9.14 Military Aircraft, Jet

Categories 639, 646, 658, 670, 673, 676, and 679

9.14.1 Introduction

These categories account for criteria pollutant emissions (particulate, organic, NO_x, SO_x, and CO) from gas turbine (jet) engines from military aircraft at various air bases and naval fields or airports in the Bay Area where military operations exist.

Category	Description
639	Military, Jet (Alameda NAS)
646	Military, Jet (Moffett Field)
658	Military, Jet (Travis AFB)
670	Military, Jet (San Francisco International)
673	Military, Jet (Oakland International)
676	Military, Jet (San Jose International)
679	Military, Jet (Hayward)

The engine consists of a compressor, a combustion chamber and a turbine. Air entering the forward end of the engine is compressed and then heated by burning fuel in the combustion chamber. The engine uses its fan to accelerate additional air around the outside of the engine producing exhaust gases for efficient propulsion.

9.14.2 Methodology

Categories 639, 646, 658, 670, 673, 676, and 679 are considered an area source category since they cover facilities / emission sources that are not directly permitted by the District, and hence not systematically cataloged. Emissions for area source categories are determined using the formula:

Current Year Emissions = Base Year Emission X Growth Profile, and,

Base Year Emission = Throughput X Control Factor X Emission Factor

where,

• throughput or activity data for applicable base year(s) is determined using a top-down approach (e.g. state-, national-level data);
• emission factor is derived from general literature, specific literature and reports, and/or source testing results provided by Air District staff;
• control factor (if applicable) is determined by District and state rules and regulations in effect;
• and, historical backcasting and forecasting of emissions is based on growth profiles as outlined in the Trends section of this chapter

More details on throughput, county distribution, emission factors and controls is provided in the following subsections.

Normal flight and ground operation modes of the aircraft constitutes the landing/takeoff (LTO) cycle. For criteria pollutant emission inventory, the LTO cycle is grouped into five modes, which is equivalent to two operations in an airport activity. These include:

1. Startup, idle and taxi out
2. Take-off
3. Climb out to about 2,300 feet–this height is considered the average mixing depth and assumed inversion height, wherein aircraft exhaust emissions are released below it
4. Descent/approach from about 2,300 feet, touch down, and landing run
5. Taxi in, idle and shutdown

For greenhouse gas (GHG) emission inventory, in addition to LTO cycle explained above, the aircraft landing approach and climb out modes above 2,300 feet elevation and aircraft cruise mode in the District’s air space is also included.

(a) Activity Data / Throughput

Number of aircraft flight operations in the Bay Area were obtained from the airports with military aircraft activity. Presently, the Travis Air Force Base is the only major military facility in the Bay Area with significant military aircraft operations. Share of military aircraft operations at the Bay Area commercial airports is much smaller compared to the Travis Airforce Base.

(b) County Distribution / Fractions

The county location of each airbase, naval facility, or airport with military activities in the Bay Area was used to distribute emissions into each county.

(c) Emission Factors

The modal emission rate information and the fuel specific greenhouse gas emission coefficients for similar aircraft were obtained from the International Civil Aviation Organization (ICAO) Aircraft Engine Emissions Data Bank³⁹⁹, the Intergovernmental Panel on Climate Change (IPCC)⁴⁰⁰, the FAA’s Aviation Environmental Design Tool (AEDT)⁴⁰¹, the U.S. Environmental Protection Agency (EPA) document AP-42^EPA. 1995. AP-42. Compilation of Air Pollutant Emissions Factors. < https://www.epa.gov/regulations-emissions-vehicles-and-engines/regulations-nitrogen-oxide-emissions-aircraft>], and the California Air Resources Board (CARB)⁴⁰².

Emission rates vary according to engine type and operating mode. Emission factors for a specific aircraft were estimated by the equation:

\[ \text{EMF} = \text{N} \times \sum{\left( v_e / v_t \right)_{m,p}} \times \text{TIM} \]

(d) Control Factors

No emission controls have been implemented by the Air District for these categories. In general, Federal airport noise regulations, over the years, have forced changes in aircraft industry, resulting in replacement of loud and dirtier engines with newer, quieter, and cleaner burning engines.

(e) Speciation

The ROG/TOG ratios applied to this category or this group of related categories are based on an Air District internal speciation profile. Multiple data sources have been used for developing speciation profiles, such as Air District-approved source tests, TOG speciation ratios used by other regional air quality agencies, and relevant literature including latest speciation profiles developed by CARB⁴⁰³ and the US Environmental Protection Agency⁴⁰⁴. For this category or group of categories, ROG constitutes 99.11% of TOG. Further assessment and improvement of ROG/ TOG speciation profiles has been planned in future inventory updates.

The PM_2.5/PM and the PM₁₀/PM ratios applied to this category or this group of related categories are based on an Air District internal speciation profile. Multiple data sources have been used for developing speciation profiles, such as Air District-approved source tests, PM speciation ratios used by other regional air quality agencies, and other relevant literature. These ratios are not necessarily consistent with the latest speciation profiles developed by CARB⁴⁰⁵ or the US Environmental Protection Agency. For this category or group of categories, PM_2.5 constitutes 96.7% of total PM and PM₁₀ constitutes 97.6% of total PM. The Air District staff routinely review speciation profiles and may update ratios as needed for improving emissions estimates.

(f) Emission Calculation Equation

TOG emissions per landing and take-off (LTO):

\[ \ \text{TOG Emissions } = \text{LTOs/yr} \times \text{lb/LTO} \div 365\ \text{day/yr} \div \text{2000 lb/ton} = \text{ton/day}\ \text{TOG} \]

9.14.3 Changes in Methodology

No changes to methodology were made in this version of the base year emissions inventory.

9.14.4 Emissions

A summary of emissions by category, county, and year are available via the associated data dashboard for this inventory publication.

In general, continuing effort in aircraft improvement, development of newer engine technology and their phasing in have resulted in reduced emissions. Low military aircraft activity results in negligible emissions for a majority of pollutants at the Bay Area commercial airports.

9.14.5 Trends

Trends in emissions tend to follow the military aircraft activity in terms of aircraft operations and the changes in fleet mix at the Bay Area military airports.

(a) Historical Emissions / History

Historical emissions through the years were based on the reported and/or estimated number of operations for each airbase and naval facility. Category 639 accounts for historical emissions from Alameda Naval Air Station which closed in 1997. Some emissions were assigned to year 1998 for this category for aircraft operations related to closure/cleanup activities.

(b) Future Projections / Growth

Projections are based on the airport reported data, the Regional Airport Plan Update Program, and other estimations. The military aircraft activity is not expected to grow as the commercial aircraft activity, which follows the regional development and/or population growth. In general, military aircraft activity is dependent on federal government or defense department policies and needs.

9.14.6 Uncertainties

The aircraft landing and take-off (LTO) cycle emission factors can be improved if the data specific to the local airports was available for the aircraft operational modes such as, Landing approach, Taxi/idle-in, Taxi/idle-out, Take-off, and Climb-out. Use of actual verses typical or standard data, such as, time in each mode, throttle settings, frequency of less than all-engine taxi operations and better accounting of emissions from aircraft auxiliary power units will also help improve emissions inventory.

9.14.7 Contact

Author: Sukarn Claire

Reviewer: Ariana Husain

Last Update: November 06, 2023

9.14.8 References & Footnotes

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399. The International Civil Aviation Organization (ICAO). https://www.easa.europa.eu/domains/environment/icao-aircraft-engine-emissions-databank↩︎

400. The Intergovernmental Panel on Climate Change (IPCC). https://www.ipcc.ch/↩︎

401. The FAA’s Aviation Environmental Design Tool (AEDT). https://aedt.faa.gov/↩︎

402. The California Air Resources Board. http://ww2.arb.ca.gov/homepage↩︎

403. CARB. 2022. ORGPROF. https://ww2.arb.ca.gov/speciation-profiles-used-carb-modeling↩︎

404. U.S. EPA. 2022. SPECIATE. https://www.epa.gov/air-emissions-modeling/speciate↩︎

405. CARB. 2022. PMSIZE. https://ww2.arb.ca.gov/speciation-profiles-used-carb-modeling↩︎