<p>Replicating deep subsurface conditions remains a major challenge for advancing subterranean biotechnologies. Microbially enhanced coal bed methane production offers a promising approach to increase biogenic gas recovery from coal seams, yet experimental progress has been limited by the difficulty of simulating in situ conditions. A key question is whether nutrient amendments stimulate coal-dependent methanogenesis or simply convert injected nutrients to methane. Here, we report the use of a large-scale (325 L) reactor to investigate <sup>13</sup>C-labeled microalgae amendments on microbially-enhanced coal bed methane production at in situ pressure. Labeled methane was detected only during the initial stimulation phase, while most of the methane produced over five months originated from the coal. These field-relevant results demonstrate that microalgae can accelerate early methanogenesis and enhance coal-derived methane production over time. This study provides a critical proof-of-concept with broad implications for advancing subsurface biotechnologies toward field-scale deployment.</p>

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Meso-scale pressure reactor demonstrates biostimulation of coal-dependent methanogenesis

  • Margaux Meslé,
  • Adrienne Phillips,
  • Elliott P. Barnhart,
  • Laura Dobeck,
  • Joachim Eldring,
  • Randy Hiebert,
  • Rita Park,
  • Alfred Cunningham,
  • Robin Gerlach,
  • Lee Spangler,
  • Katherine Davis,
  • Matthew W. Fields

摘要

Replicating deep subsurface conditions remains a major challenge for advancing subterranean biotechnologies. Microbially enhanced coal bed methane production offers a promising approach to increase biogenic gas recovery from coal seams, yet experimental progress has been limited by the difficulty of simulating in situ conditions. A key question is whether nutrient amendments stimulate coal-dependent methanogenesis or simply convert injected nutrients to methane. Here, we report the use of a large-scale (325 L) reactor to investigate 13C-labeled microalgae amendments on microbially-enhanced coal bed methane production at in situ pressure. Labeled methane was detected only during the initial stimulation phase, while most of the methane produced over five months originated from the coal. These field-relevant results demonstrate that microalgae can accelerate early methanogenesis and enhance coal-derived methane production over time. This study provides a critical proof-of-concept with broad implications for advancing subsurface biotechnologies toward field-scale deployment.