# Efficient adiabatic hydrodynamical simulations of the high-redshift   intergalactic medium

**Authors:** Prakash Gaikwad, Tirthankar Roy Choudhury, Raghunathan Srianand,, Vikram Khaire

arXiv: 1705.05374 · 2018-02-06

## TL;DR

This paper introduces a fast post-processing tool for adiabatic simulations of the high-redshift intergalactic medium, enabling efficient modeling of Lyα forest properties and thermal histories with good accuracy.

## Contribution

The method allows rapid exploration of different thermal histories and non-standard heating sources without rerunning full simulations, improving efficiency and flexibility.

## Key findings

- Results agree within 20% of self-consistent simulations
- Method reduces computation time by a factor of N for multiple thermal histories
- Enables modeling of non-equilibrium thermal and ionization evolution

## Abstract

We present a post-processing tool for GADGET-2 adiabatic simulations to model various observed properties of the Ly$\alpha$ forest at $2.5 \leq z \leq 4$ that enables an efficient parameter estimation. In particular, we model the thermal and ionization histories that are not computed self-consistently by default in GADGET-2. We capture the effect of pressure smoothing by running GADGET-2 at an elevated temperature floor and using an appropriate smoothing kernel. We validate our procedure by comparing different statistics derived from our method with those derived using self-consistent simulations with GADGET-3. These statistics are: line of sight density field power spectrum, flux probability distribution function, flux power spectrum, wavelet statistics, curvature statistics, HI column density (${\rm N_{HI}}$) distribution function, linewidth ($b$) distribution and $b$ versus $\log {\rm N_{HI}}$ scatter. For the temperature floor of $10^4$ K and typical signal-to-noise of 25, the results agree well within 20 percent of the self-consistent GADGET-3 simulation. However, this difference is smaller than the expected $1\sigma$ sample variance for an absorption path length of $\sim 5.35$ at $z=3$. Moreover for a given cosmology, we gain a factor of $\sim N$ in computing time for modelling the intergalactic medium under $N \gg 1$ different thermal histories. In addition, our method allows us to simulate the non-equilibrium evolution of thermal and ionization state of the gas and include heating due to non-standard sources like cosmic rays and high energy $\gamma$-rays from Blazars.

## Full text

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## Figures

32 figures with captions in the complete paper: https://tomesphere.com/paper/1705.05374/full.md

## References

103 references — full list in the complete paper: https://tomesphere.com/paper/1705.05374/full.md

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Source: https://tomesphere.com/paper/1705.05374