Deep within Neptune and Uranus, it rains diamonds
Deep inside the planet Neptune and Uranus, the pressure is so extreme that carbon atoms are crushed into actual diamonds, which then rain downward in solid showers through the planet's interior, and recent laboratory experiments have successfully recreated the conditions in which this happens, producing tiny synthetic diamonds in the process. The interiors of the two ice giants of the outer solar system, Uranus, at about 2.9 billion km's from the Sun, and Neptune, at about 4.5 billion, are difficult to study by any direct means. Astronomers and physicists have suspected for nearly 40 years about raining of diamonds. The outer planets of our Solar System are hard to study, however. Only a single space mission, Voyager 2, has flown by to reveal some of their secrets, so diamond rain has remained only a hypothesis. Beyond the lingering mystery of the diamond rain, there’s a big loss in our failure to study Uranus and Neptune inside and out. It limits our understanding of the Solar System and the galaxy, because planets of this size have turned out to be extremely common in the Milky Way. The number of planets similar in size to Uranus and Neptune which have been found in the galaxy is roughly nine times greater than the number of much larger planets similar in size to Jupiter and Saturn. The outermost planets also seem to bear scars which could tell us a lot about the formation of our own Solar System. So there’s a growing sense of urgency to explore Neptune and Uranus, both to better understand where and how planetary systems form and also to refine our ideas about where to look for planets which can sustain life.
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The interiors of the two ice giants of the outer solar system, Uranus and Neptune, are difficult to study. The only spacecraft ever to visit either planet was Voyager 2, which flew past Uranus in January 1986 and Neptune in August 1989, observed both worlds for a few hours each, and continued on into interstellar space. No probe has entered either planet’s atmosphere, and none is planned within this decade. What scientists know about the interiors of Neptune and Uranus comes almost entirely from theoretical models, indirect observations of magnetic fields and gravitational moments, and laboratory experiments designed to recreate the extreme pressures and temperatures believed to exist at depth. Although we’ve been limited by spacecraft and ground-based telescopes regarding how much we can learn about the exteriors of Uranus and Neptune, advances in laboratory simulations are enabling remarkable new insights about what’s happening in their interiors, including what gives rise to diamond rain. Discoveries such as these reveal the complexity of the chemical processes involved in the evolution of these planets. Our simulations give clues to the internal nature of worlds far beyond the Solar System, even worlds which we may never see directly from the outside.
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One of the more striking predictions of these models is that, somewhere between 5,000 and 10,000 km's below the planets’ visible cloud tops, the atmospheric pressure becomes so extreme that the methane molecules abundant in the atmosphere are torn apart. The methane (CH₄) decomposes into its constituent carbon and hydrogen atoms; the carbon atoms then arrange themselves into the diamond crystal lattice and crystallise out as solid diamond particles. The particles, being denser than the surrounding fluid, sink toward the planetary core under the pull of gravity. According to the 2017 SLAC National Accelerator Laboratory announcement of the first direct laboratory observation of this process, the phenomenon has been theorised for nearly four decades but had never been directly observed in any experimental setup. Neptune and Uranus are called the “ice giants“ of our Solar System because their outer two layers consist of compounds which include hydrogen and helium. In astronomy slang, ice refers to all compounds of light elements which contain hydrogen, so the planets’ water (H2O), ammonia (NH3) and methane (CH4) make them “icy.” The beautiful bluish hue of both planets is the result of methane traces in their atmospheres.
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The 2017 results have been refined in subsequent experiments. According to a 2017 Eos article published by the American Geophysical Union, the simulated conditions corresponded to a depth of approximately 10,000 km's below Neptune’s surface, and produced nanodiamonds of unambiguous crystalline structure within the femtosecond observation window. Subsequent experiments at SLAC in 2020 and 2022 used variations of the technique, including replacing the polystyrene with plastics containing oxygen (more closely approximating the actual chemical mixture inside Neptune, which includes water and ammonia along with methane), and confirmed that the diamond formation persisted under these more realistic conditions. The most recent refinement, published in Nature Astronomy in January 2024, contained a notable surprise. According to a SLAC announcement accompanying the 2024 paper, the diamond rain forms at substantially lower pressures and temperatures than the earlier experiments had suggested. The implication is that diamond formation occurs over a much larger region of Neptune’s and Uranus’s interiors than had been previously assumed, extending from much shallower depths than the originally calculated ~10,000 km's. The 2024 paper also linked the diamond rain to the unusual magnetic fields of Neptune and Uranus, which differ from those of Earth and Jupiter in being substantially offset from the planets’ rotational axes, possibly because the diamond rain disrupts the convective flows in the planets’ fluid interiors in ways which distort the magnetic field geometry.
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However, it is the “ice” in the deep middle layers which really shapes their properties. On Neptune, for example, beneath a hydrogen-helium atmosphere there is 3,000 km's thick lies an ice layer that is 17,500 km's thick. Simulations suggest that gravity compresses the “ices” in this middle layer to high densities, and the internal heat raises the internal temperatures to several thousand kelvins. Despite the high temperature, pressures more than one million times greater than the atmospheric pressure on Earth compress the so-called ices into a hot, dense fluid. Under such heat and pressures, ammonia and methane are chemically reactive. Scientists have modeled exotic processes, including diamond formation, taking place between the compounds deep within the ice layers. Marvin Ross of Lawrence Livermore National Laboratory first introduced the diamond-rain idea in a 1981 article in Nature titled, “The Ice Layer of Uranus and Neptune, Diamonds in the Sky?” He suggested that the carbon and hydrogen atoms of hydrocarbons such as methane separate at the high pressures and high temperatures inside the ice giant planets. Clusters of isolated carbon atoms would then be squeezed into a diamond structure, which is the most stable form of carbon under such conditions.
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The technical challenge of recreating Neptune’s deep interior is substantial. The pressures involved are on the order of 1.5 to 3 million times Earth’s atmospheric pressure. The temperatures are several thousand kelvin. Sustaining these conditions in any kind of bulk sample is impossible with current technology available, no container could survive the pressures, and no heating system could maintain the temperatures without destroying everything around it. The trick the SLAC team developed is to recreate the conditions for only an extremely brief instant, just long enough for a single chemical reaction to occur and be observed. The technique works as follows. According to a Lawrence Livermore National Laboratory technical summary of the experiment, a thin sample of polystyrene plastic, a substance whose chemical composition (carbon and hydrogen in long molecular chains) approximates that of the hydrocarbon compounds in Neptune’s atmosphere, is placed in a target chamber at SLAC’s Matter in Extreme Conditions instrument. The sample is then struck simultaneously by two pulses of an extremely high-powered optical laser, which together create two compression shock waves which travel through the plastic. The shock waves briefly compress the sample to roughly Neptune-deep-interior conditions of 1.5 to 2 million atmospheres of pressure and 5,000 to 6,000 K of temperature, sustaining these conditions for a few quadrillionths of a second.
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During this femtosecond-long window, the SLAC team uses X-ray diffraction or X-ray scattering, fired through the same sample by the laboratory’s Linac Coherent Light Source X-ray free-electron laser, to monitor in real time what is happening to the carbon and hydrogen atoms inside the plastic. The diffraction patterns produced by the X-rays reveal the atomic arrangement of any crystalline material present. When the SLAC team performed the experiment in 2017, the X-ray diffraction patterns showed unambiguous evidence of diamond, the carbon atoms had separated from the hydrogen, organised themselves into the characteristic cubic crystal structure of diamond, and condensed into nanometre-sized crystalline grains, all in the brief moment of peak shock pressure. Diamond is denser than the methane, ammonia and water left in the ice layer, so the carbon crystal would start to sink toward the planet’s core. It would accumulate new layers as it falls when it touches other isolated carbon atoms or diamonds, allowing individual diamond blocks to reach a size meters in diameter. We think that, as a result, a thick layer of carbon surrounds the rocky cores of Uranus and Neptune. This carbon layer may consist of blocks of solid diamond, or, if the temperature is extremely high (as some planet models suggest), it might transform into liquid carbon, or a mix of solid carbon and liquid carbon.
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If the layer is a mix of solid and liquid carbon, the solid carbon would be of lower density than the liquid, with the result that large “diamond bergs” would float on top of an ocean of liquid carbon. Each possible composition of the carbon layer, solid, liquid, or mixed, would affect the core of the planet differently. Solid diamond, for example, is electrically insulating and has a stiff crystal lattice, whereas liquid carbon is a metallic conductor and flexible. Determining the properties of the carbon layer could reveal whether or not Neptune and Uranus formed from a rocky protoplanet core billions of years ago. The diamonds produced in the SLAC experiments are nanoscale, a few nanometres across, because the experimental shock lasts only femtoseconds. On Neptune itself, the same chemical process would operate over millions of years and produce diamonds of much larger size. Theoretical models suggest that individual diamond crystals could grow to weights of millions of carats before sinking toward the planet’s core. The total mass of diamond produced over the planet’s history could amount to a substantial fraction of the total mantle material, with some estimates suggesting that Neptune may have a layer of solid diamond hundreds of km's thick surrounding its rocky core.
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The mass of diamond inside Neptune and Uranus, if these estimates are even approximately correct, would dwarf the total terrestrial diamond resource by many orders of magnitude. Diamond on Earth occurs in trace quantities in rocks called kimberlites and lamproites, with the global annual production of mined diamond on the order of 100 million carats/year, or about 20 tonnes. Neptune’s hypothesised diamond layer, if it exists at the scale current models suggest, would contain hundreds of millions of years of Earth’s diamond production in any given cubic kilometre. The diamonds would be inaccessible, Neptune is gaseous in its outer layers and the diamond rain region sits beneath thousands of kilometres of hydrogen and helium, but the resource itself, if any future technology could ever reach it, would be approximately the most abundant supply of pure crystalline carbon anywhere in the solar system. Although Ross’s idea was certainly fascinating, it was mainly hypothetical at the time and needed to be verified by observations. It is impossible with any imaginable technology to design and build a probe which could penetrate deep into Neptune or Uranus and directly observe the formation of diamonds. Scientists instead have tried to recreate the extreme conditions of planetary interiors in their laboratories. Even this more limited goal is extremely challenging, since we need to reliably generate and measure pressures of several million atmospheres and temperatures of several thousand kelvins to simulate their effects on the elements found inside the ice giants. In essence, we need to build a piece of a planet in the lab.
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Facilities around the world are tackling the problem by compressing a sample material, such as methane, between two diamond anvils with very small tips that press on the sample. The same effect of pressure enhancement can be seen on a different scale by placing something underneath the heel of a high-heeled shoe. Even though diamond anvils can generate pressures of several megabars (comparable to the pressure that would be produced by placing several thousand African elephants on top of that high-heeled shoe), the sample also needs to be heated by electrical currents or lasers in order to mimic hot planetary interiors. Using such a setup, some experiments have indeed formed diamond. However, in these setups the materials representing the planetary ice layers, methane, ammonia, or water, start to react with the diamond anvils and the gaskets. Those reactions can strongly alter and contaminate the results. Another way to generate the extreme pressure and temperature conditions found inside the ice giant planets is to create shock compression using strong explosives, high-velocity gun projectile impacts, or pulsed high-energy lasers. Although this process both compresses and heats the sample at the same time, the samples remain in the interesting state for only a tiny fraction of a second. Particularly for the high-energy lasers, which can achieve gigabar pressures and temperatures of millions of kelvins (comparable to the temperature at the center of the Sun), the conditions usually last a few nanoseconds or less. That is a very limited time in which to obtain precise and direct measurements of structural changes of the sample.
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The diamond-rain experiments have implications beyond Neptune and Uranus. Hydrocarbon-rich atmospheres are common in the universe. Many of the exoplanets discovered by the Kepler and TESS missions in the past 15 years are believed to be Neptune-like ice giants or larger “mini-Neptunes,” with atmospheres dominated by hydrogen, helium and varying mixtures of methane, water, and ammonia. The same physics which produces diamond rain in Neptune should, in principle, operate in many of these exoplanetary atmospheres. If even a small fraction of the known ice giants in the galaxy have functioning diamond-rain processes in their interiors, the total mass of crystalline carbon distributed across exoplanetary mantles in the Milky Way may be enormous. The next step in the experimental programme, according to the SLAC team, is to recreate the conditions found in still-deeper layers of these planets, pressures of 5 to 10 million atmospheres, temperatures approaching 10,000 K, and observe what other exotic chemistry occurs. The team has speculated that, at sufficient pressure, additional unusual phenomena may include the formation of metallic hydrogen, exotic compounds of helium and other noble gases, and possibly forms of carbon chemistry that have no Earth analogues at all. The diamond rain, in this view, is just the most accessible of a range of strange chemical processes which operate inside planets very different from Earth, and the SLAC experiments are the first direct experimental window into a kind of geology which exists nowhere on the visible surface of our own planet but is plausibly the dominant kind in much of the rest of the universe.
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This situation changed in 2009 with the completion of the world’s first x-ray free-electron laser: the Linac Coherent Light Source at Stanford University. Combining this machine with a powerful pulsed-laser system allows us to study chemical reactions at conditions comparable to those in the deep interiors of giant planets in real time. Plastics, which are mainly made out of carbon and hydrogen, are useful substances to mimic the material mix in the ice layers of Neptune and Uranus. Understanding the inner processes of the ice giants gives clues to the features of these planets. For example, diamond precipitation releases gravitational energy, which is converted to heat by friction between the diamonds and the surrounding material as they descend. This effect could explain why Neptune is emitting more energy than it receives from the Sun. Such an internal energy source may help to account for the origin of the surprisingly violent storms which are observed on the planet’s surface. Diamond formation may also explain why the ice giant planets’ magnetic fields are so exotic. Unlike Earth’s magnetic field, the fields around Uranus and Neptune are not symmetrical, and they don’t extend from each pole. These properties suggest that ice giant fields probably originate not in the core but in a thin, rather variable layer of conducting material, such as metallic hydrogen formed as a by-product of making diamonds. Other exotic processes inside the planets may also contribute to their magnetic fields. We will continue to study these phenomena in the lab, but a new space probe mission to Neptune or Uranus (or both) could add a wealth of information about the planets’ internal processes and about how such planets have formed in our Solar System and others. NASA is currently considering such a mission. In 2030, the planets of our Solar System will be favorably aligned for a spacecraft to launch and reach Uranus or Neptune by 2040. Another fortuitous alignment of the planets won’t come for another two generations, so now is the time to start thinking about exploring the ice giants up close and learning more about the Solar System’s intriguing diamond worlds in our universe.
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