RCS - Garrett Motion Inc - Are EVs the Effective Way to Decarbonize Europe?

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08/12/2023 09:30

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RNS Number : 1152W  Garrett Motion Inc  08 December 2023

Is the Automotive Industry's Transition to 100% Battery Electric Vehicles
(EVs) the Most Effective Way to Decarbonize European Transport?

Garrett Motion White Paper Tackles Key Question Regarding Vehicle CO2
Emissions

·      Vehicle lifecycle study (LCA) evaluates the years of use required
for battery electric vehicles (BEVs) and hybrids to off-set the significant
amount of C02 emissions generated during battery production.

·      Focused on Europe, the study considers various factors including
multiple electrified technology options, vehicle segments, average annual
vehicle use ranges, as well as the carbon-intensity of electricity generation
required for production, battery charging, among other factors.

·      Contrary to popular perceptions, results point at minimal to no
advantages for BEVs over hybrids in terms of CO2 emissions. Results challenge
the industry's focus on increasing vehicle range via larger and heavier
batteries. It suggests that: (a) aligning vehicle battery size with intended
daily use - versus for the occasional long trip - is ideal; and that (b) for
typical daily vehicle use, hybrids with low-capacity batteries outperform BEVs
in terms of minimizing emissions.

o  Mild hybrid (MHEV)

ROLLE, SWITZERLAND / ACCESSWIRE / December 8, 2023 / Garrett Motion Inc.
(NASDAQ:GTX), a differentiated technology provider for the automotive
industry, has published a white paper titled "Is the automotive industry's
transition to 100 percent electric vehicles the most effective way to
decarbonize European transport (https://pr.report/jNBqvUPM) ?"
(https://pr.report/jNBqvUPM) The study compares the CO2 emissions generated by
battery electric vehicles versus hybrid vehicles throughout their lifecycle,
including the manufacture and use of these vehicles.

The objective of this study is to evaluate the years of use required for a
battery electric vehicle to off-set the amount of CO2 generated during its
life cycle (manufacture and use) compared to different types of hybrid
vehicles. Most emissions are released during the battery manufacturing
process. The larger the battery capacity, the higher the CO2 emissions. Hybrid
or plug-in hybrid vehicles, by comparison, have batteries of smaller capacity.
Therefore, emissions related to their manufacture are lower than 100 percent
electric BEVs.

"We are all pursuing the same goal of reducing total vehicle emissions to
achieve Net Zero. Electrification is essential to reduce CO2 emissions. But,
as our study shows, for certain use cases some technologies can be less
polluting than 100 percent electric vehicles. It is therefore crucial for
consumers to be able to choose the electrified solution that best suits their
intended use. The 100 percent electric solution adopted only in Europe is by
far not the best option to reduce CO2 emissions," said Olivier Rabiller,
chairman and CEO of Garrett.

Garrett Motion's vehicle lifecycle study captures real-world CO2 emissions
data from the European car market, by type of vehicle and by use.

Garrett's analysis complements the findings of other LCA studies by evaluating
factors including a wide range of electrified technologies (100 percent
electric, mild hybrid, hybrid, plug-in hybrid), different vehicle segments
(compact, SUV, sports vehicle, and light commercial vehicle), the actual
average vehicle usage in Europe as well as the intensity of electric power
generation for production and battery charging.

Vehicle categories:

·      100% Hybrid (FHEV)

·      Plug-in hybrid (PHEV)

·      Battery electric vehicle (BEV)

Types of vehicles:

·      C-segment (compact sedan)

·      C-segment SUV

·      Sport Coupe

·      Light commercial vehicle

Types of use (mileage) of the vehicle per year:

·      High mileage - More than 20,000 km/year

·      Average mileage - 11,000 km/year or less

·      Low mileage - 8,000 km/year, 4,000 km/year or less (2,500 km/year
for sports cars)

Garrett Motion's vehicle lifecycle study shows that the actual use of a
vehicle is a determining factor in calculating its environmental impact.

Throughout its lifecycle (manufacture and use), the use of a vehicle,
regardless of its technology, is a determining factor when calculating its
real-world energy and environmental performance. Depending on the use, hybrid,
plug-in hybrid or electric technologies may emit more or fewer CO2. A few
examples :

·      In Europe, 60 percent of cars travel 11,300 km per year or less.
For this purpose, it will take at least 12 years for a popular C-segment sedan
to reach the equilibrium point of the total CO2 emissions of an electric
vehicle, compared to a plug-in hybrid vehicle. This means that for any
C-segment vehicle that travels less than these 11,300 km, the equilibrium
point favorable to the battery electric vehicle will be pushed back in time.
This duration lengthens for vehicles of greater weight, battery capacity and
increasing autonomy.

·      Plug-in hybrids are the least CO2-emitting choice compared to
battery electric vehicles:

o  For the C-segment sedan driver who drives 4000 km or less per year, about
20 percent of European drivers.

o  For the C-segment SUV driver who drives 8,000 km or less per year, about
35 percent of European drivers.

·      For the driver who drives at least 20,000 km per year (10 percent
of European drivers), the choice of 100-percent electric vehicle becomes
preferable after 5 years of use.

Aligning the battery size of an electrified technology with the intended daily
use, versus the occasional long trip, is ideal to avoid excess battery
capacity and unnecessary emissions. For typical daily vehicle use in Europe,
hybrids with low-capacity batteries outperform BEVs with oversized batteries
in terms of minimizing emissions.

Thus, most battery electric vehicles have no intrinsic advantage over other
electrified technologies in terms of total CO2 emissions over their lifetime.
In fact, ongoing efforts to increase the autonomy of BEVs without accounting
for C02 generated during production and for intended real-world uses can be
counterproductive to emission reduction goals.

Garrett's LCA study suggests that, to meet the challenge of CO2 reductions as
effectively as possible, battery electric vehicles and hybrid vehicles should
be used together, in a complementary way to meet a wide variety of daily uses.
Hence, the study concludes that the "100 percent BEV" mandates, such as the
one to be implemented in Europe by 2035, is not an optimal solution to reduce
the environmental impact of cars and commercial vehicles.

This study does not take into account key challenges beyond lifecycle CO2
emissions, such as the extraction of minerals needed to manufacture batteries
and the costs associated with vehicle electrification. Electrification costs
represent a major obstacle for widespread adoption and are mainly associated
with the size of the battery and the materials required (e.g., copper,
lithium, cobalt, graphite). Notably, cost reductions expected from mass
battery production yielding economies of scale remain small, as a result of
material price volatility and inflation triggered by growing demand.

Considering the contribution of batteries to the costs passed on to consumers,
the above is further evidence of the importance of optimizing battery sizes
according to the intended daily use, with hybrids and plug-in hybrids offering
cost-efficient alternatives in many cases.

Garrett's LCA methodology, additional insights

With this study, Garrett Motion intends to contribute to the conversation
around the LCA methodology as a tool to better-measure total emissions and to
encourage others to consider real-world criteria, such as vehicle usage, in
calculating the environmental impact of the various electrified technologies.

Vehicle lifecycle assessments are a complex, dynamic task that analyzes CO2
emissions beyond tailpipe or exhaust emissions. It generally accounts for
three lifecycle stages: (1) Manufacturing (e.g., mineral extraction,
production and transport of batteries and vehicles; (2) Vehicle use (e.g.,
electricity consumption based on the mix of energy production; fuel drilling,
refining, distribution and combustion emissions; and (3) Recycling
(dismantling, disposal, second life).

Battery electric vehicles generate the greatest amount of CO2 during the
production and recycling stage, while electrified hybrid vehicles generate
more CO2 during the use stage. Garrett's study analyzed the first two stages
of a vehicle's lifecycle, taking into account emissions related to the
production and use of the vehicle. The study does not consider in its
calculations the third stage of LCA, recycling and disposal of the vehicle,
due to its relatively low contribution to overall emissions, but also due to
the lack of pan-European data.

To read the white paper, visit Garrett Motion's Knowledge Center
(https://pr.report/l2S15kLC) . Translations of the white paper are available
in German, French and Italian by request.

About Garrett Motion Inc. - Garrett Motion is a differentiated technology
leader serving automotive customers worldwide for nearly 70 years. Known for
its global leadership in turbocharging, the company develops transformative
technologies for vehicles to become cleaner and more efficient. Its advanced
technologies help reduce emissions and reach zero emissions via passenger and
commercial vehicle applications - for on and off-highway use. Its portfolio
includes turbochargers, electric turbos (E-Turbo) and electric compressors
(E-Compressor) for both ICE and hybrid powertrains. In the zero-emissions
vehicle category, the company offers fuel cell compressors for hydrogen fuel
cell vehicles (FCEVs) as well as electric propulsion and thermal management
systems for battery electric vehicles (BEVs). Garrett boasts five R&D
centers, 13 manufacturing sites and a team of 9300 people located in more than
20 countries. Its mission is to empower the transportation industry to further
advance motion through unique, differentiated innovations. For more
information, please visit www.garrettmotion.com (https://pr.report/yFPMucXb) .

###

GLOBAL MEDIA CONTACT: Maria Eugenia Santiago Echandi; Director of Global
Public Relations;
maria.santiagoechandi@garrettmotion.com
(mailto:maria.santiagoechandi@garrettmotion.com) ; Cell. +1 734 386 6593

SOURCE: Garrett Motion

 

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