IMPROVING THE ENERGY EFFICIENCY &

IMPROVING THE ENERGY EFFICIENCY & ENVIRONMENTAL PERFORMANCE OF GOODS MOVEMENT James J. Winebrake, PhD., Rochester Institute of Technology Asllomar 2009 Conference on Transportation and Energy

Acknowledgements Although I am presenting today, much of the material was developed jointly with Dr. James J. Corbett, University of Delaware. I am indebted to the faculty and students in the Laboratory for Environmental Computing and Decision Making at RIT, including Bryan Comer, Chris Prokop, Dr. Scott Hawker, and Dr. Karl Korfmacher

My Job Today Present energy and environmental attributes of goods movement from multiple modes Discuss benefits from shifting from high energy-intensity modes to low energy-intensity modes Assess overall opportunities for mode-shifting in a larger systems context Provoke policy-focused discussion

Working Hypothesis We can solve a large part of the energy and environmental problems of freight transportation by moving ggoods off trucks and onto trains and ships. V.

Overview of Goods Movement

Goods Movement and GDP 4800 Ton Miles v. GDP for the U.S. (1987 2005) iles (Billions) Ton Mi 4600 4400 4200 4000 3800 3600 3400 3200 For every trillion dollar increase in GDP, we expect an additional 242 billion ton-miles. 3000 6000 7000 8000 9000 10000 11000 12000 GDP (Billions, 2000$) Source: Corbett and Winebrake, 2009.

6,000,000 U.S. Freight Transport by Mode, 1980 2030 5,000,000 Ton miles Millions of 4,000,000 3,000,000 2,000,000 1,000,000 0 1980 1985 1990 1995 2000 2005 2010 2015 2020 2025 2030 Truck Rail Domestic Shipping Air Source: Bureau oftransportationstatisticstable Table 1 46b (1980 2006); AEO 2009 (derived, 2007 2030).

8000.0 Projected Energy Use in U.S. Freight Transport, 2006 2030 7000.0 6000.0 Trillion BTU 5000.0 4000.00 3000.0 2000.0 AAGR: -Freight truck =1.3% -Freight rail = 0.9% -Air (freight carriers) = 2.8% -Domestic shipping = 0.9% 1000.0 0.0 2005 2010 2015 2020 2025 2030 Truck Rail Domestic Shipping Air Source:AEO2009 Table 45 Source: AEO 2009, Table 45.

Shipping, International 3.1% Percentage of Energy Related Transportation CO2 Emissions by Mode, 2008 Recreational Boats Air Military Use Lubricants 0.9% 9.8% 2.8% 0.3% Total emissions from transportation ~1.9 GtCO 2 eq/yr Shipping, Domestic Total emissions 12% 1.2% from all energy sectors ~5.9 GtCO 2 eq/yr Rail, Freight 2.2% Rail, Passenger 0.3% Freight Trucks 18.3% Bus Transportation 1.0% Light Duty Vehicles 57.8% Commercial Light Trucks 2.1% Source: AEO 2009, Table 19.

Modal Comparisons

5000 Energy Intensity of US Freight Modes, 1980 2006 (BTU/ton m mile) Energ gy Intensity 4500 4000 3500 3000 2500 2000 1500 1000 500 0 Note: These represent top-down averages and should not be used for blanket modal comparisons! 1980 1985 1990 1995 2000 2005 Truck Rail Domestic Shipping Source: Transportation Energy Data Book 27

Range of typical CO2 efficiencies for various cargo carriers Crude LNG General Cargo Reefer Chemical Bulk Container LPG Product RoRo / Vehicle Rail Road NOTE: Impacts are a function of many factors related to route and modal characteristics. 0 50 100 150 200 250 g CO2 / ton*km Source: Buhaug, et al. 2009

Some Examples Using GIFT The Geospatial Intermodal Freight Transportation ti (GIFT) model is a model jointly developed by the Rochester Institute of Technology and the University of Delaware, with funding support from US DOT/MARAD, Great Lakes Maritime Research Institute, ARB, among others.

Connect Multiple Transportation Mode Networks at Intermodal Transfer Facilities Road Network Rail Network Waterway Network Intermodal Transfer Facility

Define Economic, Energy, Time and Environmental Costs of Traversing Each Network Segment and Transfer Truck Segment Costs Distance Time Operating Cost Energy CO 2 NOx ESRI ArcGIS Network Analyst finds Shortest (least cost) routes.

Montreal to Cleveland (Ship 1) Montreal to Cleveland (Ship 2)

CO 2 (kg) 600 400 200 0 Emissions and Time of Delivery Tradeoffs Montreal to Cleveland Truck Ship (DR) Rail Ship (EJ) Time e-of Deliver y (hrs) 80 60 40 20 0 Truck Ship (DR) Rail Ship (EJ) Mode

CO 2 (kg) 400 300 200 100 0 CO 2 Comparison Truck Only Rail Only Ship-Truck Rail-Truck

2500 CO 2 Comparison CO 2 (kg) 2000 1500 1000 500 0 Truck Only Rail Only Truck-Rail

Opportunities i for Mode Shifting i

The IF-TOLD Mitigation Framework: A Context t for Mode Shifting Discussions i The IF-TOLD six-legged cow : Intermodalism/mode-shifting use of efficient modes Fuels use of low carbon fuels Technology application of efficient technologies Operations best practices in operator behavior Logistics improve supply chain management Demand reduce how much STUFF we consume Even a six-legged cow can move all legs dynamic, balancing!

Opportunities for Mode-Shifting Δ [ ( ) ] E = W c f p E E ij ik ijk ijk ijk i j k ΔE ij = energy savings due to modal shift from i to j W ik = work done by mode i for commodity k (ton-miles) c ijk = shipment compatibility fraction of i to j for k (cargo) f ijk = shipment feasibility fraction of i to j for k (infrastructure) p ijk = shipment practicality fraction of i to j for k (economic) E i = energy intensity factor for i (Btu/ton-mile) E j = energy intensity factor for j (Btu/ton-mile) Also need to account for intermodal transfer penalties.

Insights into c Cargo Characteristics ijk Percentage of Goods Movement in U.S. by Commodity (Sample) and Mode (2002 CFS Data) Misc. manufactured products 1.1% Elect. and electrical equip. Nonmetallic mineral products Basic chemicals Coal Nonmetallic minerals Gravel and crushed stone Other agricultural products Cereal grains Live animals and live fish 1.0% 4.3% 3.7% 21.9% 18% 1.8% 3.4% 3.5% 8.4% 0.1% 0% 50% 100% Truck Rail Water Other/Unknown Source: CFS 2002, Ton-Miles by Commodity and Mode

Insights into f ijk U.S. Intermodal Infrastructure

1800 Average Miles per Shipment by Mode for the U.S. (2007) 1600 1400 Miles per Shipment 1200 1000 800 600 400 200 0 Truck Rail Shallow draft Great Lakes Deep draft Air (included Parcel, Other and truck and U.S.P.S. or unknown air) courier modes Source: CFS 2007.

Estimating Mode Shifting Potential ΔE ij = [ W ( )] ik cijk fijk pijk Ei Ej k Truck Rail Water Intermodal USPS/Parcel Other Modal Shift Consider total ton-miles as a gridded box, where each cell is equivalent to 1%.

Estimating Mode Shifting Potential ΔE ij = [ W ( )] ik cijk fijk pijk Ei Ej k Truck Rail Water Intermodal USPS/Parcel Other Modal Shift Assume that about 50% of the cargo currently moved by truck is compatible with rail or ship due to physical properties, safety, loading logistics, etc. [c ijk ~ 0.50]

Estimating Mode Shifting Potential ΔE ij = [ W ( )] ik cijk fijk pijk Ei Ej k Truck Rail Water Intermodal USPS/Parcel Other Modal Shift Assume that of the cargo that is compatible, infrastructure can only serve 70% of the ton-miles in the short term [f ijk ~0.70]

Estimating Mode Shifting Potential ΔE ij = [ W ( )] ik cijk fijk pijk Ei Ej k Under these assumptions, there is potential to move ~ 5% of the total ton-miles (~12% of truck ton-miles) from truck to rail/ship. If truck is ~5 times more energy intense than rail/ship, then this implies ~8% reduction in energy consumption. Average distance by truck is 200 miles. Assume that ~50% of the ton-miles shipped > 200 miles and 25% are > 500 miles. Assume economic possibility exists for mode shifting for 35% of total truck trips. [p ijk ~ 0.35].

Policies i for Promoting Efficiencyi

Policy Options sy Intermod dalism Fuel Technolo ogy Operatio ons Logistics Policy Options I F T O L D Efficiency standards Taxes Subsidies Technology mandates Infrastructure investment R&D investment Alternative/LC fuels Demand Size/weight restrictions Demand management

Conclusion

Conclusion Modal shifts offer large side-by-side benefits System benefits vary depending on vessel, vehicle, locomotive, and route characteristics and are constrained by compatibility, feasibility, and practicality research needed here Suite of policy options should be considered recognizing freight sector as a system Wedge analysis needed for freight sector that looks at potential for the IF-TOLD set of elements

Citations Corbett, J. J.; Winebrake, J.J.; The impact of globalisation on international maritime transport t activity: it Past trends and future perspectives, in Globalisation, Transport, and Environment, edited by N. A. Braathen, Organisation for Economic Cooperation and Development (OECD), Paris, forthcoming. Buhaug, Ø.; Corbett, J. J.; Endresen, Ø.; Eyring, V.; Faber, J.; Hanayama, S.; Lee, D. S.; Lee, D.; Lindstad, H.; Mjelde, A.; Pålsson, C.; Wanquing, W.; Winebrake, J. J.; Yoshida, K. Updated Study on Greenhouse Gas Emissions from Ships; International Maritime Organization (IMO) London, UK, 2009. Energy Information Administration (2009). Annual Energy Outlook 2009. Washington, DC; available at http://www.eia.doe.gov/oiaf/aeo/index.html Bureau of Transportation ti Statistics, ti ti Commodity Flow Survey (2002 and 2007), available at http://www.bts.gov/programs/commodity_flow_survey/