Within the Netherlands, approximately 8.5 million tonnes of solid waste are produced annually. Being the capital city with the most populated district in the Netherlands, higher municipal solid waste accumulation in Amsterdam is in existence. A substantial portion of the municipa
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Within the Netherlands, approximately 8.5 million tonnes of solid waste are produced annually. Being the capital city with the most populated district in the Netherlands, higher municipal solid waste accumulation in Amsterdam is in existence. A substantial portion of the municipal waste in Amsterdam is categorized as organic waste, with a percentage of 36%. By far, the waste separation in Amsterdam is further less than the national average, especially for organic waste where its separation rate does not even reach 0.1%. Eventually, most of the organic waste is often commingled with residual waste and being incinerated collectively. A wide range of solutions is proposed to preserve as much value of organic waste as possible such as through bio-digestion and composting. A project called ReStore contributed to this by developing a measurement method on centralised and decentralised organic waste management options. However, it is not yet known the extent to which the outcome of this model can be accurately interpreted. An evaluation and comparison within a systematic approach is needed by considering different attempt in the modelling, conceptualization, and approach in order to gain a far-reaching and thorough interpretation. Furthermore, the typical configuration, feature, infrastructure, and process design made up the unique characteristic of organic waste management. Thus, there is a need for detailed analysis that is capable of considering specific waste properties and process characteristics through a chain perspective. Taking the ReStore method as a point of departure, this study seeks to investigate the carbon footprint of composting, bio-digestion, and WtE using the Life Cycle Assessment (LCA) method and finally point out how both models can complement one another. To that end, a literature review was firstly carried out along with the ReStore model conceptualisation. Next, an environmental impact modelling was performed following the LCA methodology, building on the model characteristics and framework from ReStore. Through comparative analysis, the outcome of the LCA study was then compared with the outcome from the ReStore model. Finally, recommendations were formulated on how the concept of LCA helps in providing suggestions on modelling waste management for the ReStore model and vice versa. The results demonstrate a close outcome between the LCA model and the ReStore model, either from the order of impact or from the hotspot dispersion. The results vary along the chosen allocation method, yet, all of these results show that neither bio-digestion nor composting are seen as the preferably option towards WtE. Though differences between both models are not really prominent, the knowledge of LCA embraces essential contributions towards performance improvement for ReStore to model better organic waste management scenarios. It helps ReStore to be more aware with regard to multifunctionality issue and its solutions. Moreover, the wide-range impact categories included in the LCA will help in defining a more extensive result interpretation through different impact point of view. Furthermore, LCA provides thorough and systematic result evaluation that will contribute to a more conclusive analysis. While the LCA model and its concept shares imperative roles to the ReStore model, the LCA model model could also learn from the ReStore model to be more specific with regard to the modelling and analysis. The ReStore model has inspired the LCA model with regard to the flexibility in handling changes in the waste composition. Finally, LCA that is known as a complex and resource intensive tool may learn from ReStore in terms of its accessibility.