Amping Airpower—Electric Vertical Takeoff and Landing for the U.S. Air Force: Military Utility, Market Dynamics, and Warfighter Adoption

Table of Contents

• Amping Airpower Electric Vertical Takeoff and Landing for the U.S. Air Force 1
• About This Report 3
• RAND Project AIR FORCE 3
• Acknowledgments 3
• Summary 5
• Background 5
• Approach 5
• Key Findings 5
• Recommendations 6
• Contents 7
• Figures and Tables 9
• Figures 9
• Tables 10
• Introduction 11
• Research Approach 15
• Assessing Current and Future eVTOL Technology and Commercial Business Plans 15
• Modeling eVTOL Aircraft Military Utility to USAF Use Cases 16
• Evaluating USAF Influence on eVTOL Market 16
• Strategizing How the USAF Should Proceed with eVTOL 17
• Transition Mechanisms 17
• Strengths and Limitations of This Approach 17
• Organization of This Report 18
• 2022 Market Overview and Future Projections 20
• Surveying the eVTOL Market by Platform Design 21
• Surveying eVTOL Market by Investment Data 22
• Commercial Business Cases 23
• Passenger Movement 24
• Cargo Movement 24
• 2022 eVTOL Aircraft Capabilities and Limitations 24
• Other Factors for Commercial Success 28
• Infrastructure Requirements 28
• Safety Aircraft Certifications Air Traffic Control and Other Commercialization Factors 30
• Pilot Training 31
• Future eVTOL Capabilities 31
• Past Work 37
• Our Findings of Operational Community Perspectives on eVTOL Aircraft 37
• Surface Transport at the Nevada Test and Training Range 39
• Reducing Travel Times for Nevada Test and Training Range Operations with eVTOL Aircraft 40
• Commuting via eVTOL Could Improve Site Operator Quality of Life and Retention Rates but at High Cost 41
• Electric Infrastructure at USAF Sites in and Around the NTTR 41
• Missile Field Support Transportation 42
• New eVTOL-Enabled Concepts of Operation for Malmstrom AFB 45
• Electric Infrastructure for the eVTOL Enabled CONOP 46
• Quantitative Analysis of eVTOL Use by Roaming Security Teams 46
• Quantitative Analysis of On-Demand Movement of Maintenance Personnel to and from Silos 47
• Quantitative Analysis of eVTOL Use to Conduct Monthly Silo Inspections 48
• Agile Combat Employment 49
• General Considerations for eVTOL Charging in Agile Combat Employment 49
• Isolated eVTOL Infrastructure 50
• Notional ACE Scenarios We Modeled 51
• Major Command Support Today 54
• Initial Conclusions 55
• To What Extent Do USAF Technical and Supply Chain Requirements Overlap with Those of the Commercial Market 57
• Technical Specifications 58
• Secure Supply Chain 58
• Reliable Supply 58
• Summary of Overlap Between the USAF and the Commercial Market 59
• What Is the Proportion of USAF Demand Relative to the Commercial Market 60
• Commercial Versus Military Demand Forecasts 61
• Implications of Low Market Share for the USAF 63
• Where Will eVTOL Supply Chains Be Located 64
• Pros and Cons of Domestic Production 65
• Using the Automotive Industry as a Proxy for eVTOL Aircraft 66
• Geography of Technology Integration and Final Assembly 67
• Geography of Material and Component Supply Chains 68
• Implications of Supply Chain Geography 71
• A Strategic Approach to Future USAF Engagement with eVTOL Technology 73
• A Strategic Framework for Commercial Technology Opportunities 73
• Scenario A High Military Value Low Market Sensitivity to Military Investment 76
• Scenario B High Military Value High Market Sensitivity to Military Investment 77
• Scenario C Low Military Value High Market Sensitivity to Military Investment 77
• Scenario D Low Military Value Low Market Sensitivity to Military Investment 78
• How Does eVTOL Technology Rate on the Military Value Scale for the USAF 78
• Will eVTOL Transform Military Operations in the Future 80
• How Does the eVTOL Market Rate on the Sensitivity Scale 82
• How Does the eVTOL Market Compare with the sUAS Market 83
• Implications for Agility Prime 85
• The Prime Model Is Not a Good Fit for the Commercial eVTOL Market but Shows Promise for Other Commercial Technology Opportunities 86
• Options to Transition eVTOL Technology to the Warfighter 89
• Options to Transition Emerging Commercial Technologies to the Warfighter 90
• Transition Routes by Sponsoring Organization 92
• Barriers to Transitioning Emerging Commercial Technologies 94
• Noteworthy Transition Mechanisms 95
• Feasible Transition Routes for eVTOL Technology 96
• Begin with Sponsor Capability Entry A 96
• Begin with Small-Scale Purchase Entry B 96
• Begin with Prototyping or Experimentation Entry C or D 97
• Applying Experimentation and Prototyping Lessons to eVTOL Technology 97
• Implementing a Survey-the-Market Approach 99
• Improving DoD Acquisition Processes for Commercial Technology 101
• Transition Conclusions 101
• Findings and Recommendations 103
• Major Findings 103
• Utility of eVTOL Technology for USAF Is Unclear 104
• USAF May Have Difficulties Acquiring eVTOL Aircraft with Defense- Specific Requirements 106
• A Survey-the-Market Approach Is Most Appropriate for eVTOL 107
• Recommendations 107
• Recommendations for Agility Prime Engagement with Other Military and Government Entities 110
• General Emerging Technology Recommendations to the USAF 111
• Conclusion 112
• Previous USAF Analysis of eVTOL Utility 113
• Innovative Capability Opening 113
• Multi-Attribute Tradespace Exploration 114
• USAF Fellows Report 114
• Stakeholder Input 116
• Operational Community Perspectives 117
• Other Platform Cost and Capability Assumptions 122
• Electric Infrastructure Cost Data 126
• Use Case Assessment 128
• Calculating eVTOL Aircraft Utility 128
• Identify Vehicle Travel Routes 128
• Calculating Distance and Travel Times 129
• Use Cases 130
• Nevada Test and Training Range 131
• Missile Field Support 133
• Agile Combat Employment 136
• Emerging Technology Case Studies 141
• Palletized Munitions 141
• Robotic Combat Vehicles 142
• MQ-1 Predator 143
• Blue sUAS 144
• Falcon 9 Spacelift 146
• Case Alignment with Routes to Transition Emerging Commercial Technologies to the Warfighter 148
• Transition Mechanisms 149
• Abbreviations 151
• References 154