Green and chemical-free pretreatment of corn straw using cold isostatic pressure for methane production

In this study, the effect of cold isostatic pressure (CIP) pretreatment on the physicochemical properties and subsequent anaerobic digestion (AD) performance of corn straw (CS) was explored. The CS was subjected to CIP pretreatment by pressures of 200, 400 and 600 MPa, respectively, while AD was carried out at medium temperature (35 & PLUSMN; 2 & DEG;C). The results showed that CIP pretreatment disrupted the dense structure of the CS and altered the crystallinity index and surface hydrophobicity of the CS, thereby affecting the AD process. The presence of CIP pretreatment increased the initial reducing sugar concentration by 0.11-0.27 g/L and increased the maximum volatile fatty acids content by 112.82-436.64 mg/L, which facilitated the process of acidification and hydrolysis of the AD. It was also observed that the CIP pretreatment maintained the pH in the range of 6.37-7.30, maintaining the stability of the overall system. Moreover, the cumulative methane production in the CIP pretreatment group increased by 27.17 %-64.90 % compared to the control group. Analysis of the microbial results showed that CIP pretreatment increased the abundance of cellulose degrading bacteria Ruminofilibacter from 21.50 % to 27.53 % and acetoclastic methanogen Methanosaeta from 45.48 % to 56.92 %, thus facilitating the hydrolysis and methanogenic stages. The energy conversion analysis showed that CIP is a green and non-polluting pretreatment strategy for the efficient AD of CS to methane.

Automated summary

This study explored the effect of cold isostatic pressure (CIP) pretreatment on the physicochemical properties and subsequent anaerobic digestion (AD) performance of corn straw (CS). The results showed that CIP pretreatment disrupted the dense structure of the CS and altered its crystallinity index and surface hydrophobicity, thereby affecting the AD process. The CIP pretreatment increased the initial reducing sugar concentration and maximum volatile fatty acids content, facilitated acidification and hydrolysis, maintained pH stability, and significantly increased cumulative methane production. Moreover, the microbial results indicated that CIP pretreatment enhanced the abundance of cellulose degrading bacteria and acetoclastic methanogen, thus promoting hydrolysis and methanogenesis. The energy conversion analysis revealed that CIP is a green and non-polluting pretreatment strategy for efficient CS to methane AD.