Assessment of CO2 Emissions Life Cycle in the Fuel Cell Electric Truck Sector, United States, 2024 2040

Assessment of CO2 Emissions Life Cycle in the Fuel Cell Electric Truck Sector, United States, 2024 2040

Adoption of Clean Hydrogen Production Sources Will Drive Transformational Growth in Sustainable Transportation Due to Reductions in CO2 Emissions by 43% Per FCET

RELEASE DATE
09-Sep-2024
REGION
Global
Deliverable Type
Market Research
Research Code: PFI2-01-00-00-00
SKU: AU_2024_1006
AvailableYesPDF Download
$4,950.00
In stock
SKU
AU_2024_1006

Assessment of CO2 Emissions Life Cycle in the Fuel Cell Electric Truck Sector, United States, 2024 2040
Published on: 09-Sep-2024 | SKU: AU_2024_1006

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In this study, Frost & Sullivan offers a comprehensive exploration of the carbon dioxide (CO2) trail of a fuel cell electric truck (FCET) by investigating the carbon emission implications of FCETs, particularly with focus on hydrogen as a prospective fuel for the trucking industry in the United States. Our analysis begins with the rationale for considering hydrogen, highlighting its potential to mitigate life cycle emissions as compared to conventional fuels.

We delve into various hydrogen production methods, ranging from grey hydrogen to renewable sources, each carrying distinct carbon footprints. Emphasis falls on the CO2 emissions associated with manufacturing fuel cell vehicles, pinpointing significant contributions from components including fuel cell stacks and hydrogen storage tanks. Furthermore, we project total CO2 emissions throughout the operation of a truck, drawing comparative insights with its battery electric and diesel truck counterparts.

Ultimately, this study underscores the urgency of transitioning to cleaner hydrogen production methods and optimizing vehicle manufacturing to achieve substantial CO2 emission reductions in the trucking sector.

The study period is 2023 to 2030.

Author: Christus Divyan

Why is it Increasingly Difficult to Grow?

The Strategic Imperative 8™

The Impact of the Top Three Strategic Imperatives on the CO2 Emissions of Fuel Cell Electric Truck (FCET) Industry

Hydrogen is the Fuel of the Future

Life Cycle CO2 Flow of a Fuel Cell Electric Truck

Different Methods of Producing Hydrogen

Research Scope

Powertrain Technology Segmentation

Growth Drivers

Growth Restraints

Analysis of Major Hydrogen Production Methods

Analysis of Major Hydrogen Production Methods (continued)

Analysis of Major Hydrogen Production Methods (continued)

Key Factors Impacting Adoption of H2 Production Methods

Factor 1: Lower CO2 Emissions & Readiness Levels

Factor 2: Clean Hydrogen Programs and Targets

Factor 3: States’ H2 Production Potential & Plan

Adoption Forecast of H2 Production in California

Adoption Forecast of H2 Production in the Southwest

Adoption Forecast of H2 Production in Texas

CO2 Emission Trail from H2 Production

Major Components of a Fuel Cell Electric Truck

Fuel Cell Stack

Hydrogen Storage Tanks

Battery

CO2 Emission Trail: Manufacture of an FCET

LDT Use Case Characteristics and Forecast Assumptions

LDT Cycle A & H—H2 Consumption and CO2 Emissions

LDT Cycle A to H—kgCO2 Per Mile

MDT Use Case Characteristics and Forecast Assumptions

MDT Cycle A & H—H2 Consumption and CO2 Emissions

MDT Cycle A to H — kgCO2 per Mile

HDT Use Case Characteristics and Forecast Assumptions

HDT—Cycle A

HDT—Cycle H

HDT Cycle A to H—kgCO2 Per Mile

LDT: ICE, BEV, and FCEV Comparison (Cycle A & H)

MDT: ICE, BEV, and FCEV Comparison (Cycle A & H)

HDT: ICE, BEV, and FCEV Comparison (Cycle A & H)

Top 3 Takeaways

Growth Opportunity 1: CO2 Emissions Tracking

Growth Opportunity 1: CO2 Emissions Tracking (continued)

Growth Opportunity 2: Geographic-specific Vertical Integration for Battery and Fuel Cell Manufacture

Growth Opportunity 2: Geographic-specific Vertical Integration for Battery and Fuel Cell Manufacture (continued)

Growth Opportunity 3: Hydrogen Infrastructure Expansion

Growth Opportunity 3: Hydrogen Infrastructure Expansion (continued)

Best Practices Recognition

Frost Radar

Benefits and Impacts of Growth Opportunities

Next Steps

List of Exhibits

List of Exhibits (continued)

Legal Disclaimer

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Impacting your company's future growth potential.

In this study, Frost & Sullivan offers a comprehensive exploration of the carbon dioxide (CO2) trail of a fuel cell electric truck (FCET) by investigating the carbon emission implications of FCETs, particularly with focus on hydrogen as a prospective fuel for the trucking industry in the United States. Our analysis begins with the rationale for considering hydrogen, highlighting its potential to mitigate life cycle emissions as compared to conventional fuels. We delve into various hydrogen production methods, ranging from grey hydrogen to renewable sources, each carrying distinct carbon footprints. Emphasis falls on the CO2 emissions associated with manufacturing fuel cell vehicles, pinpointing significant contributions from components including fuel cell stacks and hydrogen storage tanks. Furthermore, we project total CO2 emissions throughout the operation of a truck, drawing comparative insights with its battery electric and diesel truck counterparts. Ultimately, this study underscores the urgency of transitioning to cleaner hydrogen production methods and optimizing vehicle manufacturing to achieve substantial CO2 emission reductions in the trucking sector. The study period is 2023 to 2030. Author: Christus Divyan
More Information
Deliverable Type Market Research
Author Christus Divyan
Industries Automotive
No Index No
Is Prebook No
Podcast No
Predecessor PECC-01-00-00-00
WIP Number PFI2-01-00-00-00