The Space Launch System Rocket of the National Aeronautics and Space Administration, the Largest Rocket Ever Produced, the Size of the Rocket Fuel Storage Facility for the Space Launch System Rocket, the Type of Welding Used for the Space Launch System Rocket Fuel Containers, the Reason Liquid Rocket Fuel Replaced Solid Rocket Fuel, Oxygen Imported into Space to Allow a Rocket to Achieve Thrust, American Physicist Robert Goddard’s Liquid Kerosine and Liquid Oxygen Rocket Fuel, the Reaction of Kerosine and Oxygen, the First Liquid Fueled Rocket Launch, the Result of This Launch, the Reason Goddard’s Liquid Fuelled Rocket Could Not Surpass 3 Kilometers in Altitude, Russian Rocket Scientist Konstantin Tsiolkovsky’s Rocket Equation and the Implications of This, the Fuel Required to Reach Space, Scientists Unable to Circumvent the Tsiolkovsky Formula, the Equation Which Explains the Limitation of Space Travel, the Majority of a Rocket Being Fuel in Place of Payload, the Largest Rocket Prior to the Space Launch System Rocket, the Method Used to Try and Bypass the Limitations of the Tsiolkovsky Formula, the Advent of Rockets Having Multiple Stages, the Only Fuel Which Can Deliver Astronauts to the Moon, Tsiolkovsky Calculating if Kerosine Could Allow a Rocket to Reach the Moon, the Reason Hydrogen Fuel is More Energy Dense Than Alternative Fuel Sources, the Reaction of Hydrogen and Oxygen, the RS25 Rocket Engine, the RS25 Engine Being Repurposed to Power the Space Launch System Rocket, the Capabilities of the Reformatted RS25 Rocket Engine, the Difficulty of Landing a Rocket for Reuse, the First Reusable Rocket’s Developed During the 1970’s, the Original Goal of the Space Shuttle Rocket, the Cost of Each Space Shuttle Rocket Launch, the Next Generation of Reusable Rocketry Developed During the 1990’s, the Advent of the Delta Clipper Experimental Rocket, the Location of the Delta Clipper Experimental Rocket Test Flights, the Delta Clipper Experimental Rocket Providing Proof of Concept of a Reusable Rocket, the Destruction of the Delta Clipper Experimental Rocket During a Test Flight Leading to the Cancellation of the Program, Astronauts Losing Voice Communication With Ground Control During Reentry, the Cancellation of the Space Shuttle Rocket Program, the 2003 Columbia Disaster Leading to Outsourcing of Rocket Technology Toward Private Industry, the Difficulty of Creating a Reusable Rocket, the Process Required to Land and Reuse a Rocket, the Method Used to Determine What American Aerospace Corporation Blue Origin Did in 2000, the Time Required to Design, Build, and Test the First Fully Reusable Rocket, Blue Origin’s New Shepard Rocket Successfully Launching and Returning for Reuse, American Aerospace Corporation SpaceX’s Falcon 9 Rocket Successfully Launching and Returning for Reuse, New Zealand Aerospace Corporation Rocket Lab Dramatically Reducing the Cost of Rocket Manufacturing, the Reason Rocket Lab Has Been Able to Dramatically Reduce the Cost of Rocket Production, the Reason Small Satellites are Becoming Easier and More Cost Effective to Launch, the Extremely Light Weight Carbon Composite Rocket, Canadian Aerospace Corporation Vector Aerospace Creating a Rocket Which Can be Launched Virtually Anywhere, How Vector Aerospace Experiments to Reduce Rocket Launch Costs, Vector Aerospace Pioneering Concepts like Liquid Oxygen and Propylene Instead of Traditional Fuel Resources, the Thrust Capability of Propylene, American Engineer John Garvey’s View of Vector Aerospace, American Space Tourism Corporation Virgin Galactic Designing the Virgin Orbit Rocket to Reduce Rocket Costs for Space Tourism, and How Virgin Galactic Rockets are Designed to Operate and Reach Orbit