Synthesis of prebiotic organics from CO2 by catalysis with meteoritic and volcanic particles

Blog

HomeHome / Blog / Synthesis of prebiotic organics from CO2 by catalysis with meteoritic and volcanic particles

Aug 15, 2023

Synthesis of prebiotic organics from CO2 by catalysis with meteoritic and volcanic particles

Scientific Reports volume 13,

Scientific Reports volume 13, Article number: 6843 (2023) Cite this article

5539 Accesses

385 Altmetric

Metrics details

The emergence of prebiotic organics was a mandatory step toward the origin of life. The significance of the exogenous delivery versus the in-situ synthesis from atmospheric gases is still under debate. We experimentally demonstrate that iron-rich meteoritic and volcanic particles activate and catalyse the fixation of CO2, yielding the key precursors of life-building blocks. This catalysis is robust and produces selectively aldehydes, alcohols, and hydrocarbons, independent of the redox state of the environment. It is facilitated by common minerals and tolerates a broad range of the early planetary conditions (150–300 °C, ≲ 10–50 bar, wet or dry climate). We find that up to 6 × 108 kg/year of prebiotic organics could have been synthesized by this planetary-scale process from the atmospheric CO2 on Hadean Earth.

The formation of reactive organic molecules to form the building blocks of life on the nascent Earth is one of the prerequisites for abiogenesis1,2,3. The emergence of a stable continental crust and liquid water on the Earth at ∼ 4.4 Gyr ago4,5, and the earliest biogenic carbon isotope signatures at ∼ 3.8–4.1 Gyr ago6,7 suggest that life originated only ∼ 400–700 million years after the formation of the Earth8,9,10. This relatively short time span indicates that the major part of organic precursors has been already formed on the Hadean Earth as early as 4.4 Gyr ago. One possibility is that the prebiotic organic constituents that had been formed in the solar nebula, carbon-rich asteroids, and comets have been delivered onto the early Earth11,12,13,14,15,16,17,18,19,20,21. Other theories consider the synthesis in the atmosphere and in the ocean by catalytic or high energy processes (lightnings, volcanic energy, impact shocks)22,23,24,25,26,27,28,29,30,31,32,33,34,35,36,37,38,39,40,41,42,43,44,45,46,47,48,49,50,51,52,53,54,55,56,57,58,59,60,61,62,63,64. Some of the underlying chemical processes have been experimentally simulated, such as Miller-Urey synthesis in the CH4 rich atmosphere, Fischer–Tropsch64—catalysis in the CO rich environments, the CO2 fixation to pyruvate over iron and nickel nanoparticles65, the aqueous Strecker synthesis of amino acids inside carbonaceous asteroids, or the interstellar ice chemistry in comets.

Yet, it is difficult to deduce with certainty which scenario was the most dominant (if any) due to missing key data. In the exogeneous delivery scenario, besides debated early bombardment rates, a poorly known fraction of the organic matter would have been lost upon the atmospheric entry by ablation, due to impact shocks and pyrolysis by heating, or dissolution in the melted crust. In the insitu synthesis scenario, the Miller-Urey-like synthesis would have been less productive in a CO2- and N2-rich, neutral atmosphere of the early Earth compared to the reduced, CH4-, N2-, H2-rich atmospheric conditions assumed in the early experiments66,67,68.

Another possible scenario, the organic synthesis around hydrothermal vents at the ocean floor has been extensively studied58,61,69,70. The organic synthesis in the ocean has limitations related to dilution of the reaction products or vaporization by giant impacts71. There are other scenarios proposed e.g., organic synthesis in the Darwinian ponds on the continental surface72, synthesis driven by the native iron reduction of CO261, or the Urey-Miller-like synthesis driven by converting a neutral Earth atmosphere to a reduced state upon collision with a single 1023 kg iron core73, etc.

We propose another robust pathway to the formation of key prebiotic organic matter on the early Earth. In this scenario, microscopic iron-rich particles from space or formed in situ by the giant impacts74, ablation of meteorites75, or produced by volcanic eruptions had been catalytically driving the CO2 fixation from the atmosphere. Natural minerals available on volcanic islands on the early Earth would have served as support materials in this synthesis (cf. Fig. 1). To test this idea, we investigated experimentally the catalytic properties of iron particles from meteorites and volcanic ash under the simulated reaction conditions of the early Earth in presence of CO2, H2 and H2O.

Formation of prebiotic key organic matter from CO2 by catalysis with meteoritic and volcanic particles. (A) Early Earth scenario with sources of catalytically active iron, and iron-rich particles. The exogenous sources include iron and iron-containing stony meteorites and asteroids producing nanoparticles by their thermal ablation in the atmosphere or after giant impacts. In situ sources are active volcanic chains similar to Hawaii, which produce iron-rich volcanic ash particles. These nano- and microscopic particles of elemental iron show catalytic activity and drive a robust synthesis of the feedstock atmospheric CO2 and H2 or H2O into key prebiotic organic compounds, at temperatures and pressures representative on the early Earth. Alternatively, H2 can be formed during the oxidation of elemental iron with water. These prebiotic organic compounds can act as reactants in further organic syntheses leading to the formation of carbohydrates, lipids, sugars23, amino acids55, and RNA and DNA molecules35. (B) Catalyst particles were prepared by acidic dissolution of iron meteorites Campo del Cielo and Muonionalusta, stone meteorite Gao-Guenie and volcanic ash from Etna (Sicily, Italy) (I), followed by the impregnation of support material, calcination at 450 °C (II), and reduction (III). To simulate a giant impact or volcanic eruption these materials were also ground in a ball mill. These catalytic particles were investigated in high-pressure autoclave experiments applying a broad range of conditions (9–45 bar and 150–300 °C) with a mixture of CO2 and H2 (IV). The reaction products were identified and quantified by GC–MS measurements (V).

As catalytically active metal sources on the early Earth we considered iron meteorites, stony meteorites, and volcanic ash. In our experiments we investigated representative samples of the iron meteorites Campo del Cielo and Muonionalusta, the stony meteorite Gao-Guenie, and volcanic ash from Etna. Their different metal composition is summarized in Table 1.

The iron meteorites Campo del Cielo and Muonionalusta contain considerable amounts of Ni and traces of Ir, which are good hydrogenation catalysts.

It is well known that the catalyst particles stabilized on the surface enlarging supports (e.g. Al2O3) increase the catalytic activity and stability. Here, we follow a similar approach by combining our iron sources with natural minerals that might have been available on the early Earth. This simulates experimentally a process where the formed metal particles were deposited on minerals, e.g. (1) montmorillonite, (2) olivine, (3) diopside, and (4) hydroxyapatite. All of them are present either in the Earth crust or in meteorites and asteroids: While montmorillonite and hydroxyapatite can be formed under hydrothermal conditions, olivine and diopside are products of mafic volcanism. In addition, we use silica gel (5) as a reference system. The elemental compositions of these supports were determined via the energy dispersive X-ray analysis (EDX) and are summarized in Table 2.

The meteorites and the volcanic ash were dissolved in aqueous nitric acid yielding the stock solutions. The stone meteorite and the volcanic ash are not completely dissolved under these conditions, therefore the solutions were dispersed and used without filtration. For the preparation of the supported oxidized catalysts, the support (silica gel, hydroxyapatite, olivine, diopside and montmorillonite clay) was impregnated with the stock solution. The prepared suspension was dried at 100 °C and subsequently calcined at 450 °C for 4.5 h. Under these conditions the metal nitrates completely decompose under formation of the corresponding metal oxides.

For preparation of the ball milled oxidized catalysts from the Campo del Cielo meteorite, the meteorite was dissolved in aqueous nitric acid vide supra. This solution was dried at 100 °C. The resulting powder or volcanic ash was mixed with the support materials (silica gel, hydroxyapatite, olivine, diopside and montmorillonite clay) and milled in the ball mill at 800 rpm for 15 min.

This procedure simulates the crushing process of meteorites and asteroids or the formation of the volcanic ash particles. The freshly obtained catalysts were examined by the scanning electron microscopy (SEM) to determine their surface topology and the size of the formed nanoparticles. In Fig. 2 an SEM picture and the size distribution of the particles prepared by dissolution of a sample of the Campo del Cielo meteorite and impregnation on the montmorillonite support is shown. The mean size and narrow distribution of 4.7 ± 2.4 nm shows that small nanoparticles can be obtained, which can act as highly active catalysts. All samples were characterized by the SEM and the size distributions determined (see Supplementary Information section IV).

The pre-catalyst prepared from the Campo del Cielo meteorite supported on Montmorillonite. (A) Scanning electron microscopy (SEM) picture of oxidized particles of the Campo del Cielo meteorite on the support montmorillonite. (B) Size distribution of the nanoparticles with mean and standard deviation (σ).

For the reduction of the oxidized catalysts, ≈ 1 g of the impregnated support materials was transferred in the glass insert (quartz glass) of the autoclave. The autoclave was evacuated and flushed with nitrogen (three times). After evacuation (9 × 10–3 mbar), hydrogen (≈ 50 bar) was pressurized into the autoclave. Reduction of the oxidized catalysts was achieved by heating to 300 °C for 17  hours.

After reduction the excess hydrogen of the reduced and cooled down supported catalyst was released and carbon dioxide and, subsequently, hydrogen or water were added with a defined partial pressure or volume, respectively. The pressurized autoclave was then heated to the corresponding temperature. The detailed reaction conditions are listed in the Supplementary Information section VII. After the set reaction time, the autoclave was cooled to 0 °C (to condense the volatile compounds). In order to separate the formed organic compounds from the catalyst, a distillation was performed. The black, frozen catalyst was cooled to − 180 °C and transferred to the glass distillation apparatus. This apparatus was evacuated to 3 × 10–2 mbar. Then, the leg of the distillation apparatus with the catalyst was heated to 210–220 °C and the evaporated compounds were condensed into a flask cooled with liquid nitrogen (− 180 °C). After completion of the distillation process the apparatus was opened and, after a warming, the reaction products were collected by adding dichloromethane (3 × overall 0.3 mL or 0.5 mL).

To investigate the catalytic properties of the prepared catalysts, a reaction screening was performed using a high-pressure autoclave system. The mineral supported catalysts were pressurized with CO2 and H2 gases at various partial pressures (CO2: 5–40 bar; H2: 5–41 bar; total pressure: 9–45 bar) and heated (150 °C–300 °C) in the autoclave system to cover a broad range of conditions. Under these conditions, the oxidized catalysts, which are typically red coloured by the oxidized Fe, are reduced and activated, turning to dark black coloured materials. The reduced material corresponds to the deposited particles formed by thermal ablation upon an entry of meteorites in the atmosphere or crushing of material by (geo-) mechanical forces. These autoclave reactions were performed for several days and weeks. After cooling down and release of pressure, the reaction products were isolated by separation from the catalysts by micro-distillation, and then identified and quantified using gas chromatography–mass spectrometry (GC–MS) (see Supplementary Information section V).

Figure 3 shows the product distribution resulting from experiments with the catalytic active particles obtained from the Campo del Cielo meteorite supported on montmorillonite at 300 °C, a H2:CO2 ratio of 2:1 and a total pressure of 45 bar. The total product mass was 934 μg, with the yield being comparable to the results under hydrothermal conditions59. The main components were methanol, ethanol, and acetaldehyde, summing up to 70wt% in total. The residue consists of n-alkanes (n-hexane to n-pentadecane) and iso-alkanes (iso-heptane to iso-tetradecane), each accounting for approx. 15% of the total product mass. We also detected formaldehyde under these conditions (see Supplementary Information section V-B). The identification of such large amounts of oxygenated organic compounds is an exciting result, because formaldehyde and acetaldehyde are important building blocks for the synthesis of carbohydrates, amino acids and for forming deoxyribonucleosides. This analysis was performed for catalytic screening reaction with all catalytic materials prepared (see Supplementary Information VII). Under these conditions no other reaction products were detected. The product ratios of the compounds, the overall yield, and the distributions of the detected reaction products of catalysis depend on the physical conditions. Surprisingly, even the reaction temperatures as low as 150 °C and the extended reaction times of 14 days yielded reaction products, which shows that the materials are catalytically active even under mild reaction conditions. Therefore, a comprehensive screening by varying these reaction conditions was performed (vide infra).

Reaction product distribution by the carbon number. Reaction conditions: a gas mixture of CO2:H2 = 1:2, a total pressure of 45 bar, temperature of 300 °C, and reaction time of 4 days. Catalyst: Metal particles prepared from the Campo del Cielo meteorite on montmorillonite as support. The overall yield was 934 µg and turn over number was 3.97 g/(kg d). (A) Pie chart of the product distribution (in mass percentage) separating oxygenated reaction products (yellow; methanol, acetaldehyde, and ethanol), n-alkanes (red; n-hexane to n-hexadecane) and iso-alkanes (green; from iso-heptane to iso-pentadecane). (B) Bar plot showing the mass percentage of compounds with a different number of C-atoms in each group: oxygenated reaction products (yellow), n-alkanes (red) and iso-alkanes (green).

To exclude potential contamination due to the solvents and from the experimental setup itself, we conducted a series of blank measurements to validate the results. Additionally, we performed experiments with the pure supports and metal sources to quantify their catalytic activities as well as impurities under the same reaction conditions. In all blank experiments, the resulting masses of oxygenated products, n-alkanes, and iso-alkanes did not exceed 4 μg, which is significantly lower than, for example, the 934 μg that have been obtained in the experiment shown in Fig. 3.

To perform a quantitative comparison of all experiments, we standardized the results by calculating turnover numbers (TON) for each experiment. The TON is defined as the mass of the reaction product (\({m}_{product}\)) divided by the product of the mass of the catalyst (\({m}_{metcat}\)) and time (\(t\)):

The turnover number is independent of the size of the nanoparticles. The size of the nanoparticles is very similar for the all considered materials, which have the size distribution between ~ 5 and 10 nm.

We investigated the catalytic materials prepared from the meteorite and volcanic ash samples systematically (reaction conditions: a gas mixture of CO2:H2 = 1:2, a total pressure of 45 bar, temperature of 300 °C, and reaction time of 4–5 days). Figure 4 summarizes the yields and the product distribution for all the catalysts on the various supports and prepared by the wet impregnation approach and by ball milling. The supports have a strong influence on the activity and can significantly enhance the catalytic activity [up to TON = 85.50 g/(kg d)]. This effect is smaller in the experiments with hydroxyapatite [up to TON = 1.00 g/(kg d)] and olivine [up to TON = 5.13 g/(kg d)]. In the case of hydroxyapatite, this is probably due to the alkaline surface, since an experiment with calcium carbonate showed similar results (see Supplementary Information). For olivine, it is likely that the surface properties influence the activity. In the same experiment with a synthetic forsterite (Mg2[SiO4]) that has a similar composition, but a different structure than the natural olivine, the activity is significantly increased [TON = 8.30 g/(kg d); see SI].

Screening of the metal sources and supports for the CO2 fixation. Metal sources (x-axis): blank (measurements without a supporter), Campo del Cielo (iron meteorite) as nanoparticles (Nanoparticles) and microscopic particles (Ball Mill), Muonionalusta (iron meteorite) as nanoparticles (Nanoparticles), Gao-Gunie (stone meteorite) as nanoparticles (Nanoparticles) and volcanic ash as nanoparticles (Nanoparticles) and microscopic particles (Ball Mill). Supports (y-axis): blank (without a metal source, \({m}_{metcat}\) is set to the mass of the support) silica gel, hydroxyapatite, olivine, montmorillonite, and diopside. A symbol "x" indicates that no reaction has occurred. The size of the circle reflects the turnover number of the catalyst (see scale at the right). The pie charts within these circles show the product distribution containing the oxygenated products (yellow: methanol, acetaldehyde and ethanol), n-alkanes (red: n-hexane to n-hexadecane) and iso-alkanes (green: from iso-heptane to iso-pentadecane). Reaction conditions: a gas mixture of CO2:H2 = 1:2, a total pressure of 45 bar, temperature of 300 °C, and reaction time of 4–5 days.

Comparing the metal sources, the volcanic ash shows the highest activity and, hence, has the highest turnover number. A reason for this observation could be the presence of catalytic promoters such as potassium and sodium salts, which were found in the volcanic ash (Table 1).

Iron and nickel rich Muonionalusta and Campo del Cielo meteoritic catalysts are slightly less active. The lowest turnover number is observed when using the stony meteorite as a source of catalytic particles. A possible reason could be the lower yield in catalytically active nanoparticles obtained in the preparation of these materials (see Tables 1 and 5).

The highest selectivity in favour of the formation of alkanes and branched alkanes was observed for the combination of metallic Campo del Cielo catalyst and montmorillonite (up to 30% alkanes) (cf. Fig. 3). In contrast to this, we found that all other catalysts showed higher selectivity for oxygenated products, which make up more than 95% of the total product mass.

We then studied the influence of the nanoparticle size on the catalytic activity. For this purpose, different metal salt concentrations of Campo del Cielo were mixed with silica gel or montmorillonite, dried, and calcined. By increasing the metal salt concentrations, the nanoparticles became smaller (silica gel: 13.38 nm > 11.81 nm > 9.63 nm) and we observed that the yield of CO2 [silica gel: TON = 1.37 g/(kg d) < 4.39 g/(kg d) < 36.97 g/(kg d)] conversion increased in catalytic experiments (for more details see Table S10 in the SI). Using a ball mill, we produced microscopic catalysts with a 100 times bigger particle size. Surprisingly, such large particles still showed catalytic activity. However, in contrast to the catalysts formed during wet impregnation, the metal ratio in these micrometer-sized catalysts had to exceed a threshold to show a significant product formation (see Supplementary Information Table S11). For the catalyst prepared from the Campo del Cielo meteorite supported on diopside, we observed a similar activity for ball milled micrometer-sized particles and for the nanoparticle catalysts. For the other catalysts, the turnover number for the ball mill particles was 3–24% of that of the nanoparticles (see Supplementary Information Table S11). This can be explained by the lower surface-to-volume ratio of the ball mill particles as compared to the nanoparticles, leading to a smaller number of catalytic surface sites per unit area of the support.

We identified favourable environmental conditions for the formation of key prebiotic organic matter on the early Earth by systematic screening of the reaction conditions. The results for various temperatures as well as for various CO2:H2 ratios and pressures using the catalytic particles from the Campo del Cielo iron meteorite on the montmorillonite support are depicted in Figs. 5 and 6, respectively.

Temperature and reaction time dependence of the CO2 fixation. Turnover numbers at different reaction times (3–38 d) and temperatures (150–300 °C). The size of the circle reflects the turnover number (see scale at the right). The pie charts within these circles show the product distribution containing the oxygenated products (yellow: methanol, acetaldehyde and ethanol), n-alkanes (red: n-hexane to n-hexadecane) and iso-alkanes (green: from iso-heptane to iso-pentadecane). Reaction conditions: a gas mixture of CO2:H2 = 1:2 and a total pressure of 45 bar. Iron particles were prepared from the Campo del Cielo meteorite at montmorillonite as support.

Partial pressure dependence of the CO2 fixation. Turnover number at different partial pressures of carbon dioxide (3–40 bar) and partial pressures of hydrogen (2–40 bar). The size of the circle reflects the turnover number (see scale at the right). The pie charts within these circles show the product distribution containing the oxygenated products (yellow: methanol, acetaldehyde and ethanol), n-alkanes (red: n-hexane to n-hexadecane) and iso-alkanes (green: from iso-heptane to iso-pentadecane). Reaction conditions: either a gas mixture of CO2:H2 with equal ratio 1:1 but varied total pressure or CO2:H2 with varied ratio but a total pressure of 45 bar. Temperature is 300 °C, and reaction time is 3–4 days. Iron particles prepared from the Campo del Cielo meteorite on montmorillonite as support.

Figure 5 shows that there is a strong temperature influence on the reaction products. Below 300 °C, only oxygenated products were formed with the TON increasing with temperature and reaction time, while at 300 °C, both n-alkanes and iso-alkanes were detected. Here, the total mass of the products decreased with reaction time [38 d and 300 °C: TON = 0.21 g/(kg d)]. However, a larger variety of branched alkanes was observed at the end of the experiment after 38 days, likely formed by cracking alkanes and rearrangement reactions on the montmorillonite support41.

The most striking result is that the catalysis with meteoritic particles is robust and produces prebiotic organic matter under both neutral and reducing atmospheric conditions (see Fig. 6). The highest overall yield and the largest share of oxygenated products was observed at a CO2:H2 pressure ratio of 21:24 and a total pressure of 45 bar [TON = 7.3 g/(kg d)]. The overall catalytic activity was lower at lower total gas pressures, as commonly observed in the Fischer–Tropsch catalysis76. The catalysis is more efficient in a CO2-rich [CO2:H2 = 40:5; TON = 3.72 g/(kg d)] than in an H2-rich environment [CO2:H2 = 5:41; TON = 0.16 g/(kg d)]. Both the dependence on the temperature and the atmospheric conditions suggest that the oxygenated compounds such as aldehydes and alcohols are formed under milder conditions, while alkanes are formed by reactions of these intermediates at elevated temperatures.

As already pointed out, the most readily produced oxygenated products (especially the aldehydes) are essential compounds for the formation of building blocks of life such as (deoxy) ribosyl moiety of RNA and DNA nucleosides35,36, amino acids55, and carbohydrates22,57. If we project our experimental results to the history of the early Earth, the yield and the selectivity towards oxygenated products should have increased with the gradual loss of the primordial H2 and the cooling of the atmosphere.

To consider environmental conditions under which H2 was not readily available, experiments have also been carried out under reduced partial pressure of H2 (see Fig. 7) and solely in the presence of CO2 and H2O (see Supplementary Information Table S14). In the former we can clearly see that the CO2 fixation still works under the mild conditions of 10 bar carbon dioxide, 1 bar hydrogen and 200 °C, although the turn-over number is reduced by two orders of magnitude compared to the experiments at higher pressures. These reaction conditions also reflect other models predicting lower atmospheric pressures on the Hadean earth, e.g. a maximum of ~10 bars of CO2 and ~1 bar of nitrogen77 or even lower pressures78. Again, we observe that alkanes are only formed at higher temperatures. In the experiments with water, we observed that the redox reaction of reduced iron with water led to the continuous in situ generation of H278. This coupled process of the H2 formation and its immediate reaction with CO2 produces oxygenated products, as for the case of the CO2–H2 experiments.

CO2 fixation with low hydrogen partial pressure. Turnover numbers at different partial pressures of carbon dioxide (8–40 bar) and temperatures (200–300 °C) are shown. The size of the circle reflects the turnover number (see scale at the right). The pie charts within these circles show the product distribution containing the oxygenated products (yellow: methanol, acetaldehyde and ethanol), n-alkanes (red: n-hexane to n-hexadecane) and iso-alkanes (green: from iso-heptane to iso-pentadecane). Reaction conditions: The partial pressures of hydrogen in these experiments were 1–2 bar and the reaction time was 3–10 days. Iron particles prepared from the Campo del Cielo meteorite supported on montmorillonite.

Because alkanes were formed only under harsher reaction conditions and their yield is a few orders of magnitude lower than the yield of the oxygenated products, it is likely that two different, partially independent mechanisms are responsible for their production. The formation of the alkanes and the fact that they are only observed under certain conditions (montmorillonite, Campo del Cielo, high temperatures, high partial pressure of hydrogen) can be explained by the water gas shift reaction shown in Fig. 8.

Water gas shift reaction, which could have a positive effect on the formation of alkanes in CO2 fixation.

The use of montmorillonite as a catalyst leads to the removal of water. Therefore, it shifts the equilibrium to the carbon monoxide side. The same holds when the partial pressure of carbon dioxide is low, and the partial pressure of hydrogen is high. The latter also leads to a very high concentration of hydrides on the surface, and thus a highly reductive environment. For the explanation of the effect of temperature, we have to look at the state of aggregation of water, because the presence of gaseous water leads to a shift of the equilibrium to the side of carbon monoxide. Starting from 250 °C and the resulting pressure of 89 bar in the autoclave, water is gaseous. Therefore, our conditions favour the presence of carbon monoxide which can form linear and branched alkanes via the classical Fischer–Tropsch reaction. Only Campo del Cielo shows a significant production of alkanes, since all other metal sources contain elements that hamper the Fischer–Tropsch reaction, for example, sulphur. Since the conditions favouring alkanes also shift the water gas reaction towards the side of carbon monoxide, it is assumed that they are formed by the classical Fischer–Tropsch reaction.

We propose a mechanism for the formation of the oxygenated products (see Fig. 9). This mechanism is also in agreement with the findings by Varma, Muchowska, Chatelain, and Moran for the formation of formic acid, methanol, and acetate under hydrothermal conditions61 and also observed for nanoparticle catalysts79. The first step is the dissociation of hydrogen on the catalytic surface, as known from the Haber–Bosch and the Fischer–Tropsch reaction. With addition of carbon dioxide, a surface-formyl is formed. This compound can be reduced to a surface-hydroxymethyl and a surface-methyl.

Proposed mechanism for the carbon fixation. As a first step, hydrogen bond is cleaved on the surface as in the Fischer–Tropsch and Haber–Bosch synthesis. By addition of carbon dioxide and condensation, a surface-formyl is formed, similar to the mechanism proposed by Varma, Muchowska, Chatelain, and Moran61. Next, via reduction and recombination of the surface-species, the products, which are marked blue, are formed. A dashed horizontal line shows the metal surface.

Recombination of these compounds with each other or with a surface-hydride leads to the formation of formaldehyde, methanol, acetaldehyde, and ethanol. This mechanism also suggests production of methane and ethane, which were however not detected under investigated reaction conditions. Please note that there is no possibility to build CH2-fragments to achieve a chain elongation (as in the Fischer–Tropsch reaction), and hence only products with a maximum of two carbon atoms are generated. The proposed mechanism additionally explains why, in contrast to hydrothermal59,61 and laser spark experiments24,59, no carboxylic acids were formed.

The catalysed synthesis as a source of prebiotic organic matter should have been most active during Hadean, as it requires surface temperatures above about 150 °C and several bar of atmospheric pressure to operate. The conditions on the early Earth at that time, with high planetesimal bombardment rates and volcanic activity should have been the most favourable for the production of iron-rich catalytic particles and atmospheric H2, driving the synthesis. Following predictions of the atmospheric model for the early Earth with at least several to several tens of giant impacts during Hadean80, we considered a post-impact neutral CO2:H2:N2 atmosphere with a total pressure of about 3–10 bar and a surface temperature of the volcanically active islands of about 130–200 °C (for details, see Supplementary Information section VIII). Next, we assumed that montmorillonite-like minerals, a common product of the acidic weathering of volcanic rocks, covered the surface of these islands and served as support for this synthesis. The subaerial surface at that time was at most about 1% of the modern continental landmass. The minimum and maximum total delivery rates of the exogenous matter of ∼ 3 × 1012 and 1015 kg/yr were adopted52, and a mass fraction of FeNi and iron-rich compounds was calculated using measured meteoritic and IDP abundances. Assuming that only < 0.1 – 1% fraction of the metals or iron-rich silicates would recondense as catalytic nano- and micron-sized particles, the total delivery rate of the exogenous catalysts on the subaerial surface of the Hadean Earth could have been ∼ 5 × 107–4 × 1011 kg/yr (Supplementary Information, section VIII.B).

We also assumed that the volcanic activity on the Hadean Earth has been at most several times higher than on the modern Earth, producing a total ash volume of up to ~ 20–100 km3 (Supplementary Information, section VIII.C). Based on modern geological data, about 4 wt% of that volume would be represented by the iron-rich silicate particles smaller than 30 micron. The resulting total deposition rate of the fine ash particles into the subaerial surface could have been ~ 2 × 1011–1012 kg/yr. Finally, based on our experimental results, we assumed that the catalytic particles deposited on minerals would be active for about 30 days.

By taking the measured synthesis yields at T = 150–200 °C and scaling these values down to the total pressures of ~ 3–7 bar, the resulting production rate of the prebiotic organics in a CO2-rich atmosphere with P(CO2)/P(H2) ~ 1–2 could have been up to ~ 106–6 × 108 kg/yr (Supplementary Information, section VIII.D). This is comparable or exceeding the delivery rate of the exogenous organic matter onto the subaerial surface of ~ 2 × 107 kg/yr and endogenous production in the post-impact zones of ~ 104 kg/yr44. The Urey-Miller-like organic synthesis driven by volcanic lightnings could have added another ≲4 × 109 kg/yr of organics to this production rate59. In contrast, if the early Earth atmosphere had been CO-rich instead of CO2-rich80,81, the Fischer–Tropsch synthesis driven by the native iron or exogenous FeNi particles would produce up to 7 × 1010–5 × 1013 kg/yr of CH4, 7 × 109–5 × 1012 kg/yr of HCN, and other organics82,83.

We conclude that the catalytic synthesis presented in this study could have produced a substantial amount of key oxygenated organics in a neutral, CO2-rich atmosphere on the Hadean Earth77, complementing production of precursors of sugars and amino acids by other processes66,84,85. Over a geologically short time span of several tens of Myr, the mass of prebiotic organics synthesized in situ on the early Earth could have been as high as ~ 1013–6 × 1016 kg, comparable with or exceeding the modern aquatic and total terrestrial biomasses, respectively86.

In this work, we experimentally showed that meteoritic and volcanic iron-rich particles are efficient catalysts for converting atmospheric carbon dioxide into hydrocarbons, methanol, ethanol, formaldehyde, and acetaldehyde, which are important precursors for lipids, nucleosides, sugars, and amino acids. These particles exhibit catalytic activity in the presence of naturally occurring minerals and atmospheric CO2, H2 or H2O at temperatures and pressures representative of the early Earth. Since the early Earth's atmosphere has likely been evolving toward a more oxidizing state, the oxygen-containing organic compounds would have been produced more efficiently with time, promoting further synthesis of more complex prebiotic compounds. Thus, the early Earth and similar young rocky exoplanets could be regarded as a giant catalytic reactor converting feedstock atmospheric gases into complex prebiotic organic matter.

Anhydrous dichloromethane (Honeywell or Acros Organics, 99.8%), iron nitrate nonahydrate (Alfa Aesar, 98.0–101.0%), nickel nitrate hexahydrate (Alfa Aesar, 98%), cobalt nitrate hexahydrate (Alfa Aesar, 98.0–101.0%), germanium tetrachloride (Alfa Aesar, 99.99999%), gallium nitrate (Sigma Aldrich, GA 9–10% W/W), dimedone (Sigma Aldrich, ≥ 99.0%), anhydrous iridium chloride (Strem Chemicals, 99.95+%) were purchased and used as received. Hydrogen (99.999%) and carbon dioxide (99.998% or 99.995%) were purchased from Air Liquid. Fused silica capillaries were purchased from MicroQuartz, Munich, Germany. The gas chromatographic stationary phase GE-SE-30 was obtained from Macherey & Nagel, Düren, Germany. Montmorillonite was purchased from Alfa Aesar as 'naturally occurring mineral', ~ 200 mesh powder and used as received. Silica gel was purchased from Acros Organics as 0.035–0.070 mm, 60 Å powder and used as received. Campo del Cielo was purchased from Decker Meteorite-Museum, Oberwesel, Germany, and used as received. The meteorites Muonionalusta, and Gao-Guenie, the minerals olivine and diopside were provided by the 'Mineralogische Staatssammlung Bayern'. The minerals were powdered in the ball mill (400 rpm for 15 min). The volcanic ash was collected from an eruption of the Etna, Sicily, Italy, on April 23rd 2012 in Fornazzo. For the reductions and reactions under high pressure, a high-pressure stainless-steel autoclave with a 200 mL glass insert with digital pressure gauges, fine throttling valve, and temperature sensor 330 mm. The autoclave is tightened with silver gasket. The temperature was adjusted by a heating hood 20 S, equipped with a magnetic stirrer. The autoclaves were purchased from Carl Roth, Karlsruhe, Germany. For reactions under aqueous conditions an addition a three-way ball valve was installed between the autoclave and the fine throttling valve. The autoclaves were pressurized with a home build high pressure screening setup87. The Planetary Ball Mill 33 Pulverisette 7 was purchased from Fritsch GmbH, Idar-Oberstein, Germany and was used with two grinding bowls of 20 mL stainless steel and 12 balls of 10 mm stainless steel. A Thermo Trace gas chromatograph (San Jose, California, USA) equipped with a split-injector (250 °C), a flame ionization detector (250 °C) for the quantitative analyses, and for the identification a quadrupole ion trap (PolarisQ MS) mass spectrometer or quadrupole (ISQ single quadrupole MS) mass spectrometer was used, respectively. Gas chromatographic analysis was performed on a 25 m GE-SE-30 250 nm (ID 250 μm).

For the catalyst activities we were used the catalysts in CO2 fixation under standard conditions (T = 300 °C, p = 45 bar, H2:CO2 = 2:1, t = 3–4). The results are summarized in Table 3.

To verify the size metal source particles, catalysts were prepared from montmorillonite and silica gel, respectively, with different metal concentrations of Campo del Cielo. The smaller the metal concentration, the smaller the nanoparticles. These catalysts, were now used in CO2 fixation under standard conditions (T = 300 °C, p = 45 bar, H2:CO2 = 2:1, t = 3–4). The results are summarized in Table 4.

To verify the micrometer size, catalysts were prepared from all supports, with different metal concentrations of Campo del Cielo} and volcanic ash, respectively. These catalysts, were now used in CO2 fixation under standard conditions (T = 300 °C, p = 45 bar, H2:CO2 = 2:1, t = 3–4). The results are summarized in Table 5.

For the temperature and reaction time screening we were used various temperatures (150–300 °C) and reaction times (3–38 days) in CO2 fixation under conditions (p = 45 bar, H2:CO2 = 2:1, catalyst = synthetic Campo del Cielo at montmorillonite). The results are summarized in Table 6.

For the pressure and partial pressure screening we were used various pressures (9–45 bar) and ratios of H2:CO2 (1:9 to 9:1) in CO2 fixation under conditions (T = 300 °C, t = 3–4, catalyst = synthetic Campo del Cielo at montmorillonite). The results are summarized in Table 7.

The results of the experiments with water instead of hydrogen are summarized in Table 8. The conditions were T = 300 °C, t = 3–4, catalyst = synthetic Campo del Cielo at montmorillonite and pressure of CO2 = 40 bar.

All data are available in the main text or the supplementary materials.

Butch, C. J., Meringer, M., Gagnon, J.-S. & Cleaves, H. J. Open questions in understanding life's origins. Commun. Chem. 4, 11 (2021).

Article PubMed PubMed Central Google Scholar

Wu, L.-F. & Sutherland, J. D. Provisioning the origin and early evolution of life. Emerg. Top. Life Sci. 3, 459–468 (2019).

Article CAS PubMed PubMed Central Google Scholar

Wołos, A. et al. Synthetic connectivity, emergence, and self-regeneration in the network of prebiotic chemistry. Science 369, 1584 (2020).

Article Google Scholar

Wilde, S. A., Valley, J. W., Peck, W. H. & Graham, C. M. Evidence from detrital zircons for the existence of continental crust and oceans on the earth 4.4 gyr ago. Nature 409, 175–178 (2001).

Article CAS PubMed ADS Google Scholar

Mojzsis, S. J., Harrison, T. M. & Pidgeon, R. T. Oxygen-isotope evidence from ancient zircons for liquid water at the earth's surface 4,300 myr ago. Nature 409, 178–181 (2001).

Article CAS PubMed ADS Google Scholar

Dodd, M. S. et al. Evidence for early life in earth's oldest hydrothermal vent precipitates. Nature 543, 60–65 (2017).

Article CAS PubMed ADS Google Scholar

Tashiro, T. et al. Early trace of life from 3.95 ga sedimentary rocks in Labrador, Canada. Nature 549, 516–518 (2017).

Article PubMed ADS Google Scholar

Barge, L. M. et al. Thermodynamics, disequilibrium, evolution: Far-from-equilibrium geological and chemical considerations for origin-of-life research. Orig. Life Evol. Biosph. 47, 39–56 (2017).

Article CAS PubMed ADS Google Scholar

Arndt, N. T. & Nisbet, E. G. Processes on the young earth and the habitats of early life. Annu. Rev. Earth Planet. Sci. 40, 521–549 (2012).

Article CAS ADS Google Scholar

Pearce, B. K. D., Tupper, A. S., Pudritz, R. E. & Higgs, P. G. Constraining the time interval for the origin of life on earth. Astrobiology 18, 343–364 (2018).

Article CAS PubMed ADS Google Scholar

Connelly, J. N., Amelin, Y., Krot, A. N. & Bizzarro, M. Chronology of the solar system's oldest solids. ApJL 675, L121–L124 (2008).

Article CAS ADS Google Scholar

Mojzsis, S. J. Earth, Formation and Early Evolution 467–474 (Springer, 2011).

Google Scholar

Yu, G. & Jacobsen, S. B. Fast accretion of the earth with a late moon-forming giant impact. PNAS 108, 17604 (2011).

Article CAS PubMed PubMed Central ADS Google Scholar

Thiemens, M. M., Sprung, P., Fonseca, R. O. C., Leitzke, F. P. & Münker, C. Early moon formation inferred from hafnium–tungsten systematics. Nat. Geosci. 12, 696–700 (2019).

Article CAS ADS Google Scholar

Mojzsis, S. J., Brasser, R., Kelly, N. M., Abramov, O. & Werner, S. C. Onset of giant planet migration before 4480 million years ago. Astrophys. J. 881, 44 (2019).

Article CAS ADS Google Scholar

Tsiganis, K., Gomes, R., Morbidelli, A. & Levison, H. F. Origin of the orbital architecture of the giant planets of the solar system. Nature 435, 459–461 (2005).

Article CAS PubMed ADS Google Scholar

Claeys, P. & Morbidelli, A. Late heavy bombardment. In Encyclopedia of Astrobiology 909–912 (Springer, 2011).

Chapter Google Scholar

Bottke, W. F. et al. An archaean heavy bombardment from a destabilized extension of the asteroid belt. Nature 485, 78–81 (2012).

Article CAS PubMed ADS Google Scholar

Abramov, O., Kring, D. A. & Mojzsis, S. J. The impact environment of the hadean earth. Geochemistry 73, 227–248 (2013).

Article CAS Google Scholar

Marchi, S. et al. Widespread mixing and burial of earth's hadean crust by asteroid impacts. Nature 511, 578–582 (2014).

Article CAS PubMed ADS Google Scholar

Osinski, G. R., Cockell, C. S., Pontefract, A. & Sapers, H. M. The role of meteorite impacts in the origin of life. Astrobiology 20, 1121–1149 (2020).

Article CAS PubMed PubMed Central ADS Google Scholar

Miller, S. L., Urey, H. C. & Oró, J. Origin of organic compounds on the primitive earth and in meteorites. J. Mol. Evol. 9, 59–72 (1976).

Article CAS PubMed ADS Google Scholar

Butlerow, A. Bildung einer zuckerartigen Substanz durch Synthese. Liebigs Ann. 120, 295–298 (1861).

Article Google Scholar

Miller, S. L. & Urey, H. C. Organic compound synthesis on the primitive Earth. Science 130, 245–251 (1959).

Article CAS PubMed ADS Google Scholar

Oró, J. Synthesis of adenine from ammonium cyanide. Biochem. Biophys. Res. Commun. 2, 407–412 (1960).

Article Google Scholar

Huber, C. & Wächtershäuser, G. Activated acetic acid by carbon fixation on (Fe, Ni)S under primordial conditions. Science 276, 245–247 (1997).

Article CAS PubMed Google Scholar

Miyakawa, S., Yamanashi, H., Kobayashi, K., Cleaves, H. J. & Miller, S. L. Prebiotic synthesis from co atmospheres: Implications for the origins of life. Proc. Natl. Acad. Sci. USA 99, 14628 (2002).

Article CAS PubMed PubMed Central ADS Google Scholar

Powner, M. W., Gerland, B. & Sutherland, J. D. Synthesis of activated pyrimidine ribonucleotides in prebiotically plausible conditions. Nature 459, 239–242 (2009).

Article CAS PubMed ADS Google Scholar

Bada, J. L. New insights into prebiotic chemistry from stanley miller's spark discharge experiments. Chem. Soc. Rev. 42, 2186–2196 (2013).

Article CAS PubMed Google Scholar

Patel, B. H., Percivalle, C., Ritson, D. J., Duffy, C. D. & Sutherland, J. D. Common origins of RNA, protein and lipid precursors in a cyanosulfidic protometabolism. Nat. Chem. 7, 301–307 (2015).

Article CAS PubMed PubMed Central Google Scholar

Wollrab, E. et al. Chemical analysis of a "Miller-type" complex prebiotic broth. Orig. Life Evol. Biosph. 46, 149–169 (2016).

Article CAS PubMed ADS Google Scholar

Becker, S. et al. A high-yielding, strictly regioselective prebiotic purine nucleoside formation pathway. Science 352, 833–836 (2016).

Article CAS PubMed ADS Google Scholar

Becker, S. et al. Unified prebiotically plausible synthesis of pyrimidine and purine RNA ribonucleotides. Science 366, 76–82 (2019).

Article CAS PubMed ADS Google Scholar

Barge, L. M., Flores, E., Baum, M. M., Vandervelde, D. G. & Russell, M. J. Redox and pH gradients drive amino acid synthesis in iron oxyhydroxide mineral systems. Proc. Natl. Acad. Sci. USA 116, 4828 (2019).

Article CAS PubMed PubMed Central ADS Google Scholar

Teichert, J. S., Kruse, F. M. & Trapp, O. Direct prebiotic pathway to DNA nucleosides. Angew. Chem. Int. Ed. 58, 9944–9947 (2019).

Article CAS Google Scholar

Kruse, F. M., Teichert, J. S. & Trapp, O. Prebiotic nucleoside synthesis: The selectivity of simplicity. Chem. Eur. J. 26, 14776–14790 (2020).

Article CAS PubMed Google Scholar

Yadav, M., Kumar, R. & Krishnamurthy, R. Chemistry of abiotic nucleotide synthesis. Chem. Rev. 120, 4766–4805 (2020).

Article CAS PubMed Google Scholar

Canavelli, P., Islam, S. & Powner, M. W. Peptide ligation by chemoselective aminonitrile coupling in water. Nature 571, 546–549 (2019).

Article CAS PubMed Google Scholar

Foden, C. S. et al. Prebiotic synthesis of cysteine peptides that catalyze peptide ligation in neutral water. Science 370, 865 (2020).

Article CAS PubMed ADS Google Scholar

Studier, M. H., Hayatsu, R. & Anders, E. Origin of organic matter in early solar system–I. Hydrocarbons. Geochim. Cosmochim. Acta 32, 151–173 (1968).

Article CAS ADS Google Scholar

Anders, E., Hayatsu, R. & Studier, M. H. Organic compounds in meteorites. Science 182, 781–790 (1973).

Article CAS PubMed ADS Google Scholar

Anders, E., Hayatsu, R. & Studier, M. H. Catalytic reactions in the solar nebula: Implications for interstellar molecules and organic compounds in meteorites. Origins Life 5, 57–67 (1974).

Article CAS ADS Google Scholar

Anders, E., Hayatsu, R. & Studier, M. H. Interstellar molecules: Origin by catalytic reactions on grain surfaces?. Astrophys. J. 192, L101–L105 (1974).

Article CAS ADS Google Scholar

Chyba, C. & Sagan, C. Endogenous production, exogenous delivery and impact-shock synthesis of organic molecules: An inventory for the origins of life. Nature 355, 125–132 (1992).

Article CAS PubMed ADS Google Scholar

Chan, Q. H. S. et al. Organic matter in extraterrestrial water-bearing salt crystals. Sci. Adv. 4, eaao3521 (2018).

Article PubMed PubMed Central ADS Google Scholar

Martins, Z. et al. Extraterrestrial nucleobases in the Murchison meteorite. Earth Plan. Sci. Lett. 270, 130–136 (2008).

Article CAS ADS Google Scholar

Henning, T. & Semenov, D. Chemistry in protoplanetary disks. Chem. Rev. 113, 9016–9042 (2013).

Article CAS PubMed Google Scholar

Albertsson, T., Semenov, D. & Henning, T. Chemodynamical deuterium fractionation in the early solar nebula: The origin of water on earth and in asteroids and comets. Astrophys. J. 784, 39 (2014).

Article ADS Google Scholar

Cleeves, L. I. et al. The ancient heritage of water ice in the solar system. Science 345, 1590–1593 (2014).

Article CAS PubMed ADS Google Scholar

Ferus, M. et al. Formation of nucleobases in a Miller–Urey reducing atmosphere. PNAS 114, 4306–4311 (2017).

Article CAS PubMed PubMed Central ADS Google Scholar

Pearce, B. K. D., Pudritz, R. E., Semenov, D. A. & Henning, T. K. Origin of the RNA world: The fate of nucleobases in warm little ponds. PNAS 114, 11327 (2017).

Article CAS PubMed PubMed Central ADS Google Scholar

Anders, E. Pre-biotic organic matter from comets and asteroids. Nature 342, 255–257 (1989).

Article CAS PubMed ADS Google Scholar

Chyba, C., Thomas, P., Brookshaw, L. & Sagan, C. Cometary delivery of organic molecules to the early earth. Science 249, 366 (1990).

Article CAS PubMed ADS Google Scholar

Zellner, N. E. B., Mccaffrey, V. P. & Butler, J. H. E. Cometary glycolaldehyde as a source of pre-RNA molecules. Astrobiology 20, 1377–1388 (2020).

Article CAS PubMed ADS Google Scholar

Takeuchi, Y. et al. Impact-induced amino acid formation on hadean Earth and noachian Mars. Sci. Rep. 10, 9220 (2020).

Article CAS PubMed PubMed Central ADS Google Scholar

Closs, A. C., Bechtel, M. & Trapp, O. Dynamic exchange of substituents in a prebiotic organocatalyst: Initial steps towards an evolutionary system. Angew. Chem. Int. Ed. 61, e202112563 (2022).

Article CAS Google Scholar

Haas, M., Lamour, S., Christ, S. B. & Trapp, O. Mineral-mediated carbohydrate synthesis by mechanical forces in a primordial geochemical setting. Commun. Chem. 3, 140 (2020).

Article CAS PubMed PubMed Central Google Scholar

McCollom, T. M., Ritter, G. & Simoneit, B. R. T. Lipid synthesis under hydrothermal conditions by Fischer-Tropsch-type reactions. Orig. Life Evol. Biosph. 29, 153–166 (1999).

Article CAS PubMed ADS Google Scholar

Mohammadi, E. et al. Formic acid, a ubiquitous but overlooked component of the early earth atmosphere. Chem. Eur. J. 26, 12075–12080 (2020).

Article CAS PubMed Google Scholar

Andersson, E., Simoneit, B. R. T. & Holm, N. G. Amino acid abundances and stereochemistry in hydrothermally altered sediments from the Juan de Fuca Ridge, northeastern Pacific Ocean. Appl. Geochem. 15, 1169–1190 (2000).

Article CAS PubMed ADS Google Scholar

Varma, S. J., Muchowska, K. B., Chatelain, P. & Moran, J. Native iron reduces CO2 to intermediates and end-products of the acetyl-CoA pathway. Nat. Ecol. Evol. 2, 1019–1024 (2018).

Article PubMed PubMed Central Google Scholar

Nilson, F. P. R. Possible impact of a primordial oil slick on atmospheric and chemical evolution. Orig. Life Evol. Biosph. 32, 247–253 (2002).

Article CAS PubMed ADS Google Scholar

Großmann, Y., Schreiber, U., Mayer, C. & Schmitz, O. Origin of life: aliphatic aldehydes in the earth's crust-remains of prebiotic chemistry? Research Square (2021).

Sekine, Y. et al. An experimental study on Fischer-Tropsch catalysis: Implications for impact phenomena and nebular chemistry. Meteorit. Planet. Sci. 41, 715–729 (2006).

Article CAS ADS Google Scholar

Beyazay, T. et al. Ambient temperature CO2 fixation to pyruvate and subsequently to citramalate over iron and nickel nanoparticles. Nat. Commun. 14, 570 (2023).

Article CAS PubMed PubMed Central ADS Google Scholar

Cleaves, H. J., Chalmers, J. H., Lazcano, A., Miller, S. L. & Bada, J. L. A reassessment of prebiotic organic synthesis in neutral planetary atmospheres. Orig. Life Evol. Biosph. 38, 105–115 (2008).

Article CAS PubMed ADS Google Scholar

Rodriguez, L. E. et al. Nitrogen heterocycles form peptide nucleic acid precursors in complex prebiotic mixtures. Sci. Rep. 9, 9281. https://doi.org/10.1038/s41598-019-45310-z (2019).

Article CAS PubMed PubMed Central ADS Google Scholar

Zahnle, K., Schaefer, L. & Fegley, B. Earth's earliest atmospheres. Cold Spring Harb. Perspect. Biol. 2, a004895 (2010).

Article CAS PubMed PubMed Central Google Scholar

Martin, W., Baross, J., Kelley, D. & Russell, M. J. Hydrothermal vents and the origin of life. Nat. Rev. Microbiol. 6, 805–814. https://doi.org/10.1038/nrmicro1991 (2008).

Article CAS PubMed Google Scholar

Herschy, B. et al. An origin-of-life reactor to simulate alkaline hydrothermal vents. J. Mol. Evol. 79, 213–227. https://doi.org/10.1007/s00239-014-9658-4 (2014).

Article CAS PubMed PubMed Central ADS Google Scholar

Kitadai, N. & Maruyama, S. Origins of building blocks of life: A review. Geosci. Front. 9, 1117–1153 (2018).

Article CAS Google Scholar

Mulkidjanian, A. Y., Bychkov, A. Y., Dibrova, D. V., Galperin, M. Y. & Koonin, E. V. Origin of first cells at terrestrial, anoxic geothermal fields. Proc. Natl. Acad. Sci. USA 109, E82–E830. https://doi.org/10.1073/pnas.111777410 (2012).

Article Google Scholar

Benner, S. A. et al. When did life likely emerge on earth in an RNA-first process?. ChemSystemsChem 2, e1900035 (2020).

Article CAS Google Scholar

Popova, O. P. et al. Chelyabinsk airburst, damage assessment, meteorite recovery, and characterization. Science 342, 1069 (2013).

Article CAS PubMed ADS Google Scholar

Baldwin, B. & Sheaffer, Y. Ablation and breakup of large meteoroids during atmospheric entry. J. Geophys. Res. 76, 4653–4668 (1971).

Article ADS Google Scholar

Dry, M. E. The Fischer-Tropsch process: 1950–2000. Catal. Today 71, 227–241 (2002).

Article CAS Google Scholar

Kasting, J. Earth's early atmosphere. Science 259, 920 (1993).

Article CAS PubMed ADS Google Scholar

Furukawa, Y., Samejima, T., Nakazawa, H. & Kakegawa, T. Experimental investigation of reduced volatile formation by high-temperature interactions among meteorite constituent materials, water, and nitrogen. Icarus 231, 77–82 (2014).

Article CAS ADS Google Scholar

Vukojevic, S., Trapp, O., Grunwaldt, J.-D., Kiener, C. & Schüth, F. Quasi-homogeneous methanol synthesis over highly active copper nanoparticles. Angew. Chem. Int. Ed. 44, 7978–7981 (2005).

Article CAS Google Scholar

Hashimoto, G. L., Abe, Y. & Sugita, S. The chemical composition of the early terrestrial atmosphere: Formation of a reducing atmosphere from CI-like material. J. Geophys. Res. 112, E05010 (2007).

ADS Google Scholar

Zahnle, K. J., Lupu, R., Catling, D. C. & Wogan, N. Creation and evolution of impact-generated reduced atmospheres of early earth. Planet. Sci. J. 1, 11 (2020).

Article Google Scholar

Kress, M. E. & Mckay, C. P. Formation of methane in comet impacts: Implications for Earth, Mars, and Titan. Icarus 168, 475–483 (2004).

Article CAS ADS Google Scholar

Sekine, Y., Sugita, S., Kadono, T. & Matsui, T. Methane production by large iron meteorite impacts on early earth. J. Geophys. Res. 108, 5070 (2003).

Article Google Scholar

Hattori, Y., Kinjo, M., Ishigami, M. & Nagano, K. Formation of amino acids from CH4-rich or CO2-rich model atmosphere. Origins life 14, 145–150 (1984).

Article CAS ADS Google Scholar

Strecker, A. Ueber die künstliche Bildung der Milchsäure und einen neuen, dem Glycocoll homologen Körper. Justus Liebigs Ann. Chem. 75, 27–45 (1850).

Article Google Scholar

Bar-On, Y. M., Phillips, R. & Milo, R. The biomass distribution on earth. PNAS 115, 6506 (2018).

Article CAS PubMed PubMed Central ADS Google Scholar

Siebert, M., Storch, G. & Trapp, O. A fast and reliable screening setup for homogeneous catalysis with gaseous reactants at extreme temperatures and pressures. Org. Process Res. Dev. 24, 1304–1309 (2020).

Article CAS Google Scholar

Download references

We thank the Mineralogische Staatssammlung, Munich, for providing samples of the Muonionalusta meteorite. We thank Dr. Steffen Schmidt for SEM measurements, Dr. Jan-Felix Scholtes and Dr. Kai Kohler for instrumental support, and Dr. Laurens Peters for data processing/visualization. This research made use of NASA's Astrophysics Data System.

Open Access funding enabled and organized by Projekt DEAL. Max-Planck Society, Max-Planck-Fellow Research Group ‘Origins of Life’ (OT). Germany's Excellence Strategy, ORIGINS, EXC-2094-390783311 (OT). DFG/German Research Foundation, Project-ID 364653263-TRR 235, Emergence of Life (OT). Volkswagen Stiftung, Initiating Molecular Life (OT). German Research Foundation, Priority Program 1833 ‘Building a Habitable Earth’, grant SE 1962/6-1 (DS).

Department of Chemistry, Ludwig-Maximilians-Universität München, Butenandtstr. 5-13, 81377, Munich, Germany

Sophia Peters, Dmitry A. Semenov & Oliver Trapp

Max Planck Institute for Astronomy, Königstuhl 17, 69117, Heidelberg, Germany

Sophia Peters, Dmitry A. Semenov & Oliver Trapp

Mineralogische Staatssammlung München, Theresienstr. 41, 80333, Munich, Germany

Rupert Hochleitner

You can also search for this author in PubMed Google Scholar

You can also search for this author in PubMed Google Scholar

You can also search for this author in PubMed Google Scholar

You can also search for this author in PubMed Google Scholar

Conceptualization: S.P., D.S., O.T. Methodology: S.P., O.T. Experiments: S.P. Meteorite samples: R.H. Analysis: S.P., D.S., O.T. Visualization: S.P., D.S., O.T. Funding acquisition: O.T. Project administration: O.T. Supervision: O.T. Writing—original draft: D.S., O.T., S.P., R.H.

Correspondence to Oliver Trapp.

The authors declare no competing interests.

Springer Nature remains neutral with regard to jurisdictional claims in published maps and institutional affiliations.

Open Access This article is licensed under a Creative Commons Attribution 4.0 International License, which permits use, sharing, adaptation, distribution and reproduction in any medium or format, as long as you give appropriate credit to the original author(s) and the source, provide a link to the Creative Commons licence, and indicate if changes were made. The images or other third party material in this article are included in the article's Creative Commons licence, unless indicated otherwise in a credit line to the material. If material is not included in the article's Creative Commons licence and your intended use is not permitted by statutory regulation or exceeds the permitted use, you will need to obtain permission directly from the copyright holder. To view a copy of this licence, visit http://creativecommons.org/licenses/by/4.0/.

Reprints and Permissions

Peters, S., Semenov, D.A., Hochleitner, R. et al. Synthesis of prebiotic organics from CO2 by catalysis with meteoritic and volcanic particles. Sci Rep 13, 6843 (2023). https://doi.org/10.1038/s41598-023-33741-8

Download citation

Received: 20 August 2022

Accepted: 18 April 2023

Published: 25 May 2023

DOI: https://doi.org/10.1038/s41598-023-33741-8

Anyone you share the following link with will be able to read this content:

Sorry, a shareable link is not currently available for this article.

Provided by the Springer Nature SharedIt content-sharing initiative

By submitting a comment you agree to abide by our Terms and Community Guidelines. If you find something abusive or that does not comply with our terms or guidelines please flag it as inappropriate.