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Energy and the Environment
A dynamic fleet model of U.S light-duty vehicle lightweighting and associated greenhouse gas emissions from 2016-2050 Alexandre Milovanoff, Hyung Chul Kim, Robert Dale De Kleine, Timothy J. Wallington, I. Daniel Posen, and Heather L MacLean Environ. Sci. Technol., Just Accepted Manuscript • DOI: 10.1021/acs.est.8b04249 • Publication Date (Web): 25 Jan 2019 Downloaded from http://pubs.acs.org on January 26, 2019
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Environmental Science & Technology
A dynamic fleet model of U.S light-duty vehicle lightweighting and associated greenhouse gas emissions from 2016-2050 Alexandre Milovanoffa*, Hyung Chul Kimb, Robert De Kleineb, Timothy J. Wallingtonb, I. Daniel Posena, Heather L. MacLeana,c.
a Department
of Civil & Mineral Engineering, University of Toronto, 35 St. George Street,
Toronto, Ontario, M5S 1A4 Canada b Materials
& Manufacturing R&A Department, Ford Motor Company, Dearborn, Michigan
48121-2053, United States c
Department of Chemical Engineering & Applied Chemistry, University of Toronto, 200
College Street, Toronto, Ontario, M5S 3E5 Canada
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ABSTRACT
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Substituting conventional materials with lightweight materials is an effective way to
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reduce the life cycle greenhouse gas (GHG) emissions from light-duty vehicles. However,
3
estimated GHG emission reductions of lightweighting depend on multiple factors including
4
the vehicle powertrain technology and efficiency, lightweight material employed, and end-
5
of-life material recovery. We developed a fleet-based life cycle model to estimate the
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GHG emission changes due to lightweighting the U.S. light-duty fleet from 2016 to 2050,
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using either high strength steel or aluminum as the lightweight material. Our model
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estimates that implementation of an aggressive lightweighting scenario using aluminum
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reduces 2016 through 2050 cumulative life cycle GHG emissions from the fleet by 2.9 Gt
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CO2 eq. (5.6%), and annual emissions in 2050 by 11%. Lightweighting has the greatest
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GHG emissions reduction potential when implemented in the near-term, with two times
12
more reduction per kilometer traveled if implemented in 2016 rather than in 2030.
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Delaying implementation by 15 years sacrifices 72% (2.1 Gt CO2 eq.) of the cumulative
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GHG mitigation potential through 2050. Lightweighting is an effective solution that could
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provide important near-term GHG emission reductions especially during the next 10-20
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years when the fleet is dominated by conventional powertrain vehicles.
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TABLE OF CONTENTS (TOC)/ABSTRACT ART
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BODY 1. Introduction
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Climate change resulting from anthropogenic greenhouse gas (GHG) emissions is a
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major threat to the social and political stabilities of modern societies.1 Fossil fuel
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combustion by the U.S. light-duty vehicle fleet accounted for 1.1 gigatonnes (Gt) of CO2
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eq. emissions (17% of U.S. GHG emissions) in 2016.2 One way to reduce these GHG
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emissions is to reduce future light-duty vehicles’ fuel consumption by substituting
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conventional materials (e.g., mild steel, cast iron) with lightweight materials (e.g., high-
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strength steel, aluminum).3 Lightweighting a vehicle (i.e., reducing vehicle weight using
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lightweight materials) reduces energy requirements during the use phase.3 However,
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vehicle fuel consumption reductions are beneficial only if not outweighed by increased
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energy consumption elsewhere in the vehicle’s life cycle (e.g., production or end-of-life).4
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Life cycle assessment (LCA) is a method that evaluates the environmental impacts
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of a system or a product across its life cycle stages.5 The GHG emissions mitigation
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potential of adopting lightweight materials in vehicles has been studied in the literature
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with a life cycle perspective.4,6–13 Over the vehicle lifetime, the improvement in fuel
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consumption due to overall weight reduction is generally found to offset the potentially
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more energy-intensive production phase. However, the estimated reductions are strongly
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affected by different assumptions and methods in these studies (e.g., the mass ratio
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between the lightweight material and the substituted baseline material, or the weight-
39
induced fuel consumption).3 As a result, estimates of the life cycle energy reductions of
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lightweighting with aluminum and/or high strength steel (HSS) vary from a few percent to
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more than 50%.3 In addition the size and engine technology of the studied vehicle have
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an important influence on the GHG emission changes due to lightweighting.14–16
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Alternative vehicles such as electric or hybrid vehicles typically provide lower life cycle
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GHG emission reductions due to lightweighting compared to conventional (internal
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combustion engine) vehicles because of their higher powertrain efficiencies.17
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Equivalently, electrifying a lightweighted vehicle offers less life cycle emission reductions
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than electrifying a non-lightweighted vehicle suggesting a need to study lightweighting
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and electrification simultaneously. Similarly, lightweighting vehicles with lower fuel
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efficiency and larger engines provides larger life cycle emission reductions than
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lightweighing lower fuel efficiency vehicles, particularly when the powertrain is resized to
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maintain constant performance characteristics after-lightweighting.16–18 Thus, besides
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uncertainties in the fundamental lightweighting parameters, there is also substantial
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variation in the GHG emission reduction potential associated with the type of vehicles
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being lightweighted.
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Traditional product-centered LCAs provide useful insights to improve upon current
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lightweight designs or powertrain technologies, but are not appropriate for examining the
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dynamic effects of technological changes at a large scale.19,20 Vehicle-based LCAs do
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not assess the potential fleet-level GHG emission reductions due to vehicle
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lightweighting. Fleet-based assessments that combine LCA with a dynamic fleet model
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provide insights into environmental implications over time of new vehicle designs19, or
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powertrain technologies by capturing the evolution of light-duty vehicle attributes (e.g.,
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engine technology, size, weight)21. Among the studies that used a life cycle approach to
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assess the fleet-scale implications of lightweighting the light-duty fleet20–31, only one
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focused on the U.S. fleet and it only looked at energy use26 and not GHG emissions. Das
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et al.26 assessed the cumulative energy demand of lightweighting alternative powertrain
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vehicles with a fleet-based life cycle energy assessment of the U.S. light-duty fleet. They
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found that fleet lightweighting results in greater energy savings in conventional-vehicle
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dominated market scenarios compared to alternative-vehicle-dominated market
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scenarios.26 Other studies that explicitly considered the penetration of alternative
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powertrains along with lightweighting examined these as two distinct ways of reducing
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GHG emissions or as part of their modeling and did not evaluate interactions among
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these.22,23,28 Palencia et al.22,23 developed fleet-based models to assess different market
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penetrations of conventional and alternative vehicles with and without lightweighting in
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Colombia. They concluded that alternative powertrain penetration has a larger potential
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to reduce the fleet GHG emissions than lightweighting in Colombia. Finally, Modaresi et
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al.28 estimated the worldwide life cycle GHG emission reductions due to lightweighting
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with a focus on steel and aluminum. They determined that ‘extreme lightweighting’ using
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aluminum could provide 8% reduction in cumulative life cycle GHG emissions over 40
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years, and that closing the loops of automotive materials (i.e., improving the recycling
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processes to increase the recycled content of new vehicles) could enhance these
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emission reductions by up to 33%. Their modeling included the increasing penetrations
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of alternative vehicles but did not consider the impact of increasing engine efficiency over
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time on the lightweighting GHG emission mitigation potential.
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There is little information available on the fleet-scale GHG implications of
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lightweighting the U.S. light-duty fleet, or the interactions between lightweighting and
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technological changes such as fuel consumption improvement strategies or electrification
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at a fleet level. The latter gap is particularly noteworthy given the increase in vehicle
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efficiency and penetration of electric powertrains that may be required in the U.S. to meet
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the 2025 CAFE standards.32 We address the above gaps in the present study with the
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objective of quantifying the changes in GHG emissions that would result from
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lightweighting the U.S. light-duty fleet from 2016 to 2050. More specifically, we evaluate
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the influence of electric vehicle penetration, fuel consumption improvements, fleet
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characteristics (i.e., average light-duty vehicle size and total fleet stock), and automotive
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material flow on the U.S. fleet-scale GHG emission changes due to lightweighting. Finally,
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we examine GHG emissions as a function of the temporal penetration of lightweighting.
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Overall, we provide insights on: Should lightweighting be implemented in the U.S. light-
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duty fleet? And if so, are there substantial emission reduction benefits to accelerating the
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pace and intensity of lightweighting?
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2. Method
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The following section presents an overview of the method with additional details in the
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Supporting Information (SI) and the first release of the FLAME model can be found in a
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GitHub repository.33
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2.1.
Overall method: The FLAME model
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We develop a fleet-based life cycle model, the FLAME model (Fleet Life cycle
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Assessment and Material-flow Estimation) for the U.S. light-duty fleet from 2016 to 2050.
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Four modules (vehicle, fleet, automotive material flow and LCA modules) are linked to
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comprise FLAME (figure 1). The vehicle module establishes the vehicle characteristics
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by vehicle type and includes the lightweighting submodule that simulates the vehicle
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characteristics for different lightweighting scenarios for 2016 onwards. The fleet module
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calculates the annual fleet stock including model year and fuel type, as well as fleet
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kilometers traveled and fuel use by vehicle type. Then, the automotive material flow
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module estimates the quantities of recovered materials available from scrapped vehicles,
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along with consumption of primary and secondary (recycled) materials for new vehicle
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production. Finally, the LCA module combines outputs from all other modules with fuel
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and material emission factors to calculate the annual life cycle GHG emissions of the
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light-duty vehicle fleet.
117 118
Figure 1. The FLAME model. The model is comprised of four modules (vehicle, fleet,
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automotive material flow, and LCA modules) and is run from 2016 to 2050.
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2.2.
Vehicle module
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We consider twelve vehicle technology categories34 and two size categories, cars and
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light trucks35, to represent the U.S. light-duty fleet. Each vehicle type is assigned a
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material composition (% breakdown), curb weight (kg), and fuel consumption (l or
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kWh/100 km) for each model year. The vehicle material composition consists of six
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materials or material categories that sum to the curb weight: 1) high strength steel and
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advanced high strength steel (HSS/AHSS), 2) cast iron, 3) mild steel and other steels, 4)
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wrought aluminum, 5) cast aluminum, and 6) all other materials. The other materials
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combined typically represent less than 25% of the vehicle’s weight (Figures SI.5 and SI.6
129
in SI.2.2.3).
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The vehicle material composition, curb weight and fuel consumption are historically
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calculated from 1980 to 2015 and estimated from 2016 onwards in the lightweighting
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submodule with several scenarios. The “No lightweighting” scenario considers a constant
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set of material composition for all vehicle types based on the 2015 values. The “Steel
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Intensive”, “Aluminum Intensive” and “Aluminum Maximum” scenarios are derived from
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the scenarios of Modaresi et al.28, and essentially focus on two common lightweight
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materials: HSS/AHSS and aluminum. HSS/AHSS and aluminum can provide similar
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structural performance as conventional materials (i.e., steel and cast iron) but with less
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weight. The lightweighting scenarios consist of a set of subcomponent-specific material
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replacement rates and material substitution factors of replaced and replacing materials
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(SI.2.3.1 for more details). For example, the “Steel Intensive” scenario substitutes 100%
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of steel in body with HSS/AHSS with a substitution factor of 0.8 corresponding to a
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primary 20% weight reduction of steel in body. The “Aluminum Intensive” scenario
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possesses the same subcomponent-specific replacement rates as the “Steel Intensive”
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but with different and often lower substitution factors (e.g., 0.6 from mild steel to cast
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aluminum in body. Figure SI.9). Finally, the “Aluminum Maximum” scenario possesses
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larger replacement rates and for more components. By default, the scenarios include a
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gradual 15-year linear intensification of vehicle lightweighting from 2016 to 2030. The full
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lightweighted designs are achieved for the 2030 model-year vehicles and in every year
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from 2016 to 2030, new vehicles are lighter than in the previous year. In all scenarios we
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account for unrelated vehicle weight increases driven by the inclusion of more vehicle
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features and assume that 102 kg is added to vehicle weight from 2016 to 2050 based on
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historical trends reported in MacKenzie et al.36 From the primary material substitutions
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based on the lightweighting scenarios, and feature weight increases, structural secondary
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mass changes are estimated. The secondary mass changes represent further weight
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changes achieved in some supporting components, the powertrain or in the battery. The
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method is taken from Alonso et al.37 and Luk et al.14 using equations presented in
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MacKenzie et al.38 Relatively to baseline, secondary mass savings represent 51% of the
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total mass savings from lightweighting in the Aluminum and Steel Intensive scenarios and
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46% of the mass savings in the “Aluminum Maximum” scenario for conventional cars
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(Figure SI.17). Table 1 contains the material breakdown of the same conventional car
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before and after application of the complete lightweighting scenarios (Figures SI.18 and
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SI.19 for other vehicle types).
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Table 1: Material breakdown of an average conventional internal combustion engine
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gasoline car in 2016 and in 2030 for the No Lightweighting Scenario and three
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lightweighting scenarios: Steel Intensive, Aluminum Intensive, and Aluminum Maximum.
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The results include the primary material substitution, the feature content weight increase
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and the secondary mass savings.
Conventional car material breakdown (kg)
No 2016 Lightweighting (2030)
Steel Intensive (2030)
Aluminum Intensive (2030)
Aluminum Maximum (2030)
HSS/AHSS
291
298
486
280
97
Cast Iron
117
121
116
109
50
Mild steel and other steels
589
602
341
327
255
Wrought Aluminum
42
44
42
136
310
Cast Aluminum
117
121
117
153
181
Other
461
512
504
493
484
Total
1617
1698
1606
1498
1377
Weight savings (kg)
92
199
320
Weight savings (%)
5
12
19
168 169
The overall mass changes directly influence the vehicle fuel consumption. From the
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technical attributes of the vehicles and the powertrain technology, vehicle type specific
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fuel reduction values (FRVs) are estimated and used to obtain the fuel consumptions after
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weight changes. The FRVs are computed annually based on the physics-based models
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in Kim et al.16–18. The theoretical calculations of the FRVs are able to consider
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adjustments in powertrain characteristics to result in equivalent performance
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(acceleration time and horsepower) before and after lightweighting. By default, we
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calculate FRVs as the mean of FRVs with and without powertrain adjustments; the
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resulting mean values are consistent with assumptions from existing literature16–18. We
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assess bounding scenarios with and without powertrain adjustments in the sensitivity
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analysis. In addition, we model changes to FRVs due to annual efficiency improvements
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derived from Mowad et al.39 that occur independent of the lightweighting scenarios
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(SI.2.3.2). In 2016, estimated FRVs are 0.36 and 0.08 L of gasoline equivalent per 100
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kg and 100 km for internal combustion engine gasoline cars and battery electric cars,
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respectively.
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In addition, fuel consumptions are changed annually based on the AEO 201834
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projections. The fuel consumption improvements are based on sets of technological
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advances (e.g., engine friction reduction) implemented in the AEO projections and
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dependent on economic and policy factors. We build three scenarios to account for the
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parameter sensitivity (no improvement, default, and high fuel consumption improvements
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after 2016 in new vehicles).
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2.3.
Fleet module
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The fleet module calculates the annual stock of on-road light-duty vehicles by type and
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model year40, the annual fleet kilometers traveled (Fleet KT), and fleet fuel use (SI.3 for
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more details). We consider three prospective fleet stock cases based on the reference,
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high oil price and low oil price cases of AEO 2018.34 The cases represent bounding
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estimates of the prospective fleet stock size and light-truck shares. In addition, oil prices
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also influence the prospective fuel consumption improvements and the technology market
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share of the vehicles. We therefore evaluate the sensitivity of fleet GHG emissions to oil
198
prices.
199
We also develop a High EV Penetration case to represent optimistic projections of
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battery electric vehicle penetration based on estimates from Bloomberg Energy
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Finance41. In the High EV Penetration case, battery electric vehicle sales represent 26%
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of the light-duty vehicle market share in 2030 and 58% by 2040 (Figure SI.34).
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2.4.
Automotive Material Flow module
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The automotive material flow module estimates annually the amount of recovered
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materials from scrapped vehicles along with an exogenous contribution of scrap material
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from other sectors and the consumption from new vehicles of secondary and primary
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materials. The method is based on Modaresi et al.28 and two scenarios are developed
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(SI.4 for more details). The “Business As Usual” scenario considers no improvements in
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the material recycling processes of the scrapped automotive materials. Steel and cast
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iron are partially downcycled to construction steel, and wrought aluminum components
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are partially downcycled to cast aluminum. The “Closed Loop” scenario considers
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improvements in the material recycling processes by 2050 to recover steel and aluminum
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components of the scrapped vehicles for the new vehicles.
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2.5.
LCA module
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The LCA module estimates the annual life cycle GHG emissions associated with the
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U.S. light-duty fleet over the period 2016-2050. For each year, it includes the emissions
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from new vehicle production (materials production, manufacturing and assembly phases),
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use-phase of driven vehicles (fuel production and use), and disposal of scrapped
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vehicles. Imported and U.S. produced vehicles are assumed to have equivalent
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production emissions. GHG emissions are estimated using the 100-year Global Warming
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Potentials of the IPCC 5th assessment report42 with climate-carbon feedbacks. Emissions
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factors for fuels and materials are derived from GREET 201743, and the ecoinvent
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database version 3.344. Emission factors of electricity production and of primary aluminum
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production are updated annually (SI.5 for more details).
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3. Results
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3.1.
Light-duty fleet GHG emissions
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Figure 2a shows the annual life cycle fleet GHG emissions for a baseline with
228
technological changes (i.e., with penetration of alternative powertrain and fuel, and fuel
229
consumption improvements) and three main lightweighting scenarios. Figure 2b uses a
230
baseline without technological changes to illustrate the relative contribution of fuel
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consumption improvements, alternative powertrain penetration and Aluminum Maximum
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lightweighting. Despite an increasing fleet stock (Figure SI.36), alternative powertrain
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penetration and especially fuel consumption improvements lead to a minimum of 1.38 Gt
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CO2 eq. per year in 2034 (Figure 2b). Decreasing emissions are due to the gradual
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penetration of more efficient vehicles (driven by CAFE standards), after which increasing
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Fleet KT begins to dominate again through 2050. These emissions are dominated by fuel
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production and use (Figure SI.57), respectively representing 17% and 76% of the annual
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fleet GHG emissions in 2016. By 2050, lightweighting can contribute up to 0.17 Gt CO2
239
eq. reduction in annual fleet GHG emissions or 11% in the case of the Aluminum
240
Maximum scenario.
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Lightweighting generally brings higher upfront emissions, and a cumulative perspective
242
is needed to assess the resulting life cycle GHG emission changes (Figure 2c). The
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Aluminum Maximum scenario achieves cumulative reductions of 2.9 Gt CO2 eq. or 5.6%
244
from 2016-2050, compared to the baseline with technological changes. This is 2.3 and
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1.3 times more reductions than the Steel Intensive and Aluminum Intensive scenarios,
246
respectively. Through 2050, the Aluminum Maximum scenario includes large reductions
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from the fuel production and use phases (3.1 and 0.9 Gt CO2 eq. respectively) but adds
248
1.1 Gt CO2 eq. in primary material production from the higher need for aluminum. The
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Steel Intensive scenario decreases the GHG emissions of the primary material production
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phase but brings lower fuel savings. Thus, while scenarios with progressively more
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lightweighting may or may not have higher upfront emissions (i.e., production phase),
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they result in net GHG emission reductions due to greater fuel savings. The Steel
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Intensive scenario reduces emissions immediately, but the Aluminum Intensive and
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Aluminum Maximum scenarios take 1.4 year and 6.3 years, respectively, before reducing
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cumulative emissions relative to the No Lightweighting scenario.
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Figure 2. a) Annual U.S. light-duty fleet life cycle GHG emissions 2016-2050 by
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lightweighting scenario; (b) Annual U.S. light-duty fleet emissions 2016-2050 showing
259
contributions
260
improvements, and Aluminum Maximum lightweighting (the blue area is the cumulative
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GHG emission reduction due to Aluminum Maximum lightweighting); (c) Cumulative light-
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duty fleet GHG emissions changes 2016-2050 due to lightweighting, showing
263
contributions from life cycle phases.
264
3.2.
from
alternative
powertrain/fuel
penetration,
fuel
consumption
Effects of external factors on GHG emission changes from lightweighting
265
We assess four external factors and their influences on GHG emission changes from
266
lightweighting: fuel consumption improvements through vehicle efficiency improvements,
267
alternative powertrain and fuel penetration, automotive material recovery, and oil prices.
268
The first factor (fuel consumption improvements) ranges from no improvement to high
269
vehicle efficiency improvements after 2016 for all vehicle types. The high efficiency
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improvements lead to decreasing fuel consumptions and FRVs (fuel consumptions for
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conventional gasoline cars without lightweighting decrease from 8.7 to 6.8 L/100km and
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FRVs from 0.36 to 0.27 (L/100km)/100kg between 2016 and 2030). The alternative
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powertrain and fuel penetration factor ranges from no further penetration after 2016 to
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High EV Penetration (amounting to 151 million electric vehicles in 2050). The automotive
275
material recovery factor ranges from a business-as-usual recycling loop to a closed loop.
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For the Aluminum Maximum scenario in 2030, 78% of the wrought aluminum components
277
are from primary aluminum in the business-as-usual loop and 70% in the closed loop
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(Figure SI.46). Finally, the oil price factor ranges from low oil prices (313 million vehicles
279
with 47% light-trucks in 2050) to high oil prices (255 million vehicles with 35% light-trucks
280
in 2050).
281
Figure 3a shows ranges for the cumulative GHG emission changes from lightweighting
282
during the period 2016-2050, separated into cases representing bounding assumptions
283
for each of the four external factors. For each simulation, all factors are kept at their
284
default values except the factor under study. Lightweighting has larger GHG emission
285
reduction potential (left bound of each line) when fuel consumption improvements and
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alternative powertrain are not implemented, when oil prices are low, or when automotive
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material recovery is high for aluminum lightweighting and low for steel lightweighting. The
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Aluminum Maximum scenario always offers the deepest cumulative emission reductions.
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Figure 3. (a) Cumulative 2016-2050 changes in U.S. light-duty fleet life cycle GHG
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emissions by lightweighting scenario and bounding cases for four external factors; (b)
292
Annual U.S. light-duty fleet GHG emission changes 2016-2050 assuming no alternative
293
powertrain and fuel penetration beyond 2016; (c) Annual U.S. light-duty fleet GHG
294
emission changes 2016-2050 assuming the High EV Penetration case.
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3.2.1. Fuel consumption improvements
296
When vehicles are less efficient, lightweighting provides higher cumulative GHG emission
297
reductions, i.e., 3.4 Gt CO2 eq. reductions for Aluminum Maximum lightweighting when
298
assuming no fuel consumption improvements after 2016, compared to 2.7 Gt CO2 eq.
299
reductions with high fuel consumption improvements. Efficiency improvements (largely
300
driven by CAFE standards45) are expected to decrease the FRVs of lightweighting, and
301
vehicles will have less fuel consumption reduction for the same weight savings. However,
302
expected vehicle efficiency improvements lead to lower GHG emissions than in the ‘no
303
improvement’ case, despite diminishing the lightweighting GHG emission mitigation
304
potential.
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Figures 3b and 3c show the annual contribution to GHG emission reductions from
307
alternative powertrain penetration, fuel consumption improvements and Aluminum
308
Maximum lightweighting, for bounding assumptions regarding EV penetration levels. The
309
High EV Penetration case increases the overall efficiency of the light-duty vehicles and
310
therefore reduces the lightweighting GHG emission mitigation potential. Electric vehicles
311
possess lower FRV of lightweighting than conventional vehicles (Figure SI.22), which
312
reduces by 26% the cumulative GHG emission reductions from lightweighting in a high
313
EV scenario compared to no further penetration (from 3.1 to 2.3 Gt CO2 eq. over the
314
period 2016-2050 for Aluminum Maximum lightweighting). Overall, however, the High EV
315
Penetration case offers lower annual fleet GHG emissions, mostly after 2030.
316
Lightweighting can increase the vehicle production cost and may be prohibitive for more
317
costly alternative vehicles. However, we find that selectively lightweighting only
318
conventional or hybrid vehicles is nearly as effective at reducing GHG emissions as
319
complete lightweighting of all technologies. We assess the potential “rivalry” of
320
lightweighting and alternative vehicle penetration by developing an Adapted Aluminum
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Maximum scenario. This scenario is built from the Aluminum Maximum for conventional
322
vehicles (where lightweighting offers the greatest GHG emission reductions), intensive
323
lightweighting using aluminum for hybrid vehicles and no lightweighting for electric
324
vehicles (where lightweighting offers the lowest GHG emission reductions). The Adapted
325
Aluminum Maximum scenario achieves 97% of the complete Aluminum Maximum
326
scenario’s cumulative GHG reductions in the reference fleet stock case and 85% in the
327
High EV Penetration case (Figure SI.59). Nevertheless, lightweighting BEVs may have
328
additional benefits such as increasing vehicle range, which may in turn affect BEV
329
penetration.
330
3.2.3. Automotive material recovery
331
Gradually shifting toward full recycling of all automotive materials increases the
332
cumulative GHG emission reductions from lightweighting when aluminum is the primary
333
lightweighting material (from 2.9 to 3.2 Gt CO2 eq. in the default and closed loop scenarios
334
respectively for Aluminum Maximum). Although closing the loop reduces emissions in all
335
scenarios, it actually provides greater benefit to the baseline No Lightweighting scenario
336
than to the Steel Intensive scenario because of the lower overall steel weight in vehicles
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after substitution with HSS/AHSS and the equivalent primary and secondary production
338
emission factors of mild steel and HSS/AHSS. Modaresi et al.28 found that an automotive
339
material closed loop recycling scenario increases the GHG emission reductions from
340
lightweighting with Aluminum by 30%. Our modeling for the U.S. light-duty fleet suggests
341
that closing the loop of the automotive materials increases the GHG emission reductions
342
from lightweighting by 10% in the Aluminum Maximum scenario over the 2016-2050
343
period. The difference in findings is presumably largely a result of the different
344
geographical scopes of the two studies (i.e., U.S. and world) that provide distinct fleet
345
characteristics.
346
3.2.4. Oil prices
347
The GHG emission reductions of lightweighting the U.S. light-duty fleet in a low oil price
348
case are more important than in a high oil price case (3.3 compared to 2.5 Gt CO2 eq.
349
cumulative reductions over the period 2016-2050). When oil prices are high, the light-duty
350
fleet stock decreases, and manufacturers are urged to develop more efficient and/or
351
smaller vehicles. Conversely, low oil prices impede fuel consumption improvements or
352
the penetration of alternative vehicles and increase the fleet stock and sale shares of light
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trucks (Figure SI.30). From 2016 to 2050 in the U.S., the most important influence of oil
354
prices on the fleet GHG emissions are the size of the fleet stock and the share of light-
355
trucks (Figure SI.60). Oil prices substantially affect the prospective fleet GHG emissions
356
and a low oil price case results in higher fleet GHG emissions even with the increased
357
benefits of lightweighting.
358
3.3.
Pace and timing of U.S. light-duty fleet lightweighting
359
Faced with fuel consumption improvements and increasing penetration of alternative
360
powertrains, the GHG mitigation potential of lightweighting decreases over time. Delaying
361
the lightweighting implementation of the Aluminum Maximum scenario by 15 years (i.e.,
362
starting in 2030, less than halfway through the study period) reduces the 2016-2050
363
cumulative changes due to lightweighting by 72% in the default case (from -2.9 to -0.8 Gt
364
CO2 eq. in figure 4a). The results reflect the non-linearity of the fleet GHG emission
365
reductions, the decreasing assessment period of lightweighting (2030-2050 instead of
366
2016-2050), and the decreasing GHG emission mitigation potential of lightweighting per
367
Fleet kilometer traveled (Fleet KT) over time.
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We show the GHG emission mitigation potential of lightweighting per fleet kilometers
369
traveled for three lightweighting implementation-starting years (2016, 2023 or 2030) in
370
Figure 4b. The GHG emission changes due to lightweighting are calculated over a 20-
371
year period from each starting year. For example, the lightweighting implementation-
372
starting year 2023 has a gradual linear implementation of lightweighting from 2023 to
373
2038. The cumulative GHG emission changes from lightweighting are calculated from
374
2023 to 2043 and are divided by the cumulative light-duty fleet kilometers traveled from
375
2023 to 2043. Delaying by 15 years the lightweighting implementation decreases by 16%
376
the 20-year normalized lightweighting GHG emission mitigation potential (from -8.0 to -
377
6.7 g CO2 eq. per Fleet KT over 20 years for Aluminum Maximum scenario in default
378
case). The smaller GHG emission changes for later implementation years result from the
379
expected fuel consumption improvements in the near term and the alternative powertrain
380
penetration in the longer term. If high technological changes (i.e., high fuel consumption
381
improvements and High EV Penetration) occur, waiting until 2030 to start lightweighting
382
with the Aluminum Maximum scenario decreases the 20-year normalized GHG emission
383
reductions from lightweighting by 49%, (from -6.5 to -3.3 g CO2 eq. of cumulative GHG
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emission changes per Fleet KT over 20 years). In such a case, the Aluminum Intensive
385
scenario provides more GHG emission reductions than the Aluminum Maximum over 20
386
years.
387 388
Figure 4. (a) Cumulative U.S. light-duty fleet life cycle GHG emission changes (2016-
389
2050) for three lightweighting implementation starting years, 2016, 2023 and 2030; (b)
390
Cumulative U.S. light-duty fleet life cycle GHG emission changes from lightweighting over
391
a 20-year period normalized by fleet kilometers traveled (Fleet KT) for three lightweighting
392
starting years, 2016, 2023 and 2030. The high technological changes case assumes high
393
fuel consumption improvement and the High EV Penetration case. The no technological
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changes case assumes no fuel consumption improvement and no further penetration of
395
alternative powertrains after 2016.
396
Finally, faster rates of lightweighting (e.g., reducing the lightweighting implementation
397
period) increase the absolute GHG emission reductions and reduce the GHG emission
398
payback time associated with the lightweighting scenarios (5.0 years for a 2-year
399
implementation period compared to 6.8 years for a 20-year period in the Aluminum
400
Maximum scenario, Figure SI.62).
401
3.4.
Sensitivity analysis
402
A single-factor sensitivity analysis is conducted on key parameters that do not include
403
the scenario factors previously described (Figure SI.63). The GHG emission changes
404
from lightweighting are most sensitive to the substitution factors of the lightweight
405
materials, the FRVs, and secondary weight changes. The results have a low sensitivity
406
to electricity supply mix assumptions for electric vehicles because of the relatively small
407
penetration of BEVs and PHEVs and a more important sensitivity to electric supply mix
408
assumptions for aluminum production. Figure SI.64 shows that for a combination of high
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substitution factors (e.g., 0.99 and 0.65 kg of cast/wrought aluminum per kg of steel in the
410
body and chassis, respectively) and no secondary weight savings, the Aluminum
411
Maximum lightweighting may increase cumulative fleet GHG emissions by up to 1.9 Gt
412
CO2 eq. or 4% over the period 2016-2050 compared to a baseline scenario without
413
lightweighting. Conversely, for a combination of low substitution factors (e.g., 0.29 and
414
0.5 kg of cast/wrought aluminum per kg of steel in the body and chassis, respectively),
415
high secondary mass savings, and a closed loop automotive material flow, the Aluminum
416
Maximum lightweighting could save 7.3 Gt CO2 eq. or 14% of the 2016-2050 cumulative
417
fleet GHG emissions without lightweighting.
418
4. Discussion
419
4.1.
420
Fleet GHG emission reduction target in 2025: Lightweighting a stand-alone
measure?
421
In 2015, the United States submitted a Nationally Determined Contribution pledging to
422
reduce GHG emissions in 2025 to 26-28% below 2005 levels.46 Assuming equivalent
423
contributions of all economic sectors and the prospective fleet stock of the AEO 2018
424
reference case from 2015 to 2025, the light-duty fleet would require 227 Mt CO2 eq. of
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GHG reductions in 2025 compared to the baseline fleet GHG emissions. Lightweighting
426
the U.S. light-duty fleet would likely prevent an otherwise expected rise in baseline fleet
427
GHG emissions (by 40 MT CO2 eq. in 2025 over 2016) and further provide some fleet
428
emission reductions. Alone, the Aluminum Maximum lightweighting scenario would
429
achieve 28 Mt CO2 eq. of life cycle emission reductions in 2025 compared to a baseline
430
without technological changes. This value results from 54 Mt CO2 eq. of emissions
431
reductions in the transportation sector (i.e., accounting for upstream and tailpipe
432
emissions of fuels including imported fuels) offset by a 26 Mt CO2 eq. increase in sectors
433
associated with vehicle production including imported vehicles in the U.S. (e.g., in 2017,
434
43% of the new vehicles are produced outside the U.S.). Thus, lightweighting is not a
435
stand-alone measure to attain the emissions target pledged in 2015, amounting to only
436
12% of the target with a life cycle approach.
437
We considered two technological changes that would reduce the life cycle fleet GHG
438
emissions: fuel consumption improvements, and alternative vehicle and fuel penetration.
439
Using default values, these two measures, together with Aluminum Maximum
440
lightweighting, provide 149 Mt CO2 eq. of GHG emission reductions in 2025 in the
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transportation sector compared to the baseline without technological changes. However,
442
this also implies 24 Mt CO2 eq. of GHG emission increase in other industrial sectors.
443
These 124 Mt CO2 eq. of life cycle GHG emission reductions correspond to 55% of the
444
emissions target and therefore these measures are still not sufficient. Among our
445
simulations, only a high oil price case coupled with the three previous measures would
446
achieve the emissions target in 2025.
447
4.2.
Long term prospects of lightweighting
448
In the absence of fuel consumption improvements or alternative powertrain penetration,
449
lightweighting could reduce cumulative life-cycle emissions from 2016 to 2050 by 3.7, 2.7
450
or 1.5 Gt CO2 eq. (6.1%, 4.5% and 2.5%) in the Aluminum Maximum, Aluminum Intensive,
451
and Steel Intensive scenarios, respectively. For comparison, our default assumptions for
452
fuel consumption improvements alone, and alternative powertrain and fuel penetration
453
alone reduce cumulative emissions by 6.5 Gt CO2 eq. (11%), and 2.1 Gt CO2 eq. (3.4%)
454
respectively. The more aggressive electric vehicle penetration case provides larger
455
reductions (6.5 Gt CO2 eq. or 12%). However, the reductions due to alternative powertrain
456
penetration are not expected to be substantial before 2030, even in the more aggressive
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case. This means that while a high penetration of alternative powertrains drastically
458
decreases the fleet GHG emissions, conventional vehicles continue to play a major role
459
in the transportation sector in the near- to mid-term. During this period, lightweighting is
460
an effective strategy to decrease the fleet GHG emissions. In the longer term, other
461
lightweight materials, such as magnesium11 or carbon fiber-reinforced polymers47, could
462
provide higher substitution ratios and weight savings, but their wide-scale adoption is
463
currently limited because of their high energy intensities and costs.
464
We outline substantial interactions between fuel consumption improvements,
465
alternative powertrain penetration and lightweighting to reduce the fleet GHG emissions.
466
Estimating the GHG emission changes associated with specific measures depends on
467
the order in which the measures are modeled and implemented (Figure SI.65). No matter
468
the modeling or implementation order, all three options reduce the fleet GHG emissions
469
but their contributions vary considerably. From the best to the worst ordering, cumulative
470
GHG emission reduction potentials over the period 2016-2050 range from 2.8% to 3.4%
471
for alternative powertrain penetration, from 5.6% to 6.1% for Aluminum Maximum
472
lightweighting, and from 10% to 11% for fuel consumption improvements. This raises the
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important question of the most cost-effective way to reduce the fleet GHG emissions,
474
which is left for future work.
475
4.3.
Caveats and limitations
476
Some important model limitations include the lack of detailed consideration of vehicle
477
attributes such as acceleration time or engine power and of the interconnections between
478
lightweighting and vehicle attributes. For example, weight savings from lightweighting may
479
not be used solely for fuel savings but also to enhance the vehicle horsepower.48 In addition, we
480
did not consider economic costs in the lightweighting implementation. For example,
481
economic competition between lightweighting and electric vehicles is not thoroughly
482
assessed as lightweighting can also increase the range of electric vehicles and therefore
483
influence the penetration of alternative vehicles. A consumer choice model could be
484
embodied in the current modeling to study this effect. Finally, the fuel consumption
485
improvement measures implemented in the model are based on the AEO 201834
486
projections. As CAFE standards are still in place at the time of writing, manufacturers’ aim
487
to reach the CAFE standards for their fleet and fuel consumption improvements are
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expected. However, the exact set of measures that will be implemented is unknown and
489
we do not forecast the solutions to be implemented.
490
4.4.
Lightweighting: How and when?
491
The major contribution of this paper is the enhancement of fleet-based models to tackle
492
more complex and challenging questions related to the temporal deployment of
493
lightweighting from a GHG emissions perspective. We develop multiple lightweighting
494
scenarios for conventional and alternative vehicles, and consider the effects of
495
technological improvements on the fuel reductions from lightweighting.
496
We show that lightweighting using high-strength steel or aluminum is likely to provide
497
fleet GHG emission reductions. The choice of aluminum as the lightweighting material
498
could achieve deeper reductions than HSS with the same initial replacement rates. In
499
addition, a more aggressive lightweighting scenario would lead to larger GHG emission
500
reductions. We also determine that focusing lightweighting solely or primarily on
501
conventional vehicles is a satisfactory strategy in terms of GHG emission reductions.
502
Finally, we show that the timing of lightweighting matters. Our simulations always
503
suggest that the optimal effects of lightweighting are achieved when the adoption of
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504
lightweighted design occur as soon as possible. In an increasingly more efficient fleet,
505
equivalent material substitution and weight savings offer lower fuel use reductions.
506
Furthermore, lightweighting the light-duty fleet with aggressive adoption rates provide
507
more rapid and deeper GHG emission reductions.
508
Lightweighting U.S. light-duty vehicles is not a stand-alone measure to decrease the
509
fleet life cycle GHG emissions but is an effective option in the near-term that could provide
510
important savings while the fleet is dominated by conventional vehicles.
511 512
ASSOCIATED CONTENT
513
Supporting Information.
514
This paper contains a supporting information document. Sections 1-5 of the supporting
515
information document describes the full set of assumptions associated with our method.
516
Section 6 contains additional results and section 7 an additional discussion. In addition,
517
a GitHub repository is accessible free of charge that contains all inputs, codes and
518
numerical
519
(https://github.com/amilovanoff/est_milovanoff_et_al_2019).33
520
AUTHOR INFORMATION
521
Corresponding Author
results
associated
with
this
study
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*e-mail:
[email protected] 523
ACKNOWLEDGMENT
524
We thank the reviewers for their insightful comments, which improved greatly this
525
manuscript. This work was financially supported by Ford Motor Company through Project
526
Northern Star. While this article is believed to contain correct information, Ford Motor
527
Company (Ford) does not expressly or impliedly warrant, nor assume any responsibility,
528
for the accuracy, completeness, or usefulness of any information, apparatus, product, or
529
process disclosed, nor represent that its use would not infringe the rights of third parties.
530
Reference to any commercial product or process does not constitute its endorsement.
531
This article does not provide financial, safety, medical, consumer product, or public policy
532
advice or recommendation. Readers should independently replicate all experiments,
533
calculations, and results. The views and opinions expressed are of the authors and do
534
not necessarily reflect those of Ford. This disclaimer may not be removed, altered,
535
superseded or modified without prior Ford permission.
536
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