How the Parker Solar Probe Flew Into the Sun's Corona and Survived the Extreme Heat
Aishwarya Kapoor | Times Life Bureau | Jul 04, 2026, 07:53 IST
How the Parker Solar Probe Flew Into the Sun's Corona and Survived the Extreme Heat
Image credit : Times Life Bureau
The Parker Solar Probe has done what no spacecraft in history has: flown directly through the Sun's corona, the blazing outer atmosphere that runs hotter than the surface itself. It did not melt. The secret is a carbon shield, an orbit that never lingers, and physics that separates heat from temperature in ways that rewrite what we thought we knew about our star.
The corona is hotter than the surface, and nobody fully knows why
Eugene Parker, the astrophysicist who first predicted the existence of the solar wind in 1958, had a theory about what might be driving this. Magnetic waves and small explosive events called nanoflares, he argued, were dumping energy into the corona from below. NASA named a spacecraft after him in 2017, the first time a living scientist received that honour, and launched it on August 12, 2018, specifically to go find out.
A shield made of carbon foam, not metal
The geometry matters as much as the material. The spacecraft is designed so that the shield always faces the Sun. If it tilted even slightly off-angle, the instruments would be exposed and destroyed within seconds. Onboard sensors detect any drift and fire thrusters to correct it automatically, without waiting for a signal from Earth, at closest approach, a radio signal takes about eight minutes each way, far too slow for real-time correction.
Why the probe does not melt despite 2-million-degree plasma
Compare this to an oven and a pot of boiling water. Both can be at 100 degrees Celsius, but plunging your hand into the water causes a burn far faster than waving it briefly through oven air at the same temperature. Density determines how much energy actually transfers. The corona's density is so low that the probe's shield handles the thermal load without catastrophic failure.
What Parker found when it crossed the Alfvén surface
Inside that boundary, Parker detected structures called pseudostreamers: regions where the magnetic field folds back on itself. It also recorded sudden reversals in the magnetic field direction, called switchbacks, which had been spotted earlier in the mission from farther out but are far more frequent and intense close in. These switchbacks may be one of the mechanisms heating the corona, Parker's data is still being analysed to test that hypothesis.
The spacecraft also measured the solar wind at its source, before it has had millions of kilometres to mix and slow down. That data is changing models of how the wind accelerates and what it carries. India's Aditya-L1, launched by ISRO on September 2, 2023, is studying the Sun from the L1 Lagrange point about 1.5 million kilometres from Earth. It observes the solar wind and corona from a fixed vantage point. Parker goes inside. The two missions are asking the same questions from very different positions, and the answers from each sharpen the other.
Parker's closest planned perihelion brings it to within about 6.1 million kilometres of the Sun's surface, at speeds approaching 690,000 kilometres per hour, the fastest any human-made object has ever travelled. At that speed, it would cover the distance between Mumbai and Delhi in under half a second.
The coronal heating problem is not solved. But Parker has eliminated several explanations and strengthened others. The answer, when it comes, will have been measured from inside the thing being explained, which is a different kind of knowing than any telescope at a safe distance could provide.