This is why Neptune and Uranus are different shades of blue

By Danny Halpin via SWNS

The secret behind what gives ice planets Neptune and Uranus their distinctive blue hues has been discovered by Oxford University scientists.

Neptune is a deeper blue than Uranus because it has a thinner layer of haze, scientists have found.

Like looking at distant hills on a summer evening when dust, smoke and other dry particles cast blue shadows over the landscape, the haze of these distant ice giants forms an atmospheric curtain which gives the two planets their distinctive blue colour.

While they share many similarities in mass, size and atmospheric compositions, Neptune has a noticeably deeper shade of blue than its planetary neighbor.

New research led by Professor Patrick Irwin suggests that differences in the layers of haze are responsible and that if there were no haze in the atmospheres of either planet, they would both appear equally blue.

Using observations from the Hubble Space Telescope, the NASA Infrared Telescope Facility and the Gemini North Telescope, an international team of researchers has developed a model to understand the aerosol layers in the atmospheres of Neptune and Uranus.

Professor Irwin, lead author of the study published in the Journal of Geophysical Research: Planets, said: “This is the first model to simultaneously fit observations of reflected sunlight from ultraviolet to near-infrared wavelengths.

“It’s also the first to explain the difference in visible colour between Uranus and Neptune.”

The team modelled three haze layers at different heights in the atmospheres of each planet.

The middle layer of haze particles was found to be thicker on Uranus than on Neptune and it is this layer which is key to the colour difference.

On both planets, methane ice condenses on the particles in this middle layer and it forms a shower of methane snow that pulls haze particles deeper into the atmosphere.

Here, these haze particles cause condensation of hydrogen sulphide ice which forms a separate, deeper layer of cloudy haze.

Because Neptune has a more active, turbulent atmosphere than Uranus, it is better at churning up the methane gas, causing it to condense, produce snow and pull those middle-layer haze particles deeper into the atmosphere.

This means the middle layer is thinner on Neptune than on Uranus and it, therefore, appears bluer.

In contrast, the excess haze on Uranus builds up in the planet’s stagnant, sluggish atmosphere, giving it a lighter, paler tone.

The team’s research also showed the presence of a second, deeper layer in the model that, when darkened, could account for dark spots occasionally visible on Neptune and more sporadically on Uranus, such as the famous Great Dark Spot (GDS-89) on Neptune observed by Voyager 2 in 1989.

While astronomers were already aware of the presence of dark spots in the atmospheres of both planets, they didn’t know which haze layer was causing them or whether they were caused by a thinning or darkening of a layer.

Dr Mike Wong, an astronomer and team member from the University of California, said: “We hoped that developing this model would help us understand clouds and hazes in the ice giant atmospheres.

“Explaining the difference in colour between Uranus and Neptune was an unexpected bonus.”