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Final Clean Air Fine Particle Implementation Rule for the 1997 PM2.5 Standards

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Final Clean Air Fine Particle Implementation Rule for the 1997 PM2.5 Standards

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    1. Final Clean Air Fine Particle Implementation Rule for the 1997 PM2.5 Standards Rich Damberg EPA Office of Air Quality Planning and Standards June 20, 2007

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    3. 3 PM Components: Fine and Coarse Inhalable Coarse Particles Crushing, grinding, dust Resuspended dusts (soil, street dust) Coal/oil fly ash Aluminum, silica, iron-oxides Tire and brake wear Inhalable biological Materials (e.g., from soils, plant fragments) Sources: Resuspension of dust tracked onto roads Suspension from disturbed soil (farms, mines, unpaved roads) Construction/demolition Industrial fugitives Biological sources Exposure/Lifetime: Coarse fraction (2.5-10) lifetime of hours to days, distribution up to 100s km Fine Particles Combustion, gases to particles Sulfates/acids Nitrate Ammonium Organics Carbon Metals Water Sources: Coal, oil, gasoline, diesel, wood combustion Transformation of SOx, NOx, organic gases including biogenics High temperature industrial processes (smelters, steel mills) Forest fires Exposure/Lifetime: Lifetime days to weeks, regional distribution over urban scale to 1000s of km

    4. 4 Public Health Risks Are Significant Particles are linked to: Premature death from heart and lung disease Aggravation of heart and lung diseases Hospital admissions Doctor and ER visits Medication use School and work absences And possibly to Lung cancer deaths Infant mortality Developmental problems, such as low birth weight, in children Both long and short-term exposure to high levels of PM2.5 can cause health problems, most importantly, premature death from heart and lung disease. Short-term exposure to fine particles can aggravate heart and lung diseases, such as congestive heart disease, coronary artery disease, asthma and chronic bronchitis. Short-term exposures also have been seen to increase admissions to the hospital or emergency room, as well as increased use of medication, additional doctors visits, and absences from school or work. A number of recent studies indicate that fine PM may also be linked with death from lung cancer and infant mortality. These studies are currently being evaluated as part of EPA’s regularly scheduled review of the PM standards. Fine particles may also affect developing children, with effects such as low birth weight in newborns or reduced lung function growth in school-age children. Both long and short-term exposure to high levels of PM2.5 can cause health problems, most importantly, premature death from heart and lung disease. Short-term exposure to fine particles can aggravate heart and lung diseases, such as congestive heart disease, coronary artery disease, asthma and chronic bronchitis. Short-term exposures also have been seen to increase admissions to the hospital or emergency room, as well as increased use of medication, additional doctors visits, and absences from school or work. A number of recent studies indicate that fine PM may also be linked with death from lung cancer and infant mortality. These studies are currently being evaluated as part of EPA’s regularly scheduled review of the PM standards. Fine particles may also affect developing children, with effects such as low birth weight in newborns or reduced lung function growth in school-age children.

    5. 5 Some Groups Are More at Risk People with heart or lung disease Conditions make them vulnerable Older adults Greater prevalence of heart and lung disease Children More likely to be active Breathe more air per pound Bodies still developing Groups of people particularly at risk from fine particle pollution are: people with heart or lung diseases, such as congestive heart disease, coronary artery disease, asthma, or chronic obstructive pulmonary disease Older adults and children. These groups each include tens of millions of people. Together, these three groups may make up as much as 40% of America's total population. However, not all of these people live in areas with unhealthy particle levels. People in these sensitive groups who live in areas with good air quality, for example, would be at lower risk than those living in polluted areas. And there is some overlap in the groups. People with heart or lung diseases include a large proportion of older adults and children, for example. Although HEALTHY people, including children, are unlikely to experience serious effects, they may experience respiratory symptoms like those I described a moment ago. Particulate matter can also increase one's susceptibility to respiratory infections. Groups of people particularly at risk from fine particle pollution are: people with heart or lung diseases, such as congestive heart disease, coronary artery disease, asthma, or chronic obstructive pulmonary disease Older adults and children. These groups each include tens of millions of people. Together, these three groups may make up as much as 40% of America's total population. However, not all of these people live in areas with unhealthy particle levels. People in these sensitive groups who live in areas with good air quality, for example, would be at lower risk than those living in polluted areas. And there is some overlap in the groups. People with heart or lung diseases include a large proportion of older adults and children, for example. Although HEALTHY people, including children, are unlikely to experience serious effects, they may experience respiratory symptoms like those I described a moment ago. Particulate matter can also increase one's susceptibility to respiratory infections.

    6. 6 EPA’s PM2.5 Standards: Old and New

    7. 7 Significance of State Plans to Attain the 1997 PM2.5 Standards Among the criteria pollutants, PM2.5 poses the greatest health risks. Local and in-state sources are responsible for a significant portion of the PM2.5 problem and health risk These sources are the focus of PM2.5 SIPs. CAA requires these SIPs to demonstrate attainment as expeditiously as practicable to protect public health PM2.5 implementation rule describes the steps for determining required controls and the date that is as expeditious as practicable

    8. 8 Timeline for PM2.5 NAAQS Implementation

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    12. 12 Approaches to Address “Violating Attainment Areas” Informal discussion with States and sources Letter to State Enforcement action by State Voluntary measures plus MOA agreement as “backstop” Stakeholders agree on voluntary measures Enforcement as “backstop” SIP call Designation to nonattainment A combination of the above

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    14. 14 Pollutants to Address in Attainment Plans Direct PM2.5 and SO2: must be evaluated for control measures in each area NOx: Sources of NOx must be evaluated for control measures in each area, unless the State and EPA provide a technical demonstration showing that NOx emissions from sources in the State do not significantly contribute to PM2.5 concentrations in a specific area VOC: Sources of VOC are not required to be evaluated for control measures in each area, unless the State or EPA provide a technical demonstration showing that VOC emissions from sources in the State significantly contribute to PM2.5 concentrations in a specific area Ammonia: Sources of ammonia are not required to be evaluated for control measures in each area, unless the State or EPA provide a technical demonstration showing that ammonia emissions from sources in the State significantly contribute to PM2.5 concentrations in a specific area Rule provides basic guidance on potential analyses for technical demonstration; weight of evidence approach.

    15. 15 SIP Due Dates and Attainment Dates SIP revisions are due April 2008 Account for significant air quality improvement from regional/national rules (e.g. CAIR, diesel rules) and State rules on the books Evaluate controls for local and in-state contributors to the problem Adopt reasonably available measures to attain “as expeditiously as practicable” as required by the Clean Air Act (CAA) Include enforceable emissions limitations and source testing & monitoring procedures as required by the CAA Attainment date is no later than five years from date of designation (e.g. Apr. 2010) Extensions of 1-5 years are possible, considering: the severity of the nonattainment problem availability and feasibility of air pollution control measures Areas evaluated based on most recent 3 years of monitoring data (e.g. 2007-9 for April 2010 attainment date) No classification system

    16. 16 Reasonably Available Control Technology (RACT) / Reasonably Available Control Measures (RACM) For nonattainment areas, States need to adopt all reasonably available control measures (including RACT) needed to attain the standards as expeditiously as practicable and meet Rate of Further Progress requirements Collective analysis; demonstrate that no reasonably available additional measures would advance the attainment date by at least 1 year Guidance in rule Identify technically and economically feasible measures Conduct air quality modeling Select RACT/RACM Area-specific flexibility No tonnage threshold; evaluate smaller sources for areas with more severe problem Limited analysis without modeling if have projected design value of 14.5 ug/m3 of PM2.5 by 2007-2009 Preamble includes list of specific measures that States should consider as a starting point for RACT/RACM assessment

    17. 17 RACT/RACM for Sulfur Dioxide and Nitrogen Oxides from Electric Generating Units (EGUs) Presumption SO2: If State meets the Clean Air Interstate Rule (CAIR) SO2 cap through EGU reductions only, then the State may presume that its nonattainment area EGUs meet RACT and RACM NOx: If State meets CAIR NOx cap through EGU reductions only, then the State may presume that its nonattainment area EGUs meet RACT and RACM (provided NOx sources with SCR operate it year-round) A State may impose additional requirements on a specific plant if the State determines it is a reasonable means to attain expeditiously However, several factors should be considered re: potential disbenefits of beyond-CAIR controls Addressed case-by-case through SIP development process Direct PM2.5 RACT/RACM required for all EGUs

    18. 18 Reasonable Further Progress (RFP) RFP: annual incremental reductions in emissions for purpose of ensuring timely attainment RFP plan due with attainment demonstration in 2008 If attainment date is no later than 5 years from designations (up to April 2010), RFP is met by attainment demo For areas with an attainment date extension, the State must establish emission reduction milestones showing “generally linear” progress from 2002 through the 2009 emissions year and, if appropriate, the 2012 emissions year Alternate approach is possible if it would achieve equivalent air quality improvement Geographic range of SO2 and NOx emission sources included in RFP plan could extend up to 200 km beyond nonattainment area boundary. Mid-course review in 2011 for area with 2014 or 2015 attainment date Adopt new strategies as necessary

    19. 19 Contingency Measures To be implemented without further action if area fails to attain by its attainment date or fails to meet RFP requirements. Need to be measures other than those required for attainment or to meet RFP Level of reductions: one year’s worth of reductions needed for attainment in the area

    20. 20 Condensable Particulate Matter PM is comprised of filterable and condensable emissions. Condensable emissions are a significant percentage of direct PM2.5 emissions from some sources. Emission inventories have been required to include condensable PM for a number of years Test methods for condensable PM are available but concerns remain about data uncertainties and ability to develop enforceable emission limits for many sources in a short period of time. For sources included in PM2.5 attainment plans, emissions limits including condensable PM are required after January 2011. EPA encourages States that already have required emissions testing and established emission limits for condensable PM to continue Transition period activities EPA to update Method 201A & 202 for use by States during and following transition Stakeholder groups to conduct testing with updated Method 201A & 202 to update emissions factors EPA to work with ASTM to finalize dilution-based test method States to enhance databases to support regulations

    21. 21 Other Issues Improved source monitoring Transportation conformity General conformity Emission inventories Enforcement and compliance NSR addressed in a separate rulemaking

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