Lab Report

The Great Red Spot might be Jupiter’s most famous feature, but the giant planet would be unrecognizable without the multicolored bands streaking across its face.

The colors are there thanks to the chemistry of Jupiter’s atmosphere, but the striped pattern itself comes from long-lived winds called zonal flows that blow east-west around the planet in alternating directions. These zonal flows are similar to the jet streams high in Earth’s atmosphere.

Scientists have wondered for decades how deep these bands extend. Gravity measurements collected by NASA’a Juno mission during its close flybys discovered that these bands of flowing atmosphere penetrate into the planet, to a depth of about 1,900 miles deep — about 4 percent of Jupiter’s radius. Below that, the gases that make up Jupiter rotate as a single cohesive object.

LLNL physicist Jeffrey Parker and collaborator Navid Constantinou calculated how magnetic fields could prevent these zonal flows from forming deep within rotating spheres of fluid — like those on the gaseous giant Jupiter. In the past, simulations have shown that magnetic fields can discourage zonal flows, but Parker and Constantinou have now explained in detail the physical mechanisms of the effect. The study might help scientists better understand our largest planetary neighbor.

A novel instrument that has already proven its mettle on field campaigns will attempt to measure atmospheric greenhouse gases from an occultation-viewing, low-Earth-orbiting CubeSat mission called Mini-Carb early next year -- marking the first time this type of instrument has flown in space.

Emily Wilson, a scientist at NASA’s Goddard Space Flight Center, is teaming with Lawrence Livermore to fly a smaller, more ruggedized version of her patented mini-Laser Heterodyne Radiometer, or mini-LHR, on an LLNL-built CubeSat platform early next year.

Wilson has demonstrated the ground-based mini-LHR during several field campaigns in Alaska, the Amazon River Basin and the Royal Observatory in Edinburgh, Scotland, among other locations. Highly portable, the mini-LHR is comprised of commercially available components and literally can go anywhere to gather measurements.

About the size of a toaster, the flight version of her instrument will fly as the only payload on LLNL’s new, 11-pound 6U CubeSat bus known as the CNGB -- short for CubeSat Next Generation Bus. The CubeSat Office at the National Reconnaissance Office originated the CNGB concept, funding researchers at LLNL, the Naval Postgraduate School and the Space Dynamics Laboratory to develop a government-owned nano-satellite architecture that could support a broad range of missions. Mini-Carb is the first mission to do so.