Spaceflight Insider

SAGE III to provide highly accurate measurements of atmospheric gases

Technicians inside a clean room at NASA's Langley Research Center work on the SAGE III instrument, preparing it to ship to NASA's Kennedy Space Center for launch to the International Space Station. The ozone- and aerosol-measuring instrument is the latest in a long line of atmospheric science experiments designed at NASA Langley.

Technicians inside a clean room at NASA’s Langley Research Center work on the SAGE III instrument, preparing it to ship to NASA’s Kennedy Space Center for launch to the International Space Station. The ozone- and aerosol-measuring instrument is the latest in a long line of atmospheric science experiments designed at NASA Langley. Photo Credit: NASA/David C. Bowman

The International Space Station (ISS) will soon get a new tool to investigate the Earth’s upper atmosphere. This device will be capable of conducting highly accurate measurements of aerosols and gaseous constituents in the stratosphere and troposphere.

The Stratospheric Aerosol and Gas Experiment III (SAGE III) will study ozone, aerosols, water vapor, and other atmospheric gases to help provide a better understanding of the effects of natural and human-induced changes on the global environment.

SAGE III was initially planned to be launched to the ISS aboard SpaceXs Dragon cargo craft in November 2016 atop a Falcon 9 launcher. The mission, designated CRS-10, will launch from Cape Canaveral Air Force Station’s (CCAFS) Space Launch Complex 40.

However, it was postponed several times and is currently targeted to fly on Feb. 8, 2017, from Kennedy Space Center’s Launch Complex 39A. The delays were forced by the Sept. 1 explosion at SLC-40 when another Falcon 9 rocket was destroyed during a pre-launch static fire test.

SAGE III/ISS mission logo.

SAGE III/ISS mission logo. Image Credit: NASA

The SAGE III instrument was delivered from NASA’s Langley Research Center to NASA Kennedy Space Center (KSC) in November 2015.

“Final powered testing was completed at the KSC Space Station Processing Facility during the past year, and, in December 2016, the instrument payload and the Nadir Viewing Platform were handed over to SpaceX for installation into the Dragon Trunk of the Falcon 9 rocket. The integrated trunk is now awaiting launch,” Marilee M. Roell, SAGE III Science Manager at NASA’s Langley Research Center told SpaceFlight Insider.

Roell added that there is no more technical work that needs to be done except for a few remove-before-flight items. Although a couple of pre-launch reviews are still planned, all preliminary mission operations activities have been completed.

“The team is well rehearsed and we are ready to support the mission after launch,” Roell said.

After arrival at the ISS, SAGE III will be mounted externally on the station on the Expedite the Processing of Experiments to Space Station (ExPRESS) Pallet Adapter (ExPA) to the Express Logistic Carrier (ELC). The instrument will orbit between 239 and 257 miles (385 and 415 kilometers) above Earth’s surface at a 51.6-degree inclination with nearly a three-day repeat cycle. The station’s orbit is expected to help maximize the scientific value of SAGE III’s observations while proving that atmospheric science instruments do have a place on the orbiting laboratory.

To fulfill its scientific goals SAGE III is equipped with a total mass of about 1,162 pounds (527 kilograms) of tools. Its most important payload is considered to be the Sensor Assembly (SA) instrument—a grating spectrometer that measures ultraviolet and visible light and has a two-axis pointing system. SA contains the Charge Coupled Device (CCD) array detector that enhances measurement capability and may allow for new experimental data products like methane, bromine monoxide, and iodine monoxide, as well as measure larger aerosols.

SAGE III is also fitted with the Interface Adapter Module (IAM), the Disturbance Monitoring Package (DMP), the Hexapod Pointing System (Hexapod Electronics Unit and Hexapod Mechanical Assembly), and the Instrument Control Electronics box. IAM is perceived as the “brain” of the instrument payload, providing power and computing to the payload and acting as the interface between the instrument and the station. DMP is a miniature inertial measurement unit that will measure all of the small motions from the ISS, while the Hexapod Pointing System will act as the “legs” of the payload, which keep the instrument level in orbit.

The main scientific objective of the SAGE III mission will be obtaining high quality, global measurements of key components of Earth’s atmosphere. In particular, the instrument will assess the state of recovery in the distribution of ozone and will re-establish the aerosol measurements needed by both climate and ozone models. The mission is expected to gain further insight into key processes contributing to ozone and aerosol variability.

This graphic illustrates the components that make up the SAGE III Instrument Payload.

This graphic illustrates the components that make up the SAGE III Instrument Payload. Image Credit: NASA

“Our view from the space station will give us a new perspective of atmospheric composition. Data from SAGE III, coupled with model results, will allow scientists to monitor the health of the ozone layer and track the recovery of stratospheric ozone since ratification of the Montreal Protocol. By the 2020s—in most areas—models predict that ozone will have recovered about half of the amount lost from the pre-1980 levels. SAGE III will be valuable in assessing the performance of the Ozone Mapping and Profiler Suite flying on the Suomi National Polar-orbiting Partnership satellite,” Roell said.

Data from SAGE III should also help to re-institute aerosol measurements crucial for more accurate long-term climate and ozone models. Moreover, if there are any new changes to the ozone layer. This data could help the scientific community identify the cause and assess the impact of the changes.

Understanding the stratospheric ozone changes is considered crucial to determining whether the recovery of the ozone layer is progressing as expected since the Montreal Protocol was enacted.

“We expect to see some recovery, based on model data, in the amount of stratospheric ozone since the 1990s. We’ll also be looking to see if there are any new changes occurring in the stratosphere,” Roell noted.

The instrument that is set to be installed on the ISS is the second SAGE III sent into space. The first SAGE III was launched on the Russian Meteor-3M spacecraft in December 2001. SAGE is one of NASA Langley’s longest-running Earth science missions. The idea for the instrument, begun in the 1970s with the Stratospheric Aerosol Measurement (SAM) instrument, was developed and tested at Langley.

“SAM, as well as SAM II, SAGE, SAGE II, SAGE III Meteor-3M, and now SAGE III/ISS have all been led by Langley. This latest project also included the Nadir Viewing Platform to point SAGE in the right direction, as well as other new hardware and software, all of which was designed, built, integrated, and tested at Langley,” Roell said.

When SAGE III is on the ISS, it will be operated from the Flight Mission Support Center at Langley. Ball Aerospace & Technologies Corp. built the SAGE III/ISS instrument in Boulder, Colorado, and the European Space Agency and Thales Alenia Space provided a hexapod to keep the instrument pointing in the right direction as the ISS maneuvers in space.



Tomasz Nowakowski is the owner of Astro Watch, one of the premier astronomy and science-related blogs on the internet. Nowakowski reached out to SpaceFlight Insider in an effort to have the two space-related websites collaborate. Nowakowski's generous offer was gratefully received with the two organizations now working to better relay important developments as they pertain to space exploration.

Reader Comments

They need to establish a baseline on what is up there, so they can monitor how it changes once they start the climate modification using high altitude sulfur compound spraying to stop the global warming from getting out of control.
You don’t have to be a genius to realize that if we let the warming from carbon dioxide we have already added to the atmosphere continue, it will begin to release vast quantities of methane from thawing permafrost and from the ocean floor. Methane is eight times more efficient at trapping heat than carbon dioxide. A lot of methane released faster than it can decay risks starting a rapid period of warming which would transform the surface of much of the planet to desert. Melting ice will submerge nearly all coastal cities. It would destroy civilization and kill most of the population from starvation.
At a cost of $4 billion a year, we can prevent that. But only if we get started soon, before the methane tipping point is reached. What would you do?

As a mechanical engineer at ESA being involved in the HMA development I can only say that I am proud to see the SAGE III experiment is flying soon. I wish good luck operations team at LARc in conducting experiment and want to thank all the colleagues for their contributions.

Good luck SAGE III!

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