A minimal model for predicting ventilation rates of subterranean caves

TL;DR

This paper presents a simple, physics-based model to predict cave ventilation rates using only external temperatures and cave dimensions, aiding climate reconstruction from speleothems.

Contribution

The authors develop a minimal, explicit model for cave ventilation driven by buoyancy, which does not require internal temperature data and matches observed gas variations.

Findings

Model accurately predicts seasonal and synoptic gas variations

Ventilation driven by buoyancy explains observed gas transport patterns

Model useful for climate reconstruction from speleothem growth

Abstract

The ventilation of carbon dioxide within subterranean caves regulates the growth of speleothems --- mineral deposits found in caves that provide important clues about past climate. While previous studies have used internal temperature measurements to predict ventilation rates, such data would not be available for the task of climate reconstruction. Here, we develop a parsimonious model to predict ventilation rates from knowledge of outside temperatures and the cave's physical dimensions only. In the model, ventilation arises from buoyancy-driven flows created in passageways that connect to the outside. A few key simplifications leads to a system amenable to perturbation analysis, resulting in explicit expressions for ventilation rates. We compare these predictions to time-resolved, in-situ measurements of transported cave gases (carbon dioxide and radon). The theory accurately accounts for the timing and magnitude of seasonal and synoptic variations of these gases, and is therefore diagnostic of seasonal bias in speleothem growth.