2010 journal article

Estimation of Waste Component-Specific Landfill Decay Rates Using Laboratory-Scale Decomposition Data

ENVIRONMENTAL SCIENCE & TECHNOLOGY, 44(12), 4722–4728.

By: F. Cruz  n & M. Barlaz n 

co-author countries: United States of America πŸ‡ΊπŸ‡Έ
MeSH headings : Biodegradation, Environmental; Bioreactors; Cities; Kinetics; Laboratories; Methane / analysis; Refuse Disposal / methods; Waste Products / analysis; Water Pollutants, Chemical / chemistry
Source: Web Of Science
Added: August 6, 2018

The current methane generation model used by the U.S. EPA (Landfill Gas Emissions Model) treats municipal solid waste (MSW) as a homogeneous waste with one decay rate. However, component-specific decay rates are required to evaluate the effects of changes in waste composition on methane generation. Laboratory-scale rate constants, k(lab), for the major biodegradable MSW components were used to derive field-scale decay rates (k(field)) for each waste component using the assumption that the average of the field-scale decay rates for each waste component, weighted by its composition, is equal to the bulk MSW decay rate. For an assumed bulk MSW decay rate of 0.04 yr(-1), k(field) was estimated to be 0.298, 0.171, 0.015, 0.144, 0.033, 0.02, 0.122, and 0.029 yr(-1), for grass, leaves, branches, food waste, newsprint, corrugated containers, coated paper, and office paper, respectively. The effect of landfill waste diversion programs on methane production was explored to illustrate the use of component-specific decay rates. One hundred percent diversion of yard waste and food waste reduced the year 20 methane production rate by 45%. When a landfill gas collection schedule was introduced, collectable methane was most influenced by food waste diversion at years 10 and 20 and paper diversion at year 40.