To date, an understanding of how plant growth-promoting bacteria facilitate plant growth has
been primarily based on studies of individual bacteria interacting with plants under different …

Methane is one of the critical greenhouse gases, which absorb long wavelength radiation,
affects the chemistry of atmosphere and contributes to global climate change. Rice …

Before the industrial revolution, the atmospheric CO 2 concentration was 180–330 ppm;
however, fossil-fuel combustion and forest destruction have led to increased atmospheric …

The rising atmospheric CO 2 is a major driver for climate change, directly affects rice
production. Cadmium (Cd) in paddy soils also serves as a persistent concern. Currently, few …

Studying methanogenesis in paddy fields under future climate change scenarios is
important for carbon sequestration and reduction in agroecosystems. Most studies have …

Elevated atmospheric carbon dioxide (eCO 2) greatly impacts greenhouse gas (GHG)
emissions of CH 4 and N 2 O from rice fields. Although eCO 2 generally stimulates GHG …

Roots and the associated rhizospheric activities regulate the mineralization of native soil
organic matter (SOM), which is referred to as the rhizosphere priming effect (RPE). Although …

Both elevated atmospheric carbon dioxide (CO 2) and rising temperature can alter soil
methane (CH 4) fluxes, leading to a feedback to climate change. However, predicting this …

The response of soil microorganisms to elevated atmospheric CO 2 (eCO 2) has the
potential to alter the regulation of soil biogeochemical processes including carbon and …

The simulation of abrupt atmospheric CO 2 increase is a common way to examine the
response of soil methanotrophs to future climate change. However, atmosphere is …