Stable solid and aqueous H2CO3 from CO2 and H2O at high pressure and high temperature

Wang, Hongbo; Zeuschner, Janek; Eremets, M. I.; Troyan, I. A.; Willams, Jonathan

doi:10.1038/srep19902

Cited by 44 publications

(38 citation statements)

References 35 publications

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“…Recently, a new CO 2 -H 2 O compound was observed above 2.4 GPa and asserted to be H 2 CO 3 based on IR and Raman lines similar to those of the low pressure H 2 CO 3 solid (Wang et al 2016). Following this initial report, we (Abramson et al 2017) demonstrated that this new phase can exist in equilibrium with an aqueous fluid (starting from a quadruple point with ices H 2 O(VII) and CO 2 (I), at 4.4 GPa and 165 °C), which allowed the growth of single crystals for purposes of X-ray diffraction.…”

Section: Prior Studiesmentioning

confidence: 99%

“…However, owing to unfavorable kinetics and equilibrium constants at ambient conditions (Loerting et al 2000), molecular carbonic acid has 3 long eluded detailed experimental observation and, as described below, a crystalline structure had not previously been determined. Recently, Wang et al (2016) claimed to have observed the formation of solid carbonic acid at high pressures, and Abramson et al (2017) demonstrated that the observed phase can exist in thermodynamic equilibrium with the aqueous fluid for pressures beyond a quadruple point at 4.4 GPa. Preliminary X-ray results indicated that the new phase was triclinic, but their quality did not allow a refinement of the crystal structure.…”

Section: Introductionmentioning

confidence: 99%

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Carbonic acid monohydrate

Abramson

Bollengier

Brown

et al. 2018

American Mineralogist

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In the water-carbon dioxide system, above a pressure of 4.4 GPa, a crystalline phase consisting of an adduct of the two substances can be observed to exist in equilibrium with the aqueous fluid. The phase had been found to be triclinic, and its unit cell parameters determined, but the full crystalline, and even molecular, structure remained undetermined. Here, we report new diamondanvil cell, x-ray diffraction data of a quality sufficient to allow us to propose a full structure. The crystal exists in the P1 space group. Unit cell parameters (at 6.5 GPa and 140°C) are

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Section: Prior Studiesmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Carbonic acid monohydrate

Abramson

Bollengier

Brown

et al. 2018

American Mineralogist

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“…On Earth, H 2 CO 3 is found in a solution with water (H 2 O) and carbon dioxide (CO 2 ). It plays an important role in the global carbon cycle and in biological carbonate-containing systems (Wang et al 2016). For instance, about 30 − 40% of human-induced emissions of atmospheric Send offprint requests to: S. Ioppolo; e-mail: s.ioppolo@qmul.ac.uk CO 2 dissolve into the oceans to form carbonic acid (Caldeira & Wickett 2003).…”

Section: Introductionmentioning

confidence: 99%

Vacuum ultraviolet photoabsorption spectroscopy of space-related ices: formation and destruction of solid carbonic acid upon 1 keV electron irradiation

Ioppolo

Kaňuchová

James

et al. 2021

A&A

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Context. Carbonic acid (H2CO3) is a weak acid relevant to astrobiology which, to date, remains undetected in space. Experimental work has shown that the β-polymorph of H2CO3 forms under space relevant conditions through energetic (UV photon, electron, and cosmic ray) processing of CO2- and H2O-rich ices. Although its α-polymorph ice has been recently reassigned to the monomethyl ester of carbonic acid, a different form of H2CO3 ice may exist and is synthesized without irradiation through surface reactions involving CO molecules and OH radicals, that is to say γ-H2CO3. Aims. We aim to provide a systematic set of vacuum ultraviolet (VUV) photoabsorption spectroscopic data of pure carbonic acid that formed and was destroyed under conditions relevant to space in support of its future identification on the surface of icy objects in the Solar System by the upcoming Jupiter ICy moons Explorer mission and on interstellar dust by the James Webb Space Telescope spacecraft. Methods. We present VUV photoabsorption spectra of pure and mixed CO2 and H2O ices exposed to 1 keV electrons at 20 and 80 K to simulate different interstellar and Solar System environments. Ices were then annealed to obtain a layer of pure H2CO3 which was further exposed to 1 keV electrons at 20 and 80 K to monitor its destruction pathway. Fourier-transform infrared (FT-IR) spectroscopy was used as a secondary probe providing complementary information on the physicochemical changes within an ice. Results. Our laboratory work shows that the formation of solid H2CO3, CO, and O3 upon the energetic processing of CO2:H2O ice mixtures is temperature-dependent in the range between 20 and 80 K. The amorphous to crystalline phase transition of H2CO3 ice is investigated for the first time in the VUV spectral range by annealing the ice at 200 and 225 K. We have detected two photoabsorption bands at 139 and 200 nm, and we assigned them to β-H2CO3 and γ-H2CO3, respectively. We present VUV spectra of the electron irradiation of annealed H2CO3 ice at different temperatures leading to its decomposition into CO2, H2O, and CO ice. Laboratory results are compared to Cassini UltraViolet Imaging Spectrograph observations of the 70−90 K ice surface of Saturn’s satellites Enceladus, Dione, and Rhea.

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“…This information can be used to model and understand the interiors of giant exoplanets 22 . Wang et al 23 have shown that contrary to earlier understanding, carbonic acid could be a stable species in the aqueous fluids found in the subduction zone of the earth (P > 2.4 GPa). Even simple oxides of iron like hematite and magnetite decompose at 60-70 GPa and 2500 K to release large amounts of oxygen and form novel oxides of iron.…”

Section: Introductionmentioning

confidence: 39%

High Pressure:One of the many Tools to Study Material Properties at Extreme Conditions

Garg¹

2017

Current Science

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High pressure is a powerful and clean variable, which when applied can bring about large changes in structure and properties of materials. It can be used to simulate the conditions found deep inside the earth or in different planetary interiors. It is widely used in chemical industry, especially when the chemical reaction products have lower volumes than the initial reactants, and also in the food preservation industry, where it ensures that aromas and flavours are not lost even after preservation. Materials under pressure can be studied both theoretically and experimentally. In this article apart from discussing how to set up a basic high pressure experiment using the DAC, some examples have been elaborated to show how both experiments and theory complement each other and both put together can help in a deeper understanding of the changes brought about by application of high pressure.

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Stable solid and aqueous H2CO3 from CO2 and H2O at high pressure and high temperature

Cited by 44 publications

References 35 publications

Carbonic acid monohydrate

Carbonic acid monohydrate

Vacuum ultraviolet photoabsorption spectroscopy of space-related ices: formation and destruction of solid carbonic acid upon 1 keV electron irradiation

High Pressure:One of the many Tools to Study Material Properties at Extreme Conditions

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