The final cumulative biogas product

The final cumulative biogas productions were 8291, 10395, 11970, and 14305 mL for 1%, 2%, 3%, and 4% NH3·H2O, respectively, illustrating an increase of 31.0%, 64.2%, 89.1%, and 126.0% over the untreated ones (Fig. 3). The same trend was also observed for the H2O2 pretreatment (Fig. 3b), indicating that NH3·H2O and H2O2 pretreatments can significantly improve the biodegradability of rice stalk and increase biogas yield. This phenomenon was due to the fact that alkaline and acid pretreatments increase organic solubilization and the surface area available for enzymatic action (Lin et al. 2009). The rice straw pretreated with 4% NH3·H2O resulted in higher cumulative biogas production than the other NH3·H2O concentration, in agreement with the result from Ma et al. (2011), who reported that the cumulative biogas production of 4% NH3·H2O treatment was 19.6% higher than that of the 2% NH3·H2O treatment. However, this phenomenon was not observed for the H2O2 pretreatment. Only a slight difference of 2.3% was observed in the biogas yields of 3% and 4% H2O2. More hydroxyl ion in 4% hydrogen peroxide pretreatment could produce toxicity to methanogens, thus inhibiting the activity of the microorganisms and interfering with their metabolism (Chen et al. 2008). The biogas yield of each concentration during the initial 5 days in both pretreatments presented no significant difference (Fig. 3), whereas thebiogas yield of pretreatment with a higher concentration was higher than that of the pretreatment with a lower concentration. This difference was caused by the instability of the digester at the beginning of AD, which was the environmental adaptation stage for methane bacteria. However, more biogas yield was attained with higher concentrated solution when the system was stable because of the greater ability to decompose the substance