Research Support Building

Research Support Building

Research Support Building

Research Support Building

Research Support Building

Research Support Building

Research Support Building

Research Support Building

Research Support Building

Research Support Building

Research Support Building

Research Support Building

Research Support Building

Research Support Building

Research Support Building

Research Support Building

Research Support Building

Research Support Building

Research Support Building

Research Support Building

Research Support Building

Research Support Building

Research Support Building

Research Support Building

Research Support Building

Research Support Building

Research Support Building

Research Support Building

Research Support Building

Research Support Building

Research Support Building

Research Support Building

Research Support Building

Research Support Building

Research Support Building

Research Support Building

Research Support Building

Research Support Building

Research Support Building

Research Support Building

Research Support Building

Research Support Building

Research Support Building

Research Support Building

Research Support Building

Research Support Building

Research Support Building

Research Support Building

Research Support Building

Research Support Building

Research Support Building

Research Support Building

Research Support Building

Research Support Building

Research Support Building

Research Support Building

Research Support Building

Research Support Building

Research Support Building

Research Support Building

Research Support Building

Research Support Building

Research Support Building

Research Support Building

Research Support Building

Research Support Building

Research Support Building

Research Support Building

Research Support Building

Research Support Building

Research Support Building

Research Support Building

Research Support Building

Research Support Building

Research Support Building

Research Support Building

Research Support Building

Research Support Building

Research Support Building

Research Support Building

Research Support Building

Research Support Building

Research Support Building

Research Support Building

Research Support Building

Research Support Building

Research Support Building

Research Support Building

Research Support Building

Research Support Building

Research Support Building

Research Support Building

Research Support Building, COMPASS Laboratory

Research Support Building, COMPASS Laboratory

Srujana Neelam, a researcher working at NASA’s Kennedy Space Center in Florida, programs the SciSpinner Microgravity Simulator in the Microgravity Simulation Support Facility (MSSF) inside the Neil Armstrong Operations and Checkout building on Feb. 11, 2020. The facility was developed to provide ground simulation capability to the U.S. research community in order to supplement the limited opportunities to access the International Space Station and other platforms for microgravity research. The MSSF is designed to support biological research on microorganisms, cells, tissues, small plants and small animals. The simulator provides NASA with an alternative platform for microgravity research and creates the opportunity to conduct experiments on the space station in parallel with conditions of simulated microgravity on the ground.

Ye Zhang, a project scientist at NASA’s Kennedy Space Center in Florida runs a test on a Gravite 3d clinostat device in the Microgravity Simulation Support Facility (MSSF) inside the Neil Armstrong Operations and Checkout building on Feb. 11, 2020. The facility was developed to provide ground simulation capability to the U.S. research community in order to supplement the limited opportunities to access the International Space Station and other platforms for microgravity research. The MSSF is designed to support biological research on microorganisms, cells, tissues, small plants and small animals. The simulator provides NASA with an alternative platform for microgravity research and creates the opportunity to conduct experiments on the space station in parallel with conditions of simulated microgravity on the ground.

A Gravite 3d clinostat is in the Microgravity Simulation Support Facility (MSSF) inside the Neil Armstrong Operations and Checkout building at NASA’s Kennedy Space Center in Florida on Feb. 11, 2020. The facility was developed to provide ground simulation capability to the U.S. research community in order to supplement the limited opportunities to access the International Space Station and other platforms for microgravity research. The MSSF is designed to support biological research on microorganisms, cells, tissues, small plants and small animals. The simulator provides NASA with an alternative platform for microgravity research and creates the opportunity to conduct experiments on the space station in parallel with conditions of simulated microgravity on the ground.

Ye Zhang, a project scientist at NASA’s Kennedy Space Center in Florida, makes adjustments to a Gravite 3d clinostat in the Microgravity Simulation Support Facility (MSSF) inside the Neil Armstrong Operations and Checkout building at on Feb. 11, 2020. The facility was developed to provide ground simulation capability to the U.S. research community in order to supplement the limited opportunities to access the International Space Station and other platforms for microgravity research. The MSSF is designed to support biological research on microorganisms, cells, tissues, small plants and small animals. The simulator provides NASA with an alternative platform for microgravity research and creates the opportunity to conduct experiments on the space station in parallel with conditions of simulated microgravity on the ground.

A Gravite 3d clinostat undergoes a test in the Microgravity Simulation Support Facility (MSSF) inside the Neil Armstrong Operations and Checkout building at NASA’s Kennedy Space Center in Florida on Feb. 11, 2020. The facility was developed to provide ground simulation capability to the U.S. research community in order to supplement the limited opportunities to access the International Space Station and other platforms for microgravity research. The MSSF is designed to support biological research on microorganisms, cells, tissues, small plants and small animals. The simulator provides NASA with an alternative platform for microgravity research and creates the opportunity to conduct experiments on the space station in parallel with conditions of simulated microgravity on the ground.

Some experiments are being prepared for a test in the Airbus Random Positioning Machine in the Microgravity Simulation Support Facility (MSSF) inside the Neil Armstrong Operations and Checkout building at NASA’s Kennedy Space Center in Florida on Feb. 11, 2020. The facility device was developed to provide ground simulation capability to the U.S. research community in order to supplement the limited opportunities to access the International Space Station and other platforms for microgravity research. The MSSF is designed to support biological research on microorganisms, cells, tissues, small plants and small animals. The simulator provides NASA with an alternative platform for microgravity research and creates the opportunity to conduct experiments on the space station in parallel with conditions of simulated microgravity on the ground.