Mountaintop Mining/Valley Fills in Appalachia. Background Mountaintop coal mining is a surface mining practice used in the Appalachian states involving.

Slides:

Advertisements

Similar presentations

Action Effectiveness Monitoring in the Upper Columbia (Chapter 4) Karl M. Polivka, Pacific Northwest Research Station, USDA Forest Service.

Advertisements

Rehabilitate Newsome Creek Watershed BPA Project #

20 th Annual Surface Mined Land Reclamation Technology Transfer Seminar Indiana Society of Mining and Reclamation December 5, 2006.

Framework for the Ecological Assessment of Impacted Sediments at Mining Sites in Region 7 By Jason Gunter (R7 Life Scientist) and.

WATER QUALITY ANALYSIS for ANTIDEGRADATION

Coal Mining Activities Mark A. Taylor Huntington District Corps of Engineers.

401 Water Quality Certification South Carolina Department of Health and Environmental Control.

Stormwater Rulemaking Briefing US Environmental Protection Agency.

Section 3: Mining Regulations and Mine Reclamation

MINING. Overview StepsDescriptionEnvironmental Effects MiningRemoving mineral resources from the ground Mine wastes – acids and toxins Displacement of.

Lec 12: Rapid Bioassessment Protocols (RBP’s)

What is an In Lieu Fee Program ? Clean Water Act - Section 404 : “no overall net loss” of wetland acreage and functions. One mechanism for providing Compensatory.

Water Pollution. Watershed A watershed is an area of land from which all the water drains to the same location, such as a stream, pond, lake, river, wetland.

Getting the Big Picture How to Look at Your Watershed Indiana Watershed Planning Guide,

Aquatic Plants and the Environment (SWES, ECOL, WFSc 474/574)

Hydrologic Issues in Mountaintop Mining Areas Ronald Evaldi, USGS-WSC, Charleston, WV Daniel Evans, USGS-WSC, Louisville, KY Hugh Bevans, USGS-WSC, Charleston,

Metric (Family Level) Standard Best Value (95 th or 5 th percentile) Worst Possible Value Expected Response to Degradation Total Taxa180 EPT Taxa120 %EPT91.90.

SEEDS Environmental Justice in West Virginia & Louisiana Megan Litke, Sustainability Coordinator.

West Virginia University Natural Stream Restoration Program An Interdisciplinary Program Focusing on Research, Education, and Professional Services in.

Section 404 of the Clean Water Act 404(b)(1) Guidelines Field Exercise

Headwater Stream Restoration in Mined Watersheds of the MAH Todd Petty, Mike Strager WVU Division of Forestry and Natural Resources Paul Ziemkiewicz WV.

US EPA Region IV Surface Coal Mining Field Activities Adventures in Mountain Top Mining / Valley Fill Chris Decker.

Lake Erie HABs Workshop Bill Fischbein Supervising Attorney Water Programs March 16, 2012 – Toledo March 30, Columbus.

What is a mineral? A naturally occurring solid with: Characteristic chemical composition orderly internal structure Characteristic set of physical properties.

Formation and Treatment

US Army Corps of Engineers BUILDING STRONG ® 2012 Changes to Stream Mitigation Procedures and Guidelines Mike Moxey USACE, Mobile District IRT Chair May.

Building Strong! 1 US Army Corps of Engineers Regulatory Program Kimberly McLaughlin Program Manager Headquarters Operations and Regulatory Community of.

Mountaintop Mining/Valley Fills in Appalachia Mountaintop Mining in Appalachia Mrs. Jackson Period 2.

Mountaintop Removal Mining (MTR) and the Hydrologic Effects on Terrestrial and Aquatic Ecosystems Background [1] Mountaintop removal (MTR) mining removes.

Coastal development impacts on biological communities in the Chesapeake Bay Examples from the Atlantic Slope Consortium R

Section 3: Mining Regulations and Mine Reclamation

Guided Notes on the Human Impact on Land Resources

Focus on the Headwaters The Shenandoah Watershed Study / The Virginia Trout Stream Sensitivity Study Rick Webb Department of Environmental Sciences University.

National Aquatic Resource Surveys Wadeable Streams Assessment Overview November, 2007.

IMLA New England Regional Land Use Seminar June 21, 2012 Work Session 2. Storm Water Management James N. Katsiaficas, Esq. P.O. BOX 426 PORTLAND, MAINE.

THE EFFECTS OF SPECIFIC CONDUCTANCE OF WATER ON THE BENTHIC MACROINVERTEBRATE COMMUNITY DOWNSTREAM OF COAL MINING ACTIVITIES __________________________________.

Freshwater and Society Module 1, part C. Developed by: Updated: U?-m1c-s2 Water quality degradation

Rapid Bioassessment Protocols for low gradient streams) for species richness, composition and pollution tolerance, as well as a composite benthic macroinvertebrate.

Quantifying Stream Ecosystem Responses to Smart Growth: How to Design an Assessment Allison Roy Cross-ORD Postdoctoral Researcher US Environmental Protection.

Impacts of Mining, Mining Regulations & Mine Reclamation.

Bureau of Watershed Management Regulatory Proposal Chapter 102 [Erosion and Sediment Control] Erosion, Sediment and Stormwater Management February 21,

AQUACULTURE FACILITIES [objectives]

Impact Analysis. Impact Analysis (204) ODOT attempts to avoid, and minimize impacts to the natural environment throughout the PDP process Despite these.

Storm Water Permit Program Authority to regulate storm water discharges derives from 40 CFR Illinois EPA is delegated authority to administer this.

16.3. Bellringer The Environmental Impacts of Mining Because of the potential environmental impact of mining on a large scale, mining is one of the most.

The Jordan Cove Pacific Connector Gas Pipeline and Terminal.

Watershed Restoration: Aquatic Resource Conservation at a Watershed Scale Todd Petty Professor of Aquatic Sciences February 4, 2013.

EVALUATING STREAM COMPENSATION PERFORMANCE: Overcoming the Data Deficit Through Standardized Study Design Kenton L. Sena (EPA VSFS Intern), Joe Morgan,

Rebuttals Definition:

Mountaintop Mining/Valley Fills in Appalachia

Section 3: Mining Regulations and Mine Reclamation

Coal Mining Activities

Discover Life in West Virginia ( )

Coal Mining Activities

Section 3: Mining Regulations and Mine Reclamation

Environmental Law Fall 2018

Section 3: Mining Regulations and Mine Reclamation

Section 3: Mining Regulations and Mine Reclamation

Human Activity and Ground Water

Lake Erie HABs Workshop

Objectives Describe seven important potential environmental consequences of mining. Name four federal laws that relate to mining and reclaiming mined land.

Human Activity and Ground Water

The Human and Environmental Cost of Mountaintop Removal

Human Activity and Ground Water

Section 3: Mining Regulations and Mine Reclamation

The Index of Biotic Integrity (the BI or IBI)

Mary River Project Phase 2 Proposal Freshwater Environment

IBI’s: An Introduction

Presentation transcript:

Mountaintop Mining/Valley Fills in Appalachia

Background Mountaintop coal mining is a surface mining practice used in the Appalachian states involving the removal of mountaintops to expose coal seams and disposing of the associated mining overburden in adjacent valleys. The overburden is disposed in valley fills. Valley fills occur in steep terrain where there are limited disposal alternatives. The valley fill disposal method has resulted in substantial loss of headwater streams and habitat.

Background Mining operations regulated under the Clean Water Act (CWA) including discharges of pollutants to streams from valley fills (CWA Section 402) and the valley fill itself where the rock and dirt is placed in streams and wetlands (CWA Section 404). Coal mining operations also regulated under the Surface Mining Control and Reclamation Act of 1977 (SMCRA).

Mountaintop Mining Impacts on Streams

Dragline Operation

Mining Sequence

Typical Valley Fill Construction Sediment Pond ConstructionFill Placement Completed Fill Placement Regrading and Revegetation Completed

3,113 acres = 4.86 sq. miles

Mountaintop Mining

Technical Studies

Mountaintop Mining Impacts on Streams Approximately 1200 miles of headwater streams (or 2% of the streams in the study area) were directly impacted by MTM/VF features including coal removal areas, valley fills, roads, and ponds between 1992 and An estimated 724 stream miles (1.2 % of streams) were covered by valley fills from 1985 to Certain watersheds were more impacted by MTM/VF than others. Based upon the study of 37 stream segments, intermittent streams and perennial streams begin in very small watersheds, with a median of 14 and 41 acres respectively. Streams in watersheds where MTM/VFs exist are characterized by an increase of minerals in the water as well as less diverse and more pollutant-tolerant macroinvertebrates and fish species. Questions still remain regarding the correlation of impacts to the age, size, and number of valley fills in a watershed, and effects on genetic diversity. Some streams below fills showed biological assemblages and water quality of good quality comparable to reference streams.

Mountaintop Mining Impacts on Streams Streams in watersheds below valley fills tend to have greater base flow. These flows are more persistent than comparable unmined watersheds. Streams with fills are generally less prone to higher runoff than unmined areas during most low-frequency storm events; however, this phenomenon appears to reverse itself during larger rainfall events. Wetlands are, at times inadvertently and other times intentionally, created by mining via erosion and sediment control structures. These wetlands provide some aquatic functions, but are generally not of high quality.

Mountaintop Mining Impacts on Streams (USEPA, 2002a)

Mountaintop Mining Impacts on Streams (USEPA, 2002a

Mountaintop Mining Impacts on Streams Statistical analyses were applied to determine correlation of parameters in unmined, filled, filled/residential and mined sites. The analysis indicates that biological integrity is impaired by mining. Unmined sites have a higher biotic integrity. Unmined sites have more taxa and more sensitive taxa. The strongest association with water chemistry suggested that zinc, sodium, and sulfate concentrations were negatively correlated with fish and macroinvertebrate impairments. Selenium and zinc were negatively correlated with the West Virginia Stream Condition Index (WVSCI). The potential drivers of the impaired condition are mining practices and material handling practices and the geological factors associated with specific coal seams and overburden.

Value of Headwater Streams – The ephemeral and intermittent reaches of are vital components of the ecosystem and require greater attention to functional importance Forest Fragmentation – Not directly regulated through CWA or SMCRA – Timing and location of mining activity may reduce impacts Compensatory Mitigation for Headwater Streams – Protocols need to be developed to replace functions lost Selenium Bioaccumulation Potential – The scientific community needs to reach consensus on a selenium standard Social/Economic and Heritage issues – Local and regional information and understanding is not adequate to quantify issues including Environmental Justice Cumulative Impacts – Science-based thresholds for individual and cumulative environmental costs have not been identified EPA Concerns

Comment period closed January 21, ,500 Comments Received