Abstract
In order to investigate the variability of helium degassing in continental regions, its release from rocks and emission into the atmosphere, here we studied the degassing of volatiles in a seismically active region of northern Italy (MwMAX = 6) at the Nirano-Regnano mud volcanic system. The emitted gases in the study area are CH4–dominated and it is the carrier for helium (He) transfer through the crust. Carbon and He isotopes unequivocally indicate that crustal-derived fluids dominate these systems. An high-resolution 3-dimensional reconstruction of the gas reservoirs feeding the observed gas emissions at the surface permits to estimate the amount of He stored in the natural reservoirs. Our study demonstrated that the in-situ production of 4He in the crust and a long-lasting diffusion through the crust are not the main processes that rule the He degassing in the region. Furthermore, we demonstrated that micro-fracturation due to the field of stress that generates the local seismicity increases the release of He from the rocks and can sustain the excess of He in the natural reservoirs respect to the steady-state diffusive degassing. These results prove that (1) the transport of volatiles through the crust can be episodic as function of rock deformation and seismicity and (2) He can be used to highlight changes in the stress field and related earthquakes.
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Introduction
Large-scale vertical transport of fluids through the continental crust is not always dominated by steady-state diffusion processes but it can be also advective and episodic1,2,3,4. It has been recognized that in continental regions volatiles degassing mainly occurs in areas characterised by extensional tectonic and often coincides with seismically active zones5. This correspondence has been related to the enhanced permeability of the extensional tectonic discontinuities6. However, it has been also observed that variations of the volatiles degassing rate are earthquake-related, and are frequently post-seismic7,8,9. Thus, fluids geochemistry provides evidences of the episodic large-scale transport of volatiles. Even if the flux of the major natural gases (i.e., CO2) towards the atmosphere is measured at surface it is difficult to constrain the processes controlling its variability because fluids are often reactive (e.g. water-gas-rock interaction) and several processes work concomitantly during the fluids transfer through the crust10. Therefore, in order to figure out the relationships between fluids and earthquakes generation processes, at the base of a possible modern earthquake forecast approach, it is fundamental to unravel the processes causing and regulating the fluids flux and chemistry.
Because of their chemical properties, noble gases contribute to retrace the degassing history of the Earth and the evolution of the atmosphere11,12,13,14,15. Furthermore, for investigating the mechanism controlling the transport of fluids in continental region, He, the lightest noble gas, is largely used because its sources (air, crust and mantle) are well resolvable by the use of the isotopic ratio (3He/4He)14. In fact, He is characterized by two isotopes: 3He, which is a primordial component and it is mainly stored in the mantle, and 4He that is continuously produced by the U and Th decay, so its amount stored into minerals and rocks progressively increases over geological time. Melting and volatiles release from magma are the main processes that control He outgassing from the mantle. Instead, degassing of He produced in the crust occurs under different conditions mainly consisting of two stages acting at different scales: (a) the release of the volatiles from the mineral/rocks; (b) their transport towards the surface13. It is recognized that the crustal fluids are dominated by 4He, on the contrary, mantle-derived fluids show an excess of 3He (MORB mantle 3He/4He is 8 ± 1 Ra, where Ra is the isotopic ratio in atmosphere, 1.382 ± 0.005 × 10−6)16,17 respect to the crustal-derived fluids. He is also found in considerable quantities in some natural-gas reservoirs, where it can remain stored for millions of years18,19. The continental 4He degassing shows spatial and temporal variability at regional scale1, so it is an efficient tool for evaluating the role of tectonics in enhancing the crustal scale mass transport and decipherer the mechanisms of the transfer of volatiles1,20,21,22,23. Changes of physical properties of rocks can modify the release and transfer of volatiles through the crust24. For instance, rock deformation produces new (micro) fractures enhancing the release of the trapped volatiles (e.g., He) and as a consequence the fraction of volatiles released from the rocks during deformation, increases with the rock volume changes (dilatancy processes). However, even if some experimental studies show the existence of a direct link between rock deformation/fracturation and the release of He25,26, there are only a few of applications in natural systems21,27,28. In this study, we investigated the origin and processes controlling the transfer of He through the crust in a seismically active region of the Northern Apennines (Fig. 1), to establish the possible contribution of the tectonic activity in enhancing the release of volatiles accumulated in the rock over time and more specifically, how earthquakes occurrence may contribute to the episodic volatiles degassing. To this end we collect fluids from mud volcanoes (Fig. 1a,b) and we analyse their chemical and isotopic composition (He, δ13C-CO2, δ13C-CH4, δ2H-CH4) to figure out the origin of the outgassing volatiles and the process controlling the crustal degassing. Once verified that the volatiles comes from deep natural reservoirs, we reconstructed the reservoirs volume to estimate the total amount of He stored in these natural traps. The balance between input and output of He in the reservoirs allow us to unravel the processes that control the crustal degassing from He production until its transfer towards the surface, giving also insights to the role and modality of tectonic and seismicity in the vertical transferring of fluids (diffusive vs. advective and episodic).
Results
In the northern Apennines (Italy) the mud volcanoes are distributed along the external sector of the fold-and-thrust belt (Fig. 1).
This region is considered a reference area to study fluid venting processes in an active fold-and-thrust belt29 and the fluids geochemistry is used as a potential indicator of impending local earthquakes30. The seismicity is concentrated in the crust and at local scale the maximum magnitude is 6.0 (https://emidius.mi.ingv.it). Furthermore, it is recognized that the fluid output from the mud volcanoes increased just after the earthquakes9,31,32,33.
Previous investigations highlighted that the gases emitted from the mud volcanoes are CH4-rich34 and they are fed by two reservoirs that are strongly different in dimension and vertically separated35. At the regional scale, the studied mud volcanoes are localised at the top of the anticlines (Fig. 1a), particularly in joints perpendicular to the axis of the fold, where the impermeable cover allows pore fluid pressure build-up (close to lithostatic magnitudes)35. Mud volcanoes are placed along active normal faults (Fig. 2a), allowing a vertical migration of CH4 coming from deep sources (>3–6 km)36.
In this region mud volcanism can be potentially triggered by fault failure cycles and the overpressured fluids released during faulting35. Furthermore, the relatively quiescent but continuous activity of these mud volcanoes could instead reflect a short-lived leakage of overpressured fluids along permeable fractures/faults. We are therefore in the presence of a study-case site to investigate the mechanisms of fluid transfer through the crust and the possible relationships between degassing of crustal fluids and rocks deformation and seismicity.
Fluids geochemistry
We collected gas samples from four different mud volcanoes areas (Fig. 1): Nirano, Montegibbio, Regnano and Casola. Nirano - Montegibbio sites are located 3.5 km apart, while Regnano - Casola only 2.0 km. Hereafter, we named Nirano-Montegibbio sites as the Nirano system and Regnano-Casola sites as the Regnano system. We analysed the fluids for defining the gas chemistry (He, H2, O2, N2, CO, CH4, CO2 and C2H6) and the isotopic composition of He (3He/4He), 20Ne, C of both CH4 and CO2 and H of CH4 (Table 1).
According to previous investigations36,37,38 the outgassing fluids from the Nirano and Regnano systems are CH4 dominated (96.7–98.3%). CO2 is up to 1.04%, O2 and N2 up to 0.09% and 1.27% respectively; He is in traces (up to 23 ppm vol.). The low concentrations of O2 and N2 indicate that the collected gases suffer low air contaminations (Fig. 3a).
The He isotopic ratios are 0.01–0.03 Ra, that is the typical range of the crustal radiogenic He (Fig. 3b). The 4He/20Ne ratios in the collected fluids are from 59.4 to 636.5 and these values are more than 2 order of magnitude higher than the same ratio in air (4He/20NeAIR = 0.318)14 supporting the low atmospheric component in the gases from the Nirano and Regnano systems (Fig. 3a,b). Hence, the outgassing He from the mud volcanoes systems is dominated by radiogenic 4He that is produced by U and Th decay in the crust14. The C and H isotopic composition of CH4 is in a good agreement with previous results highlighting the thermogenic nature of CH4 (Fig. 3c and Table 1)37,38,39. Here we report the first data of C and H isotopes of CH4 in gases from Casola and Montegibbio sites, indicating a unique origin of CH4 emitted from these mud volcanoes systems (Fig. 3c and Table 1). The carbon isotopic composition of CO2 in all the studied fluids is from +13.8‰ to +18.6‰ and according to Milkov and Etiope (2018)40 these values coupled to the isotopic composition of CH4 indicate that CO2 is of thermogenic origin (Table 1 and Fig. 3c,d). These results are in a good agreement with those from previous investigations36 that highlighted (1) the thermogenic nature of pristine methane in the deep reservoirs, (2) an origin of CH4 in crustal layers deeper than the reservoirs (>3–6 km) and (3) a vertical migration of CH4 towards the surface. Considering the main component in the collected gases is CH4 (~98%) and the average CH4/4He ratio in the emitted gases is ~46000 we computed the amount of 4He in the two reservoirs by using the total amount of gases into the reservoirs, between 4.00 × 1011 and 4.50 × 1011 standard cubic meter (SCM) for the main reservoir, and 5.68 × 108 SCM for the shallow reservoir (Supplementary Information: gas reserves). So, the amount of 4He into the shallower reservoir and deep reservoirs are 4.90 × 105 moles and 3.60 × 108–4.20 × 108 moles respectively. The amount of 4He in the shallow reservoir is three order of magnitude lower that the amount in the deep reservoir (lower than 1% of 4He amount in the deep reservoir), so it can be considered negligible (Table 2).
He degassing
There have been many consistent estimates of the flux of 4He from the continental crust based on calculations of in situ production and steady-state release to the atmosphere by using the U and Th content in rocks, crustal thickness and total release of 4He. These calculations yield a crustal degassing flux of 4He of the order 3.3 ± 0.5 × 1010 (atoms × m−2 × s−1)1,15,41. However, experimental works highlighted that the release of volatiles increases in volume of rock in an active stress field, which supports that the 4He degassing through the crust can be episodic in active tectonic areas26,42,43. Mechanical deformation and rocks failure can break (or crack) mineral grains, causing pervasive micro-fracturing and dilation. Consequently, the rocks can increase porosities from 20% to as high as 400% prior to failure44, open new micro-fracture surfaces, and eventually cause macroscopic failure and fracture of rocks45. These processes lead to a release of volatiles (e.g. He) previously trapped within mineral grains along fracture networks46,47 and the pore fluids transport these volatiles through the crust. Here we firstly investigate if a steady state degassing is the main process that controlled the 4He flux to the reservoirs below the Regnano and Nirano systems over time.
He degassing: Steady-state conditions
The local stratigraphy and tectonic evolution indicates that the age of formation of the anticline hosting the main gas reservoirs below the Regnano and Nirano systems goes from 1.8 to 4.5 Ma. Over a million-year the flux of 4He through the Earth’s crust to the atmosphere is comparable to the net in situ production (in steady state condition), in 30–40 km of crustal thickness48. In order to assess if the 4He production in the crust and the successive migration to the natural reservoirs feeding the Nirano and Regnano systems can justify the amount of He that is stored in the reservoirs, we used a mass balance approach49:
where 4He represents the amount of radiogenic helium (moles) in the reservoir at time t. It includes three input and two outputs terms. Among the input terms, 4HeInitial is the amount of 4He that is in the reservoir at time t-zero, 4HeInsitu the amount of radiogenic 4He produced in the reservoir-rocks volume since its formation (from 1.8 to 4.5 Ma), 4HeExternal flux is the flux from the crust below the reservoirs. 4HeLeak−d and 4HeLeak−mv are the two terms of outputs: 4HeLeak−d is the He lost by diffusion from the main reservoir over time and it is from 4.37 × 105 mol to 1.09 × 106 for a t of 1.8 Ma and 4.5 Ma respectively (Methods; gas reserves). It is up to 0.36% of the total volume of He. The second one, 4HeLeak−mv, is the He leak due to advection, and we assume that is the He emitted from the mud volcanoes. We extrapolated the current He outgassing from mud volcanoes, to the past 104 years, in this time we have considered the continuous degassing (about 95 mol/y), and the possible paroxysmal activity as follows: “normal” eruption (10 times the continuous, every year) and “strong” eruption (100 times the continuous, once every 30 years)36,50,51. The result is that up to 3.8 × 107 mol of He can by lost from mud volcanoes. Nonetheless these two outputs are less than about 10% of the amount of He stored in the main reservoir, does not entail any change in the conclusions, so it is reasonable to neglect their contribution in Eq. 1 which means an underestimation of the He present in the reservoir.
To compute 4HeInsitu and 4HeExternal flux we used literature data for the abundances of U and Th and for crust thickness. Hence, we based our calculations on the U and Th amounts for a Regional Refined Reference Model and the Global Refined Reference Model (Table 3)52.
The in-situ production of 4He is computed on the basis of the approach proposed by Zhou and Ballentine53:
where ρ is the rock density in g/cm3 (2.21 g/cm3), ∧ a parameter defining the efficiency of the transfer from the rock matrix into the gas phase, ϕ is the porosity of reservoir (fraction), α the source function of radioactive production of 4He in the rock matrix (mol 4He/grock/year), V the volume of the gas reservoir (cm3) and t the formation time of gas reservoirs (years). Since the process of 4He released from a host mineral is short compared to the geologic age13 ∧ can be regarded as being equal to 1. α, according to the U and Th decay equations, can be calculated using the following equation54:
where U and Th represent the concentrations of U and Th in rocks that host the reservoirs and are expressed in ppm. The accumulation rate of the in situ produced 4He of gas reservoirs is expressed as (mol/y):
The in-situ production of 4He is 0.11 ± 0.02 mol/y and 0.30 ± 0.02 mol/yr (in Regional and Global model respectively).
The external flux of 4He is computed by using the method in Zhou and Ballentine53:
where S is the gas-bearing area of a reservoir (cm2), t the gas reservoir formation time (years) and \({{\rm{q}}}_{{}^{4}He}^{c}\) the average external crustal 4He flux (mol 4He/cm2/year). \({{\rm{q}}}_{{}^{4}He}^{c}\) can be calculated as:
where ρ is the average crust density in g/cm3 (2.80 g/cm3)55 and H is the crust thickness in cm (3.2 × 106 cm, Lavecchia et al. 2003)56.
The external flux of 4He to the two reservoirs is 37.53 ± 12.12 mol/y and 54.54 ± 5.86 mol/y (in Regional and Global model respectively, Fig. 4).
Considering these values of 4He input in the reservoir, the total amount of 4He that can be accumulated into the trap in a time going from 1.8 and 4.5 Myr, varies from 6.7 × 107 mol to 2.5 × 108 mol, respectively. These values are lower than the amount of He in the reservoir that we computed by using the volumetric method (from 3.64 × 108 mol to 4.12 × 108 mol, Table 3). So, production of 4He from the whole crust below the main reservoir and its successive transfer by diffusion processes, cannot support the amount of He stored into the reservoirs (Fig. 5).
If we consider a steady-state diffusion model to explain the excess of 4He in the two reservoirs we need to invoke a volume of 4He-productive crust from 1.5 to 6.2 times larger than that below the trap (~1323 km3). Considering that previous investigations38 highlighted that the source of CH4 is in deep crustal layers (>3–6 km) and CH4 vertically migrated towards the natural reservoirs it is reasonable that processes of volatiles migration different from the steady-state diffusion occurred below the investigated mud volcanoes systems.
4He flux: Episodic degassing and active tectonic
The release of volatiles from rocks increases as effect of dilatancy and in regions affected by active tectonic, the flux of 4He through the crust should be higher than that in un-deforming areas where it is reasonable to assume that a diffusive steady-state transport system is acting. Our calculations show that 4He in the natural reservoirs is in excess respect to a steady-state whole crust degassing. As a result, in the main reservoir, there are between 1.2 × 108 and 3.5 × 108 moles in excess of the 4He produced in the crust below the main reservoir plus the 4HeInsitu.
Considering that the region is tectonically active and two main systems of active faults cross cut the deep reservoir (Fig. 2c and Methods: Geological setting), here we investigate if micro-fracturing can sustain the excess of 4He in the reservoirs. The release of 4He from rock, which are affected by dilatancy, is from 10 to 104 times higher than that in un-deformed rock26, so the release of 4He from a deforming fault damage zone is significantly higher if compared to the one of a tectonically undisturbed rock volume (Figs. 6 and S1).
The volume of the damage zones of the reservoir-related faults (from 0.015 km3 to 0.088 km3; Fig. 2) releases an amount of He that matches the excess of He in the reservoirs if the release of 4He is 104 times higher than that produces by pure diffusion process occurring within an un-deformed rock volume (Figs. 6 and S1). However, the high flux of volatiles from rocks as effect of dilatancy is not constant over time and it decreases in a scale of ka26. It means that in order to produce a continuous flux of volatiles high enough to justify the amount of 4He presumed to be into the reservoirs, the stress field has to be constantly active since the reservoir formation age. This result shows that the active regional tectonic could substantially contribute to enhance the 4He flux within the reservoir and that it can be an additional process to sustain the amount of 4He stored in the trap (Figs. 7 and S2). This implies that also the seismic activity is occurring since the origin of the gas traps.
Seismicity and degassing
We explored the hypothesis that the excess of He in the reservoirs may be due the occurrence of local earthquakes producing micro-fractures in crustal layers. Following the approach used by Sano et al.28, which link the magnitude of an earthquake to the volume of rock affected by deformation and the related release of 4He, we used the local (historical and instrumental) earthquakes activity as a proxy to calculate the amount of He released by the variation of the rock volume induced by each seismic event. We used the INGV database, covering the 1986–2018 time period (http://cnt.rm.ingv.it) for the instrumental earthquakes and the historical earthquakes catalogue (https://emidius.mi.ingv.it), covering the period 1501–1997, to compute the seismic energy released by the earthquakes located below the Nirano and Regnano systems. Moreover, we also extended the catalogue to the past (in terms of geological times), by assuming the same level of seismic energy release with time, from now up to the trap formation age. The considered events occurred at depths ranging between 5 km and 31 km and in 15 km wide sector along the axis of the anticline connecting Regnano to Nirano. We firstly converted the different types of magnitude reported in the catalogues (ML and Md) in moment magnitude (Mw). For the conversion from ML to Mw, we used the coefficients proposed by Castello et al.57. While we converted the Md to Mw by using the coefficients proposed by Selvaggi et al.58. We then computed the annual average of released energy (by using ZMAP computer code) for the analysis of seismic recurrences. The annual average of released energy is about 5.48 × 1016 ergs/y, which corresponds to one earthquake of magnitude equal to 3.3 per year. Thus, we computed the average volume of rock deformed by the earthquakes per year28,59 by using the relationship:
where V and M are the volume of rock affected by seismicity (km3) and the moment magnitude, respectively. These values correspond to a volume of deformed rock of 5.13 km3 per year that is higher than the volume of the faults damage zones. The amount of He released from this volume are between 7.09 × 10−2 and 3.58 × 10−2 mol/y with a Regional or Global U and Th contents in the rock respectively. So, an increase of 3 orders of magnitude of the He released by the volume of deformed rocks, due to dilatancy26,43, is still consistent to the amount of He estimated in the reservoirs (Figs. 7 and S2).
This result clearly indicates that the volume of deformed rock by stress field of the seismicity must be larger that the volume of the damage zone of the reservoir-related faults.
Conclusion
Our results show that the field of stress associated to the seismicity generated a release of 4He from rock supporting the amount of 4He that accumulated in the natural reservoirs since their formation (1.8–4.5 Ma). These results demonstrate that in tectonically active regions, the crustal 4He degassing can episodically occur and powered as an advective process by seismo-genetic processes. In fact, in the studied area the 4He flux through the crust towards the atmosphere is higher than that due to a steady-state diffusive degassing and this excess can be due to the local seismicity. Considering the recognized link between rock deformation/fracturation and He degassing, the monitoring of the He flux in seismically active regions can potentially provide evidences of a modification of the field of stress due to the active tectonics, so the He can provides information to a better knowledge of the seismo-genetic processes at regional scale. However, our study shows that natural reservoirs accumulate deep sourced volatiles and the natural traps work as a sponge over time by absorbing the signal transferred towards the surface by the volatiles coming from deeper than the reservoirs, so these volatiles do not quickly reach Earth surface. These results well fit with the evidences that the increase of the activity from the mud volcanoes or vents because of earthquake is essentially post-seismic, in the sense that it occurs as a consequence of earthquakes7,60 and generally, no geochemical variations are recognized before. Finally, mud volcanoes are surely preferential sites for studying the relationships between fluids and seismicity, however for using He and other volatiles to investigate the genesis of earthquakes it is fundamental to have a model of fluids circulation and its storage into the crust together with an high frequency monitoring of the He that outgases at the surface. The seismogenesis is a dynamic process of ongoing rock deformation until to the fracturation, so even if fluids are directly involved in these processes nevertheless the effects of rock deformation can be also masked or reach the surface in delay.
Methods
Analytical procedures
Gas samples were collected in Pyrex bottles with vacuum valves at both ends, taking care to prevent air contamination, and these were analysed in 10 days from their sampling. Gas samples have been analysed in the laboratories of the Istituto Nazionale di Geofisica e Vulcanologia, sezione di Palermo. The chemical composition of He, H2, O2, N2, CO, CH4, CO2 and C2H6 has been measured by a Perkin Elmer Clarus 500 gas chromatograph equipped with a 3.5-m Carboxen 1000 column and double detector (hot-wire detector and flame ionization detector), with analytical errors of <3%. Analytical precision for GC analyses is better than ±5% for trace gases and ±10% for alkanes. 3He, 4He and 20Ne and the 4He/20Ne ratios were determined by separately admitting He and Ne into a split flight tube mass spectrometer (GVI-Helix SFT), after standard purification procedures61. 3He/4He ratio is expressed as R/Ra (being R the 3He/4He ratio of the sample, and Ra the 3He/4He ratio of air, 1.39 × 10−6).
The analytical error is generally below 0.3%. The R/Ra values were corrected for the atmospheric contamination basing on the 4He/20Ne ratio62 and reported as Rc/Ra (Table 1)63. The C isotope composition of CO2 (expressed as δ13C‰ vs. V-PDB) was determined using a Thermo (Finningan) Delta Plus XP CF-IRMS, connected to a Trace GC gas chromatograph and a Thermo (Finningan) GC/C III interface63,64. The gas chromatograph, equipped with a Poraplot-Q column (length 30 m, i.d. 0.32 mm), kept at a constant temperature of 50 °C, uses He as the carrier gas. The analytical uncertainty was ±0.1‰. Carbon and hydrogen isotopes of CH4 were carried out on the same equipment. GC III combustion interface was used to produce carbon dioxide from CH465. GC-TC interface provides on-line high-temperature methane conversion into hydrogen suitable for isotope analyses. Typical reproducibility (1σ) for δ13C-CH4 and δD-CH4 measurements is better than 0.2‰ and 2.5‰ respectively66.
Gas reserves computations
The classic approach to estimate the gas reserves stored in a natural reservoir (Q) is based on a volumetric method67 where the computed values of the gases volume are statistically considered the “best-estimate” value68. Here we applied this approach to compute the total amount of gas that is stored into the deep and shallow reservoirs (Table 2).
The total gas amount in the reservoir is computed by using the equation69:
where: G.B.V. = Gross Bulk Volume represents the gross volume of mineralized rock (inclusive of any clayey and/or compact horizons that do not contribute to production) (9.5 × 109 m3 and 2.7 × 108 m3 the deep and the shallow gas reservoirs); Net/Gross = Ratio between the rock thickness that actually contributes to the production and the gross thickness of rock (1 for this work); \(\varnothing \) = Average porosity of the reservoir (fraction, 15%); Sw = Average water saturation of the “reservoir” (fraction) o Volume fraction of porosity filled with interstitial water70; So = Oil saturation (between 0 and 10%); Bg = “Formation Volume Factor” that is used to express the volume of hydrocarbons originally in place at the “standard” surface conditions, i.e. at a pressure of 1 atm and at a temperature of 20 °C. The Sw it is equal to 15%, calculated with Timur 196871. Where k is the permeability, equal to 80 mD.
The Formation Volume Factor is given by the ratio of the volume of gas to the conditions of the reservoir and the volume of the gas to the standard conditions. Mathematically:
where, Psc, Tsc, Zsc, represent surface (pressure, temperature and compressibility factor) conditions while, Prc, Trc e Zsc, are the conditions (pressure, temperature and compressibility factor) in the reservoir. The compressibility factor, Z, is calculated by using the approach in Piper and Corredor (1993)72. Therefore, the reverse of the Formation Volume Factor is equal to 1/Bg = 371.19 SCM/ResCM, i.e. 1 m3 of pore volume under the reservoir conditions contains 1/Bg m3 of gas under standard conditions. Table 2 shows the total gas amount in the two reservoirs, Q: (1) from 1.66 × 1013 moles to 1.87 × 1013 moles for the deep reservoir (depth 1850–2600 m) at \({{\rm{P}}}_{rc}^{Litho}\) = 49 MPa, Trc = 327.15 °K and So from 0 to 10% and (2) 2.36 × 1010 moles for the shallow trap (depth 400–1000 m) at d Trc = 295.75 °K, \({{\rm{P}}}_{rc}^{Litho}\) = 4 MPa So = 0.0. The lithostatic pressure were calculated taking into account the mean thicknesses and densities of the crustal layers and the value of g.
Helium lost by diffusion
The helium lost by diffusion it was calculated by one-dimensional steady-state diffusion model was used to quantify He loss in gas reservoirs using the formula in Liu et al.49:
where: D is the diffusion coefficient of He (2 × 10−6 cm2/s)49; Z is the buried depth of reservoir, the middle point of deeper reservoir in this case (2225 m); Q is the total gas amount in the reservoir is computed by using the Eq. (8); C(t) is the 4He concentration at time t in %v; PNC is the normal atmosphere (1 atm); TNC is normal temperature (273 °K); TRC is the reservoir condition temperature (327.15 °K); G.B.V is the gross bulk volume in (9.49 × 1011 cm3); ϕ s the porosity (%); \({{\rm{K}}}_{{H}_{2}O}\) is the is Henry’s constant calculated from the solubility model of noble gases in the water (approximately 2500)24.
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Acknowledgements
This work was supported by Istituto Nazionale di Geofisica e Vulcanologia, Grant FSE (Fondi Sociali Europei) and FISR (Fondo Integrativo Speciale per la Ricerca). A special thanks go to Dr. Giovanni Martinelli for providing us logistic support and collaboration into the collection of gases. We thank also INGV, Sezione di Palermo, for supplying the analytical support of all the analysis (gases chemistry, noble-gas and stable isotopes).
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D.B., A.C. and R.F. designed the paper. A.C. collected the gases. D.B. developed all the calculations. D.B., A.C. and L.C. investigated the relationships between the earthquakes magnitudo, rock fracturation and volatiles release. A.S. and M.G.M. provided all the geological information and the 3D reconstruction of the reservoirs. All the authors contributed in elaborating the data and writing the paper.
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Buttitta, D., Caracausi, A., Chiaraluce, L. et al. Continental degassing of helium in an active tectonic setting (northern Italy): the role of seismicity. Sci Rep 10, 162 (2020). https://doi.org/10.1038/s41598-019-55678-7
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DOI: https://doi.org/10.1038/s41598-019-55678-7
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