2020
DOI: 10.1029/2019gc008865
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Radiogenic Power and Geoneutrino Luminosity of the Earth and Other Terrestrial Bodies Through Time

Abstract: We report the Earth's rate of radiogenic heat production and (anti)neutrino luminosity from geologically relevant short‐lived radionuclides (SLR) and long‐lived radionuclides (LLR) using decay constants from the geological community, updated nuclear physics parameters, and calculations of the β spectra. We track the time evolution of the radiogenic power and luminosity of the Earth over the last 4.57 billion years, assuming an absolute abundance for the refractory elements in the silicate Earth and key volatil… Show more

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Cited by 22 publications
(28 citation statements)
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References 91 publications
(154 reference statements)
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“…Production rates ν and ν for 40 K are higher than previous reports because of the recently updated 40 K's half-life T 1/2 estimation [14], which is, respectively, 2.6%, 2.3% and 1.1% lower than what reported in [15][16][17] *The 238 U decay chain contains β − decays (e.g., 210 Tl) producing geoneutrinos with energies > 3.26 MeV. Historically, these are not considered for geoneutrino analyses because of their low intensities, impossible to observe through current experiments…”
Section: What Are Geoneutrinos?contrasting
confidence: 62%
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“…Production rates ν and ν for 40 K are higher than previous reports because of the recently updated 40 K's half-life T 1/2 estimation [14], which is, respectively, 2.6%, 2.3% and 1.1% lower than what reported in [15][16][17] *The 238 U decay chain contains β − decays (e.g., 210 Tl) producing geoneutrinos with energies > 3.26 MeV. Historically, these are not considered for geoneutrino analyses because of their low intensities, impossible to observe through current experiments…”
Section: What Are Geoneutrinos?contrasting
confidence: 62%
“…The radiogenic heat production inside the Earth is due to the energy released by the decays of radioactive nuclides which indeed play a starring role in the comprehension of geodynamical processes. Neglecting a fractional contribution coming from rare radionuclides ( 87 Rb, 138 La, 147 Sm, 176 Lu, 187 Re and 190 Pt), the 99.5% of the present Earth's radiogenic heat production is due to the decay (or the decay chains) of 40 K, 232 Th, 235 U and 238 U, long-lived radionuclides (T 1/2 > 10 8 years) created at the time of the Solar System formation and still extant now [121]. Due to their different halflives, the relative amounts of heat-producing nuclides, and in turn their contribution to radiogenic budget, changed with time.…”
Section: Radiogenic Heat Production (H)mentioning
confidence: 99%
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“…g Desch et al (2018). h Heat production in the bulk silicate planets are calculated from chondritic (Al/Th) mass = 2.81×10 5 and (Th/U) mass = 3.7, planetary (K/Th) mass = 7000, 3700, and 5300 for Mercury, Earth, and Mars, respectively (Peplowski et al 2011;Arevalo Jr. et al 2009;Taylor et al 2006), and an equation from McDonough et al (2020). pW = 10 −12 W; TW = 10 12 W.…”
Section: Composition Of the Terrestrial Planetsmentioning
confidence: 99%
“…Based on the compositional estimates given in Table 1, chondritic ratios of refractory elements, and planetary K/Th values, we have calculated the present-day radiogenic heating rate (pW kg −1 ) and total planetary radiogenic power (TW) according to the method outlined in McDonough et al (2020). The estimated bulk uranium contents of Mercury, Earth, and Mars are 7, 13, and 15 ppb (10 −9 kg/kg).…”
Section: Implications Of the Modelmentioning
confidence: 99%