| Views | |
|---|---|
| TRR 170 Planetary Data | 2509 |
| July 2025 | August 2025 | September 2025 | October 2025 | November 2025 | December 2025 | January 2026 | |
|---|---|---|---|---|---|---|---|
| TRR 170 Planetary Data | 73 | 239 | 1002 | 64 | 101 | 26 | 4 |
| Views | |
|---|---|
| Replication Data for: Silicon and iron isotopes in components of enstatite chondrites: Implications for metal–silicate–sulfide fractionation in the solar nebula | 330 |
| Replication Data for: Chromium Stable Isotope Panorama of Chondrites and Implications for Earth Early Accretion | 297 |
| Replication Data for: Onset of plate motion in the presence of chemical heterogeneities in the mantle and the effect of mantle temperature | 297 |
| Replication data for: Planetary impacts: effects of the impact speed on the crater depth | 296 |
| Replication Data for: Chlorine and hydrogen degassing in Vesta’s magma ocean | 287 |
| Replication Data for: Experimental and petrological investigations into the origin of the lunar Chang'e 5 basalts | 286 |
| Replication Data for: Blaubeuren, Cloppenburg, and Machtenstein—Three recently recognized H-group chondrite finds in Germany with distinct terrestrial ages and weathering effects | 279 |
| Replication Data for: Common feedstocks of late accretion for the terrestrial planets | 273 |
| Replication Data for: Formation of simple impact craters in layered targets: Implications for lunar crater morphology and regolith thickness. | 273 |
| Replication Data for: What Factors Affect the Duration and Outgassing of the Terrestrial Magma Ocean? | 269 |
| Replication Data for: The anomalous polymict ordinary chondrite breccia of Elmshorn (H3-6)—Late reaccretion after collision between two ordinary chondrite parent bodies, complete disruption, and mixing possibly about 2.8 Gyr ago | 269 |
| Replication Data for: Sulfides and hollows formed on Mercury's surface by reactions with reducing S-rich gases | 264 |
| Replication Data for: Impact-related crystallization and modification of small zircons in Apollo 15 and 16 impactites at 4.2 Ga | 263 |
| Replication Data for: 3D-simulation of Lunar Megaregolith Evolution: Quantitative Constraints on Spatial Variation and Size of Fragment | 262 |
| Replication Data for: Modal abundances of coarse-grained (>5 µm) components within CI-chondrites and their individual clasts – Mixing of various lithologies on the CI parent body(ies). | 261 |
| Mass fractions of siderophile elements, Sm and Ba in lunar high-Ti mare basalts by ID-ICP-MS | 261 |
| Reproduction Data for: Moderately volatile elements in chondrites record chondrule formation, two component mixing and redistribution on parent bodies | 256 |
| Replication Data for: Classification of CM chondrite breccias – Implications for the evaluation of samples from the OSIRIS REx and Hayabusa 2 missions. | 255 |
| Replication Data for: Ruthenium isotope fractionation in protoplanetary cores | 254 |
| Replication Data for: The effect of target properties on transient crater scaling for simple craters. | 253 |
| November 2025 | December 2025 | January 2026 | |
|---|---|---|---|
| Replication Data for: Mid-infrared spectroscopy of lunar high-Ti basaltic glassy analogues | 67 | 60 | 3 |
| Replication Data for: Tellurium isotope cosmochemistry: Implications for volatile fractionation in chondrite parent bodies and origin of the late veneer. | 33 | 28 | 20 |
| Replication Data for: The Temperature and Composition of the Mantle Sources of Martian Basalts | 26 | 31 | 18 |
| Replication Data for: Synthesis of Large Amounts of Volatile Element-Bearing Silicate Glasses Using a Two-Stage Melting Process | 26 | 22 | 24 |
| Replication Data for: The effect of target properties on transient crater scaling for simple craters. | 34 | 20 | 17 |
| Replication Data for: Low volcanic outgassing rates for a stagnant lid Archean earth with graphite-saturated magmas | 31 | 22 | 16 |
| Replication Data for: Ruthenium isotopic fractionation in primitive achondrites: Clues to the early stages of planetesimal melting | 24 | 24 | 19 |
| Replication Data for: The Timeline of Early Lunar Bombardment Constrained by the Evolving Compositions of Differently-Aged Melt | 36 | 16 | 14 |
| Replication Data for: Formation of Apollo 16 impactites and the composition of late accreted material: Constraints from Os isotopes, highly siderophile elements and sulfur abundances. | 27 | 20 | 17 |
| Replication Data for: Nano- and microstructures in lunar zircon from Apollo 15 and 16 impactites: implications for age interpretations. | 20 | 25 | 18 |
