7.5.2: Reduced inorganic components of minerals

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In addition to organic compounds, reduced inorganic components within rocks and sediment, such as ferrous iron and sulfur, can also serve as energy sources for chemolithotrophic microorganisms if suitable electron acceptors are available such as oxygen or nitrate. For example, studies have shown that microorganisms can use ferrous iron and sulfur in pyrite as an energy source (Baker and Banfield, 2003; Percak-Dennett et al., 2017) as well as ferrous iron in basalt, siderite, biotite, olivine, and hornblende (Edwards et al., 2003; Napieralski et al., 2019; Popa et al., 2012; Shelobolina et al., 2012).

Such energy sources have the potential to be important in marine environments where basalt is exposed to seawater containing oxygen and/or nitrate. Santelli et al. (2008) estimated that reduced inorganic components of upper ocean crust can support \(10^{7}\) to \(10^{9}\) cells per gram of rock, which corresponds well to measured cell densities on basalt. Moreover, iron-oxidizing chemolithotrophs isolated from deep sea environments have been shown to be capable of growing on basalt and causing increased basalt weathering (Edwards et al., 2004, 2003).

They also have the potential to support microbial ecosystems in terrestrial environments where reduced components in bedrock are exposed to oxic or nitrate-bearing solutions. For example, Napieralski et al. (2019) demonstrated that iron-oxidizing bacteria inhabit the weathering rind of a quartz diorite in Puerto Rico and have the capability of using mineral-derived ferrous iron as their primary energy source. Culturing experiments indicate that their activities increase the rate at which the bedrock weathers. Additional information about mineral weathering is available in Section 11.4.

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