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  • 11.
    Zhao, Lingfeng
    KTH, School of Industrial Engineering and Management (ITM), Materials Science and Engineering.
    Purification of Engineered Graphite for Advanced Application2022Independent thesis Advanced level (degree of Master (Two Years)), 20 credits / 30 HE creditsStudent thesis
    Abstract [en]

    Graphite has important applications in several key industries, which has been listed as a “criticalraw material” considered to be supply-risk by European since 2020. Purification of engineered graphite is one of the essential processes for the manufacturing of high-quality graphite. In this work, the production process and the existing methods to purify the three major types of graphite are evaluated and compared. Then purification method focusing on acid washing to remove iron from bio-graphite is investigated. The results showed that the impurity removalefficiency of acid washing increases with the increase of temperature, but efficiency decreased because of HCl volatilization when the temperature reaches 100 ℃. High concentrations of hydrochloric acid and other strong acids can improve the ability of acid washing. The smaller the graphite particle size, the more iron impurities are removed. Finally, through multi-steps acid washing with hydrochloric acid and aqua regia at 80 °C, bio-graphite with a purity of 99.67 % was obtained. This meets the requirements of metallurgical electrodes and other applications. The acquisition of ultra-high-purity graphite still needs more further work.

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  • 12.
    Nilsson, Mika
    KTH, School of Architecture and the Built Environment (ABE), Architecture.
    MAGASINET2022Independent thesis Basic level (degree of Bachelor), 10 credits / 15 HE creditsStudent thesis
    Abstract [en]

    The proposal aims to build on Eskilstuna municipality's work with circular ideas about sustainability to create a lively community house with focus on cultivation and creativity. By utilizing garden waste and processing it into biochar used in both large- and small-scale cultivation, carbon dioxide is bound in the soil for thousands of years.  The biochar binds nutrients and water and provides an improved harvest. The design takes inspiration from the character of the place with it’s traditional red colored cultivation boxes and the red cycle bridge across the creek. The idea of a historic warehouse building (magasin) as a flexible basic structure emerged and has led to an exploration of how to give the typology a public character. The goal was to create a place where young and old could cultivate their interest in agriculture and culture, and in the long run encourage own food production as a driving factor in achieving a more climate-smart and resilient society.

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  • 13.
    Torres Morales, Eileen Jimena
    KTH, School of Industrial Engineering and Management (ITM).
    Assessment of biochar potential as a land-based emission mitigation measure in Colombia2022Independent thesis Advanced level (degree of Master (Two Years)), 20 credits / 30 HE creditsStudent thesis
    Abstract [en]

    There is an urgent need to mitigate carbon emissions to the atmosphere to reduce the negative effects of climate change. Countries have pledged national strategies to reach their climate change mitigation goals in their Nationally Determined Contributions (NDC). In the case of Colombia, the country envisions becoming carbon neutral by 2050. 

    A pathway to reach this goal is emission reduction through nature-based solutions (NBS). Biochar is an NBS with the potential to be used as a land-based emission mitigation technology. Records indicate that it was first used by indigenous communities in the Amazon about a thousand years ago. Biochar can be obtained through thermochemical conversion by slow pyrolysis of residual biomass. The original organic carbon present in the biomass is sequestered in the biochar as it is pyrolyzed and thus, CO2 emissions are prevented. Biochar is not yet considered in Colombia´s carbon neutrality strategy.

    The aim of this thesis project is to investigate the potential of biochar production in Colombia as a land-based mitigation technology (LMT). Therefore, a comprehensive assessment is performed with the purpose of identifying the status of biochar in the country. The motivation behind the assessment is to gain an understanding of the variables involved in biochar production. Factors such as the production sectors involved, feedstocks, production technologies, project costs and emission mitigation are of interest.

    The study explores these factors by following five methodological steps. First, the current research on the technology is mapped to understand biochar’s status at a national level. Second, experts are interviewed to collect their views regarding biochar and a PESTEL (Political, Economic, Social, Technological, Environmental & Legal) analysis is employed based on their point of view on the technology. Third, the potential sources of residual biomass which could be used to produce biochar in the agricultural sector are quantified. The approach to biochar’s potential is enriched with a focused in-person case study of biochar production from oil palm residues. Fourth, these residual biomass sources are subsequently employed to estimate the emissions sequestered in their biochar production. Lastly, project feasibility implementation is evaluated through a techno-economic to identify the project’s main cost drivers. The results are then discussed using a SWOT (Strength, Weaknesses, and Opportunities & Threats) analysis.

    The existing studies and the local experts’ opinion indicate that biochar potential is in the agricultural sector and that it can be thought of for soil adaptation. Biochar’s emission mitigation is considered an added value. In 2021, the agricultural sector produced near 73 million tonnes of agricultural products. The residues from agriculture could be used for biochar production. If the residues from the most produced agricultural products are transformed into biochar, about 1 to 2,2 tonne of CO2 per tonne of biochar could be avoided.

    The published literature and the in-person study visit confirmed that the largest advance in biochar production and use in Colombia is in the oil palm sector. Palm kernel shell, fibre and empty fruit bunches are the oil palm residues that could be used to produce biochar. From 1 tonne of these three oil palm residues, about 60 kg of biochar can be obtained.

    The results show that currently there is no market for trading with biochar in Colombia. High investments, transport and feedstock costs are identified obstacles. An Advanced Technology pyrolizer cost can cost around 330.000 USD while a Basic Technology one can be around 100 USD. Taxes associated with revenue from the biochar trade can negatively impact a biochar project’s feasibility. In this study, a price for biochar is estimated using break-even analysis. Under the assumptions used, the biochar price per tonne is around 200 to 1.000 USD. Price variability is explained in the technologies used for production, feedstock biomass availability and variable revenues from biochar sales. 

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  • 14.
    Jungefeldt, Louise
    KTH, School of Architecture and the Built Environment (ABE), Sustainable development, Environmental science and Engineering.
    Climate change mitigation from biochar production at farm level: A time dynamic LCA study of wheat2022Independent thesis Advanced level (degree of Master (Two Years)), 20 credits / 30 HE creditsStudent thesis
    Abstract [en]

    Agricultural production in Sweden account for a large contribution of the territorial GHG emissions. System optimization, fossil fuel removal and increased circularity is therefore of great importance in order to reach the national net zero emission target by 2045. Biochar production from biomass side flows is a cost-efficient method for carbon dioxide removal which could help to reduce the climate impact of agricultural systems. This study aimed to investigate the potential for climate change mitigation by implementing biochar production from wheat straw at farm level in Sweden. A life cycle perspective was used to assess the climate change impact for production of 1 Mg wheat, with three scenarios for straw management 1) biochar production and application on fields 2) straw incorporation into soil and 3) district heat production. A time distributed LCI was used to include the time dynamics of soil processes. Climate impact was assessed using two metrics: Total GWP100 impact(static) and global surface temperature change (time dynamic). Excess thermal energy from the pyrolysis process was assumed to be used for drying of grains and heating buildings at the farm. The results showed a total GWP100 impact of 214 kg CO2-eq/Mg wheat in the scenario with biochar production, which compare to the impact of 425-429 kg CO2-eq/Mg wheat for the scenarios with conventional straw management practices. The temperature response was ca 50 % lower all throughout the analysed time period, compared to the scenarios with straw incorporation or district heat production. The largest contribution to the impact reduction was achieved from carbon sequestration from biochar application to soil amounting to 223 kg CO2-eq/Mg. A sensitivity analysis of the biochar yield (kg biochar produced per kg of dry mass feedstock) for pyrolysis of straw confirmed that biochar production was preferable over other straw management practices for lower biochar yields as well. In conclusion, utilizing straw for biochar production could have a large potential for reducing the climate impact from wheat production in Sweden. However, a combination of measures for climate change mitigation is needed to reach net zero emissions of wheat production.

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  • 15.
    Zhang, Jinghe
    KTH, School of Industrial Engineering and Management (ITM), Energy Technology, Heat and Power Technology.
    Numerical Design of an Extremely High Temperature Thermochemical Reactor for Converting Biochar to Hard Carbon2022Independent thesis Advanced level (degree of Master (Two Years)), 20 credits / 30 HE creditsStudent thesis
    Abstract [en]

    Hard carbon is now a popular choice for the anode material in sodium-ion batteries. Converting biochar to produce hard carbon is considered carbon neutral and of great interest since it reduces the environmental impacts of biomass waste. This procedure requires high temperatures, and induction heating provides several advantages over other heating methods and is, therefore, widely used. In this thesis, a thermochemical reactor based on the principle of induction heating is designed, and CFD simulations of fluid-thermal coupling are performed. According to the simulation results, the total energy use efficiency of the induction heating reactor is calculated and compared with that of the thermal conduction heating reactor, which is found to be much higher than that of the thermal conduction heating reactor. Furthermore, the temperature of the tube wall of the reactor and the power losses of the inlet and outlet are observed, and design improvements are suggested. Simulation results indicate that adding a layer of protector to the exterior of the workpiece effectively reduces the wall temperature and the effect would be greater as the thickness of the protector increases. Meanwhile, the change in efficiency and energy losses are essentially negligible.

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1234567 11 - 15 of 55
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