Raw data for thermodynamic modeling of komatiite-weakly acidic early seawater interatcion in the manuscript by Nishizawa et al. published as "Highly Alkaline, Hydrogen- and Ammonia-Rich Fluids from Hadean Komatiite-Hosted Hydrothermal Systems.

Raw data for thermodynamic modeling of komatiite-weakly acidic early seawater interatcion in the manuscript by Nishizawa et al. published as "Highly Alkaline, Hydrogen- and Ammonia-Rich Fluids from Hadean Komatiite-Hosted Hydrothermal Systems.

Dataset of hypervelocity impact experiments simulating oceanic impacts of asteroids. Table 1: Relationship between cavity depth and time after the first contact between projectile and water. Table 2: Time evolution of cavity growth and pressure wave propagation in the water column. (We have removed the pressure values in water from Table 2 due to the wrong estimates. )

Dataset of hypervelocity impact experiments simulating oceanic impacts of asteroids. Table 1: Relationship between cavity depth and time after the first contact between projectile and water. Table 2: Time evolution of cavity growth and pressure wave propagation in the water column. (We have removed the pressure values in water from Table 2 due to the wrong estimates. )

Dataset of hypervelocity impact experiments simulating oceanic impacts of asteroids, showing the fragmentation of projectile (chondrite, stainless-steel, olivine) within expanding water cavities filled with water bubbles. Table 1: Relationship between cavity depth and time after the first contact between projectile and water. Table 2: Depth trends of stress wave propagation rate, downward expansion rate of main cavity, and calculated peak shock pressure within water column. Table 3: Relationships between water depth normalized by projectile diameter (H/d) and (a) maximum crater diameter, (b) maximum crater depth, and c) crater volume in benthic solid target as a function of kinetic energy of projectile (V/E).

Dataset (Table S1 to Table S4) of hypervelocity impact experiments simulating oceanic imapcts of asteroids, suggesting small-asteroid (200-1,000 m in diameter) fragmentation within water cavities filled with water bubbles from vaporization of supercritical water.