Why is There No Biochar Production for The Palm Oil Industry Yet?

Even though biomass waste is abundant in the palm oil industry, both in the plantation area and in the palm oil mill area, most of the biomass waste, especially empty fruit bunches or EFB, is still not utilized or is simply piled up or thrown away. In fact, if the palm oil industry has a strong vision about maximizing profits by minimizing the occurrence of waste, especially biomass, and maximizing environmental sustainability as well as being part of the climate solution, then biomass waste, especially empty fruit bunches or EFB, is a big opportunity.  Currently, special department in the palm oil industry that specifically deal with sustainability issues are starting to be created by palm oil companies. Waste management issues including the utilization of EFB, reducing soil and water pollution due to fertilizers and increasing fertilizer efficiency are the concerns of the sustainability department.

The empty fruit bunches or EFB can be used as fuel so that most or all of the palm kernel shells or PKS can be sold directly and even exported. Palm oil mill boiler fuel currently uses fuel in the form of palm fiber (mesocarp fiber) and some palm kernel shells / PKS, which can be replaced using empty fruit bunches (EFB) and palm fiber (mesocarp fiber) and without palm kernel shells / PKS. Palm kernel shells / PKS are a very popular biomass fuel in the global market that competes fiercely with wood pellets. By being able to sell all palm kernel shells / PKS and at the same time utilize empty fruit bunch / EFB waste, the palm oil industry will provide many economic benefits.

The use of empty fruit bunches / EFB and mesocarp fiber as a heat source for the boiler is not burned as usual or as is done by all palm oil mills today but must be gasified or pyrolyzed so that another product is produced in the form of biochar. Although gasification can be used to produce biochar, pyrolysis is more recommended because the quality and quantity of biochar will be better. The biochar can later be used for the palm oil plantation itself. The use of biochar in palm oil plantations will significantly save on fertilizer use as well as reducing water and soil pollution due to inefficient use of fertilizer. The biggest cost in operating a palm oil plantation is fertilizer, so by using biochar these operational costs can automatically be reduced. Biochar will become a slow release agent so that fertilizer use will be more efficient or increase NUE (Nutrients Use Efficiency).

Empty fruit bunches / EFB and mesocarp fiber are solid waste from palm oil mills so the waste is located around the palm oil mill, while biochar is used for palm oil plantations. In palm oil companies, management is generally separated between the plantation and mill departments. The use of biochar in palm oil plantations while the raw material comes from palm oil mills requires special arrangements regarding this matter. This could be, for example, trucks transporting fresh fruit bunch / FFB from the plantation to the palm oil mill, then after the FFB is unloaded at the mill, they then go to the plantation again carrying biochar from the palm oil mill.

Currently, no one is utilizing empty fruit bunches / EFB and palm mesocarp fiber as a source of boiler heat and biochar production. The main factor causing this is the main orientation or vision of the palm oil company itself as described above. This is predicted to change soon as awareness of climate issues increases and reaches all levels, especially in sectors related to energy and sustainibility. Moreover, when biochar is applied to plantation land, it also gets carbon credit as carbon sequestration. The smoke coming out of the boiler furnace will also be cleaner as seen from its opacity. The use of gas and liquid fuels from pyrolysis by-products will produce better combustion quality as well as smoke from the chimney. And even the liquid products from pyrolysis can also be used as biopesticides and organic fertilizers. Boiler efficiency will also increase because it uses boiler feed water (BFW) in the form of hot water from the condenser output of the pyrolysis unit.

Apart from old palm oil mills which really want to upgrade their industrial energy systems and fertilizer efficiency in their plantations including sustaibility according to this vision, new palm oil mills whose status is in the development stage should be able to apply this concept more easily. New palm oil mills can immediately follow developments and demands of the times so that they become trend setters with this vision. Being a pioneer and trend setter is indeed more difficult and even risky than just being a follower, but this will raise the reputation and become a leader in the industry so it should also have a positive impact on the company's business performance. A worthy effort.

Decarbonization of the Iron and Steel Industry Part 3: from Low Carbon Production to Carbon Neutral Production

When the decarbonization target must be achieved according to the specified deadline, various efforts will also be made, including through a transition phase. The transition phase in the iron and steel industry is from low carbon production to neutral carbon production. There are a number of factors that influence towards this goal, especially the readiness of the market to buy iron and steel products produced from the production process and also the readiness of fuel and reducing agents for blast furnaces in the iron and steel industry. Charcoal is a fuel and reducing agent derived from biomass which has great potential for use in this transition phase. Charcoal as a carbonization or biomass pyrolysis product has a high calorific value, high fixed carbon and is stable.

Meanwhile, carbon neutral production conditions will be achieved when iron and steel production in the industry uses 100% renewable energy. The use of an electric furnace (EAF/Electric Arc Furnace) can be done as long as the electricity is produced from renewable energy sources. Likewise, the use of hydrogen fuel in blast furnaces (with electrical energy for plant operations also from renewable energy) is also able to achieve carbon neutral production conditions, and even the use of hydrogen fuel in blast furnaces is considered to be the ultimate goal in decarbonization of the iron and steel industry. With the target of achieving net zero emissions by 2050 and the average service life of blast furnaces being 20 years, the iron and steel industry's efforts to achieve the target must be well formulated and programmed. Even if efforts to replace blast furnaces do not follow this target time, it will put the achievement of net zero emissions by 2050 in jeopardy.

In fact, currently it is still far from achieving this goal because the construction of blast furnaces - basic oxygen furnaces (BF -BOF) is still being carried out, which should be EAF (Electric Arc Furnace) or currently only around 30% of the global iron and steel industry uses this EAF. Even the International Energy Association (IEA) highlighted this critical issue to achieve the Paris Agreement's net-zero target by 2050. CO2 intensity in this industry has only slightly decreased so that the use of renewable energy becomes increasingly important and accelerated.

A case example is the Japanese iron and steel industry. As a steel producer of more than 85 million tons per year with main use in domestic construction projects and automotive manufacturing and with more than 25% (more than 21 million tons) being exported, the Japanese steel industry has a significant influence on the global market. The dominant dependence on coal is the main problem of decarbonization and moreover, Japan is also the third largest coal importer in the world. Furthermore, decarbonization in Japan is considered inadequate because the Japanese steel industry lags behind other major world steel producers. Japan is a G7 country that does not implement a coal phaseout period.

Nippon Steel has even been labeled a climate laggard or slow to respond to the climate crisis in the Asian region. This is because the decarbonization strategy is inadequate or not in accordance with the IPCC's 1.5°C warming pathway or the IEA's net-zero pathways. This condition threatens national and global decarbonization targets and puts Japan's steel industry at risk. Meanwhile demand for low-carbon steel is increasing rapidly because steel industries and governments around the world are committed to reducing carbon emissions from fossil fuels. The Japanese steel industry needs to immediately decarbonize to remain competitive in the global market. Decarbonizing by investing in low-carbon steel production will address these risks and can position the Japanese steel industry as a leader in the green transition of the global steel industry.

 

Regarding the issue of fuel or renewable energy sources, biomass has a strategic position and role, namely in blast furnace operations, charcoal, which is a product of biomass carbonization, is used as a fuel and reducing agent, while in electricity production for iron and steel plant operations, biomass can be used as a renewable energy sources or biomass power plants. This is why the availability of biomass is very important so that the creation of energy plantations as a source of biomass is very necessary. Not only is the plantation a source of energy, it can also play a role in the production of food and feed, both of which are very beneficial for human life. And of course optimizing the use of the plantation by utilizing all parts of the tree (whole tree utilization) also provides maximum financial / economic benefits and with good management it will also provide benefits or improve the environment. And ideally by 2050 the steel industries will use electric arc furnaces / EAF, 100% hydrogen in blast furnaces and even a combination of carbon capture, to achieve net zero emissions in 2050 or even negative emissions so it is very good for the climate.