# Fileset

[README.md](https://mdr.nims.go.jp/filesets/fd8b3ffa-4293-48a5-b3e4-b13ead6f5832/download)

## Creator

Cesare Cozza, [Kousuke Nakano](https://orcid.org/0000-0001-7756-4355), Saburo Howard, Hao Xie, Ravit Helled, Guglielmo Mazzola

## Rights

[Creative Commons BY Attribution 4.0 International](https://creativecommons.org/licenses/by/4.0/)

## Other metadata

[Hydrogen Equation of State with SCAN-VV10](https://mdr.nims.go.jp/datasets/5fd091cf-8c8a-42da-8290-80add49b1518)

## Fulltext

# Hydrogen Equation of State – H_SCANvv10_EoS.txtThis repository contains tabulated data for the **Equation of State (EoS) of Hydrogen** as computed and used in:**C. Cozza, K. Nakano, S. Howard, H. Xie, R. Helled, and G. Mazzola. _A denser hydrogen inferred from first-principles simulations challenges Jupiter’s interior models_. arXiv:2501.12925, 2025.**  [arXiv:2501.12925](https://arxiv.org/abs/2501.12925)---## 📄 Description### `H_SCANvv10_EoS.txt`This file provides a tabulated Hydrogen EoS over a **regular grid in Temperature and Pressure**, suitable for use in planetary interior modeling and related simulations.- **Temperature range**: 150 K to 50000 K   (149 points)  - **Pressure range**: 10⁻⁴ GPa to 10695 GPa  (349 points)The data file consists of 5 columns:1. **Temperature** [K]  2. **log₁₀(Pressure)** [GPa]  3. **log₁₀(Density)** [g/cm³]  4. **log₁₀(Internal Energy)** [MJ/kg]  5. **Entropy** [MJ/kg/K]As shown in **Figure 6** of the paper, the `H_SCAN+vv10_EoS.txt` table is built from multiple sources:- On the **low-pressure** side (150–11000 K, 10⁻⁴–0.1 g/cm³): SCvH data  - In the **intermediate regime** (2000–15000 K, 0.3–2.6 g/cm³): SCAN+vv10 data  - At **high densities** (> 3.4 g/cm³) and **high temperatures** (> 23000 K): CMS19 data  - All remaining regions: interpolation between the above datasets---### `H_SCANvv10_MD.txt`This file contains raw Molecular Dynamics results computed using the **SCAN+vv10** functional. It includes **total energies and pressures** (both electronic and ionic components) for selected state points.The file consists of 6 columns:1. **Temperature** [K]  2. **Density** [g/cm³]  3. **Energy per atom** [Ry]  4. **Pressure** [GPa]  5. **Statistical error (Energy)** [Ry]  6. **Statistical error (Pressure)** [GPa]These values were used to construct part of the SCAN+vv10 contribution to the full equation of state described above.As shown in Fig.6 of the paper we performed 126 Molecular Dynamics on a regular grid of 7 Tempertures from 2000 to 15000K and 18 Densities from 0.3 to 2.6 g/cm^3.  ---## ⚠️ Notes- The EoS table is **rectangular in T-P space**, but **not all thermodynamic quantities are available at every point**.- In regions where the density, internal energy, and entropy are **not physically meaningful or relevant** (e.g., **very high T and low P**, or **very low T and high P**), these columns contain the string `'NaN'`. For a clearer view of teh shape of the EoS we again refer to Fig. 6 of the paper.---## 📘 UsageThis dataset is intended for researchers modeling planetary interiors or conducting thermodynamic simulations of hydrogen under extreme conditions. To read the read the dataset using `pandas` use the following code snippet to delete the `'NaN'` values and convert all the data to floats" ```pythonimport pandas as pddf = pd.read_csv('H_SCANvv10_EoS.txt', sep=' ')# Remove rows containing NaN (as string or real NaN)df = df.replace('NaN', pd.NA)df = df.dropna()# Convert columns to float for plottingdf['T(K)'] = df['T(K)'].astype(float)df['logP(GPa)'] = df['logP(GPa)'].astype(float)df['logrho(g/cm^3)'] = df['logrho(g/cm^3)'].astype(float)df['logE(MJ/kg)'] = df['logE(MJ/kg)'].astype(float)df['S(MJ/kg/K)'] = df['S(MJ/kg/K)'].astype(float)```---## 📜 LicenseThis dataset is licensed under the [Creative Commons Attribution 4.0 International License (CC BY 4.0)](https://creativecommons.org/licenses/by/4.0/).  You are free to use, modify, and redistribute the data as long as you provide proper attribution.---## 📚 CitationIf you use this dataset in your work, please cite:**C. Cozza, K. Nakano, S. Howard, H. Xie, R. Helled, and G. Mazzola. _A denser hydrogen inferred from first-principles simulations challenges Jupiter’s interior models_. arXiv:2501.12925, 2025.**  [arXiv:2501.12925](https://arxiv.org/abs/2501.12925)