cameron Parish, the debris line along the western side of the parish was found to be very close to the coastline. In the eastern side of Cameron Parish, the debris line extended further inland, up to 7.5 miles from the coastline. Except for some minor areas with higher elevations, the remaining portion of Cameron Parish north of the debris line was inundated by storm surge from the Gulf of Mexico. Calcasieu Lake, which is about 30 miles east of the landfall location, had maximum surge heights of 9.5- to 10-feet along its northern shoreline. The storm surge from the Gulf of Mexico experienced in Cameron Parish also crossed the border of the parish and stretched five miles further north into Calcasieu Parish. Storm surge also inundated areas an additional three miles inland along the Sabine River, Calcasieu River, and Bayou Lacassine in Calcasieu Parish. The southern potion of Jefferson Davis Parish experienced a storm surge up to 5 miles from the banks of Bayou Lacassine and the Mermentau River. From the eastern border with Cameron Parish, the debris line continued into Vermilion Parish along State Highway 82 for an additional 22 miles. The debris line extends inland from the coastline of Vermilion Parish up to 9.5 miles. Vermilion Parish was inundated by surge up to 30 miles inland from the coast. The surge inundation continued into Iberia Parish and extended up to 9.5 miles from the coastline. Storm surge also affected St. Mary Parish and extended up to 17 miles inland from the coast. To the north of St. Mary Parish, Assumption Parish was also inundated by storm surge, which continued up to 1,200 ft. from the border with St. Mary Parish. Plaquemines Parish, on the eastern side of the Louisiana coast, experienced surge inland along the Mississippi River channel for over 45 miles from the coast. The inundation did not extend beyond 1.2 miles from the banks of the channel because of levees and roadways that acted as a barrier. Flooding on the northern side of Lake Pontchartrain created a 19.5-mile WWL in St. Tammany Parish. The WWL extended up to 4.5 miles inland from Lake Pontchartrain. The area to the west of Lake Pontchartrain, including Lake Maurepas and portions of Tangipahoa Parish, Livingston Parish, Ascension Parish, and St. John the Baptist Parish, experienced storm surge flooding up to 22 miles inland. Conclusions The majority of the coastal surge and damage occurred in Cameron and Vermillion Parishes. The southern portions of Calcasieu and Jefferson Davis Parishes and the coastal regions of Iberia, Saint Mary, and Plaquemines Parishes were also affected by coastal surge. Although field crews attempted to visit coastal areas along the Gulf of Mexico in Terrebonne, Lafourche, Jefferson, Plaquemines and St. Bernard’s Parishes, the swampy characteristics of the Louisiana Coast prevented access to and clear identification of WWL points in many of these areas. NWI information is shown on the WWL Maps to illustrate the extent of wetlands in southeastern Louisiana. Effects from surge in these areas were partially absorbed by the wetlands, but the wetlands did not provide full ‘buffering’ from the effects of the storm. Similarly, low lying wetland areas west of Lake Pontchartrain were difficult to access, and thus estimates of the WWL in these areas are based on CHWMs and topography. Field crews noted that there is not significant development for much of this area due to the land cover. North of Lake Pontchartrain, St. Tammany Parish experienced damage as result of flooding from surge along Lake Pontchartrain. A total of 67 WWL points were identified by field crews in southeast Louisiana. Calcasieu Parish had the greatest number of identified WWL points with twenty-four points. Eight WWL points were identified in both St. Tammany and Vermillion Parishes, six were in St. Mary Parish, four were in both Lafourche and Livingston Parishes, three were in Cameron Parish, two were in both Assumption and Plaquemines Parishes, and one WWL point was in each of the following parishes: Iberia, Jefferson Davis, Orleans, St. Charles, St. Martin, and Terrebonne. Of these 67 points, seven were within a range of approximately 200 feet from either the inundation polygon or the debris line developed by photointerpretation of the post-event imagery. Using the remaining 60 points, including the field crews’ observations, photos, post-event imagery, local topography, and base mapping, engineers analyzed the photointerpreted debris line and inundation area to extend these boundaries beyond the post-event imagery. These engineers decided that 32 of these points would be used to actually edit and extend the inundation polygon and debris line. Therefore, the field data presented a good complement to the information developed solely from analyzing the post-event imagery. Appendix A: Wind Water Line Data Points Appendix A contains a data table for the WWL data points. DUE TO PRIVACY ISSUES (ADDRESSES ARE INCLUDED TO IDENTIFY POINT LOCATIONS), THIS APPENDIX IS NOT AVAILABLE IN THE VERSION OF THE REPORT POSTED ON THE FEMA WEBSITE. Appendix B: Photographs Appendix B contains an index and thumbnails of the photographs. The naming convention for the photographs uses the data point ID Number (RLAC-XX-XX) and then a sequential number for the photographs(s) associated with that ID Number (RLAC-XX-XX-1, RLAC-XX-XX-2). In most instances, two photographs were taken for each data point; however, when additional information was needed, three photographs were taken. NOTE: The SD memory cards containing some of the images became corrupt and the images on them were unrecoverable. For this reason, images for 25 of the WWL data points are not available. DUE TO PRIVACY ISSUES, THIS APPENDIX IS NOT AVAILABLE IN THE VERSION OF THE REPORT POSTED ON THE FEMA WEBSITE. Appendix C: Debris Line and Inundation Mapping Summary (HMTAP Task Order 443) Appendix C contains a summary report from HMTAP Task Order 443: Rapid Response, Aerial Radar – Texas and Louisiana. The aerial imagery collected under this task order was used to delineate a debris line and flood boundaries that served as base data for HMTAP Task Order 447, Rapid Response, Hurricane Rita Wind Water Line – Louisiana. WWL data points were used in conjunction with these data to delineate the WWL. Appendix D: Notes on Analysis of Wind Water Line Data Points Appendix D contains a record of the comparison of the photointerpreted data to the field data and the actions taken to resolve any differences between the two. Where photointerpreted data were not available, notes on how the WWL data points were used are included. Appendix E: Wind Water Line Maps Appendix E contains the Wind Water Line Maps illustrating the location of the Wind Water Line from Rita along the Louisiana Coast. 1 This HWM illustrates the concept of a water mark on a structure, but would be too high to be considered a WWL data point. 2 The SD memory cards containing some of the images became corrupt, and as such, the images on them were unrecoverable. For this reason, images for 25 of the WWL points are not available.