Diamond formation kinetics in shock-compressed C─H─O samples recorded by small-angle x-ray scattering and x-ray diffraction.
Zhiyu HeMelanie RödelJulian LütgertArmin BergermannMandy BethkenhagenDeniza ChekryginaThomas E CowanAdrien DescampsMartin FrenchEric GaltierArianna E GleasonGriffin D GlennSiegfried H GlenzerYuichi InubushiNicholas J HartleyJean-Alexis HernandezBenjamin HeuserOliver S HumphriesNobuki KamimuraKento KatagiriDimitri KhaghaniHae Ja LeeEmma E McBrideKohei MiyanishiBob NaglerBenjamin K Ofori-OkaiNorimasa OzakiSilvia PandolfiChongbing QuDivyanshu RanjanRonald RedmerChristopher SchoenwaelderAnja K SchusterMichael G StevensonKeiichi SuedaTadashi TogashiTommaso VinciKatja VoigtJan VorbergerMakina YabashiToshinori YabuuchiLisa M V ZintaAlessandra RavasioDominik KrausPublished in: Science advances (2022)
Extreme conditions inside ice giants such as Uranus and Neptune can result in peculiar chemistry and structural transitions, e.g., the precipitation of diamonds or superionic water, as so far experimentally observed only for pure C─H and H 2 O systems, respectively. Here, we investigate a stoichiometric mixture of C and H 2 O by shock-compressing polyethylene terephthalate (PET) plastics and performing in situ x-ray probing. We observe diamond formation at pressures between 72 ± 7 and 125 ± 13 GPa at temperatures ranging from ~3500 to ~6000 K. Combining x-ray diffraction and small-angle x-ray scattering, we access the kinetics of this exotic reaction. The observed demixing of C and H 2 O suggests that diamond precipitation inside the ice giants is enhanced by oxygen, which can lead to isolated water and thus the formation of superionic structures relevant to the planets' magnetic fields. Moreover, our measurements indicate a way of producing nanodiamonds by simple laser-driven shock compression of cheap PET plastics.