Treatment of landfill leachate by H3P04 impregnated Parkia speciosa (Petai) pods activated carbon: characterization, kinetics, thermodynamics and isotherms studies

(주)코리아스칼라

최초 등록일: 2023.05.22
최종 저작일: 2023.02; 16페이지/ 어도비 PDF; 가격 4,900원

다운로드

장바구니

상세정보
자료후기 (0)
자료문의 (0)
판매자정보

* 본 문서는 배포용으로 복사 및 편집이 불가합니다.

서지정보

ㆍ발행기관 : 한국탄소학회 ㆍ수록지정보 : Carbon letters / 33권 / 1호
ㆍ저자명 : Vivek Laishram, Potsangbam Albino Kumar

Abstract
1 Introduction
2 Materials and methods
2.1 Synthesis of adsorbent
2.2 Leachate sample collection and analysis
2.3 Batch experiment and analysis
2.4 Methodology
3 Results and discussion
3.1 Characterization of alum pretreated stabilized leachate
3.2 Adsorbent characterization
3.3 Surface morphology of PPAC adsorbent by FESEM analysis
3.4 Elemental composition of PPAC adsorbent by EDAX analysis
3.5 Point of zero charge of PPAC
3.6 Influence of pH on COD removal by PPAC adsorption
3.7 Effects of contact time on COD adsorption by PPAC
3.8 Kinetic adsorption modeling
3.9 Temperature effects on COD removal
3.10 Thermodynamics part of temperature effect
3.11 Effects of PPAC dosage on COD removal
3.12 Adsorption isotherm study on COD removal
3.13 Influence of PPAC dosage on TDS, total iron and colour removal
3.14 Regeneration and reuse of spent adsorbent
4 Conclusion
References

영어 초록

The present study focuses on the adsorption of organic matter mainly COD from pretreated landfill leachate of Lamdeng Khunou Solid Waste Management Plant, Manipur, India through the employment of H3PO4 treated activated carbon derived from Parkia speciosa (Petai) pods (PPAC). The adsorbent was analyzed for morphological and surface characterization by various methods including, Field emission scanning electron microscopy (FESEM), Energy Dispersive X-Ray Analysis (EDAX), Brunauer–Emmett–Teller (BET) surface area and pH at zero point charges ( pHZPC). The impacts of adsorption processes such as initial pH, temperature, equilibrium time and dose of adsorbent were considered to evaluate the performance of PPAC. At 20 °C, PPAC showed maximum COD removal of 93% within 90 min contact time, at optimum pH 2. Adsorption kinetic was able to explain by Lagergren’s pseudo-second-order equation and intraparticular diffusion models suggesting the combined behavior of both the physical and chemical adsorption of COD on PPAC. Through thermodynamics and isotherm studies, the adsorption of COD on PPAC is revealed to be exothermic with maximum monolayer coverage of 200 mg COD/g PPAC. The performance of the PPAC adsorbent is also compared with other existing reported adsorbents for treating leachate.