The Urgency of Biochar Application on Palm Oil Plantations in Indonesia

The large number of acidic soils in Indonesia that are used for palm oil plantations makes the productivity of palm oil fruit or the resulting FFB (fresh fruit bunch) not optimal. The acid soil covers the largest dryland area in Indonesia. It occupies approximately 55% of the total land area (191.09 million ha) in Indonesia. About 107.36 million ha of all Indonesian acid soils is classified as dryland acid soils and the rest (14.93 million ha) as peat soil. Acid soils in Indonesia are distributed amongst the big islands, such as Kalimantan (39.42%), Sumatera (28.81%), Papua (18.03%), Java (7.77%), and Sulawesi (6.95%). Acidic soils with low pH make nutrient absorption low in plants and so do soil microbial activity, which plays a large role in soil fertility. This condition should not be ignored because besides making the cultivation of palm oil plantations not optimal, there will also be a lot of fertilizer used. This makes the operational costs of  palm oil plantation operation high. Biochar is a biomass pyrolysis product that is effective and efficient in overcoming these problems. With the abundant amount of biomass waste produced by palm oil mills or CPO mills as biochar raw materials, efforts to improve the quality of plantation soil should be easy to do and have even become the operational standard for these plantations. But the fact is not.

 

Why hasn't biochar been used to improve soil quality and thus increase the production of palm oil fruit or FFB? The lack of information and education about the benefits and uses of biochar are the main factor. This of course makes the application of biochar in palm oil plantations not yet done even though palm oil mills have abundant biomass waste such as empty palm fruit bunches (EFB) and fiber which are generally not used and cause environmental problems. The priority for processing EFB compared to other products such as EFB pellets or compost also needs separate considerations. The best choice, of course, is based on a comprehensive study according to the characteristics of the business or business will be built. Consider not only short-term economic benefits, but also environmental and long-term benefits is an important thing.

Quantitatively, an increase in the production of palm oil fruit or FFB, an increase of at least 20% with the application of biochar is something that is normal. And a 20% increase in fruit production will also result in a big profit. Productivity of a number of other agricultural commodities can be increased by 30%, 40% or even more than 100%. The low productivity of palm oil fruit in Indonesia can be increased by the application of biochar, which is particularly effective in improving the soil quality in the palm oil plantations. Moreover, about 80% of the components of the cost of producing crude palm oil (CPO) come from the plantations, and 20% in the processing sector (palm oil mills). The operational costs of palm oil mill plantations, especially fertilizers, can also be reduced by the use of biochar. The priority of liquid biofuel development will also get better if the volume of biofuel raw materials such as CPO increases. This shows the strategic role of biochar. Apart from that from the aspect of climate change, biochar will also absorb CO2 concentrations in the atmosphere or reduce the concentration of greenhouse gases, as a solution to today's world problems. 

 

Meanwhile, from the side of the palm oil mill, another advantage obtained from biochar production is the use of excess energy from the pyrolysis process or the production of biochar as an energy source for the boiler. Boiler feed water (BFW) will also be preheated twice when it is used for cooling in the pyrolysis condenser and then the economizer on the boiler. In this way, the energy needed by the boiler decreases. When the boiler energy source uses the energy source from pyrolysis, this means that the palm kernel shell (PKS) can be taken and used for other things and can even be sold directly for local and export markets. The main obstacle to business development in the palm oil industry is the availability of energy source namely electricity. If the energy source is available, the development of palm oil-based businesses is very open and varied, such as the production of CPO derivatives, palm kernel shell processing, PKO production, PKO derivative production, biomass power plants and so on.

Production of EFB Pellet EFB or EFB Biochar ?

One of the main obstacles for palm oil mills to develop their business is the availability of electricity. With locations that are generally located in remote areas in the middle of palm oil plantations, palm oil mills do not get electricity supply from PLN (Indonesia State Owned Electricity Company). Eventhough electricity is very important in a production process, such as in the production of EFB pellets. Even though empty bunches or EFB in general are an environmental problem for palm oil mills. If every ton / hour of EFB pellet production takes 300 KW, then for production of 10 tonnes / hour (5,000 tonnes / month) 3 MW of electricity is needed, export of biomass fuels such as wood pellets and PKS (palm kernel shell)  with bulk shipments usually requires 10 thousand tons / shipment. So if the production of EFB pellets is planned for 10 thousand tons / month so that every month can export the EFB pellets, the factory capacity or EFB pellet production is 20 tons / hour (10,000 tons / month) 6 MW of electricity is needed. For palm oil mills, utilizing liquid waste or POME to become biogas is a potential source of energy for the production of electricity. However, with a palm oil mill capacity of 30 tonnes of FFB / hour, only about 1 MW of electricity is generated from POME biogas, so to produce 6 MW of palm oil mills with a capacity of 6 x 30 tonnes of FFB / hour are generated equal to 180 tonnes of FFB / hour. In fact, the average palm oil mill has a capacity of 45 - 60 tonnes of FFB / hour, so it is impossible to generate 6 MW of electricity from the palm oil mill's POME biogas.

The use of EFB pellets is the same as wood pellets and PKS is mainly for power generation. All three are biomass fuels. The high chlorine and potassium content in empty palm fruit bunches or EFB makes their use limited to power plants due to corrosion and scale causes. Not all power plants can use EFB pellets at large capacities or quantities. The use of coal-fired power plants with pulverized combustion technology can only be used with a small ratio or an estimate of less than 5%, but can be used more or even 100% in fluidized bed and stoker types of power plants. The capacity of fluidized bed and stoker type PLTU is generally much smaller than pulverized combustion.

When the biomass source is managed properly, the use of biomass fuel is an environmentally friendly and sustainable fuel. Biomass fuels like this are carbon neutral fuels, because they do not increase the concentration of CO2 in the atmosphere. This is because the biomass as a fuel source comes from plants whose growth is from the photosynthesis process, one of which uses CO2 from the atmosphere, so that when the biomass is burned, there is practically no addition of CO2 to the atmosphere. In general, there are 2 ways to overcome the CO2 concentration in the atmosphere which causes climate change and global warming, namely the carbon neutral scenario and the carbon negative scenario. In a carbon negative scenario, CO2 in the atmosphere will be captured and absorbed so that it is no longer released and the concentration of CO2 in the atmosphere can be reduced, as in the biochar application below.

Whereas in the production of biochar with pyrolysis, besides not requiring a large amount of electrical power for its operation, electricity can also be generated from the use of excess energy from pyrolysis itself. By using the excess energy from pyrolysis, the palm oil mill boiler fuel does not need to use palm kernel shells and fiber. The use of gas or liquid fuels from the excess energy of the pyrolysis process also makes burning emissions cleaner. To achieve more complete combustion, gaseous or liquid fuels are better than solid fuels. Palm kernel shells so that everything can be sold or even exported. The biochar product applied to palm oil plantations will also improve the quality of the soil so that fertilizer use can be reduced and the productivity of palm oil fruit will increase. Biochar also absorbs CO2 from the atmosphere so that the use of biochar in large palm oil plantations means that with massive applications it can also be used for carbon trading. Recent developments indicate that the use of biochar is increasingly widespread, such as biomaterials for construction, transportation, plastics, packaging, furniture and so on. The use of biomaterials for these products means substituting the use of fossil-derived raw materials.

So based on the above review, the production of biochar with pyrolysis is more profitable and easy to implement for palm oil mills compared to EFB pellet production. The addition of electricity production with a large capacity and the availability of sufficient raw materials is not easy and cheap for the average palm oil mill in Indonesia with a capacity of 45 - 60 tons of FFB / hour. Whereas in the production of biochar with pyrolysis, a certain amount of energy is produced which can be used for various purposes and the use of biochar is also multi-beneficial. Palm oil mills should consider this in particular in the aspects of waste management, plantation productivity, environmental aspects and business development, for more read here. Based on experience, the cost structure of the CPO or palm oil production business consists of about 80% of the cost of production is the cost of crops or plantation aspects, while the other 20% is the cost of processing or mill aspects. And the highest cost aspect of palm oil plantations is the cost of fertilization so that if the need for fertilizer can be reduced and the productivity of palm oil can be increased, of course it is very profitable, biochar is effective and efficient to use for this.

Biochar For Date Palm Plantations

Biochar is increasingly being used as a soil amendment with the aim of improving the physical, chemical and biological properties of the soil, and reducing the concentration of greenhouse gases from the atmosphere. In date palm plantations which are mostly planted in dry and sandy areas, the use of biochar will especially increase the ability of water and nutrients holding capacity, meaning that the evaporation of groundwater can also be reduced and nutrient loss for date palms can also be reduced. This of course is very beneficial for the date palm tree. Waste from date palm plantations such as midribs, seeds and leaves can be used as raw material for the biochar. The impact or positive results of the use of biochar have been reported from enormous of studies and experiments. These results are improvements in the physical, chemical and biological properties of the soil which ultimately result in the quality and productivity of the fruit yield.

Every year, it is estimated that each date palm tree produces 33 kg of green waste or 20 kg of dry biomass waste. Currently, it is estimated that date palms around the world reach 120 million trees with a biomass waste potential of 4 billion tonnes of green waste or 2.4 billion dry and can be converted into biochar into 800 million tonnes of biochar. The 10 largest date producing countries are Egypt, Iran, Saudi Arabia, Algeria, Iraq, Pakistan, Sudan, South Sudan, Oman and the United Arab Emirates. The use of modern pyrolysis equipment for processing biomass waste into biochar, also produces excess energy for heat or electricity production which can be used for various purposes. Location of date palm plantations in rural areas can use electricity or store this energy for other purposes such as cooking. The energy storage can be done with large or small tanks for the needs of residents in that location. By utilizing the excess energy from the pyrolysis process, environmental damage such as illegal logging can be minimized. Dry and arid are areas with high evaporation and low rainfall, and such areas as these occupy 41% of the land surface area on earth. Currently nearly 900 million people inhabit this area.

Improved soil quality will result in higher crop productivity. The better the quality of the soil that can be cultivated, the better the productivity will be. Biochar will enrich soil organic carbon which has important roles, including reducing plant nutrient loss, increasing soil aggregation, reducing soil erosion, and increasing water holding capacity. Each plant has its own characteristics regarding the growing medium and environmental condition. Improving the quality of the soil will certainly increase the productivity of dates and even increase the quality of the fruit.

Production of Electricity and Biochar from Pineapple Plantation Waste

Besides being able to be processed into briquettes or in more detail, read here, pineapple plantation waste can also be used for electricity and biochar production. The use of biochar on pineapple plantation land will increase fertility and improve soil quality so that it will also increase the productivity of the pineapple fruit. The use of biochar on dry land such as pineapple plantations will be more effective so that the benefits will be even more real. Biochar that can last up to hundreds of years in the soil will provide long-term benefits for pineapple plantation owners. The era in the future that tends towards efficient agriculture or precision agriculture will also produce less waste or even zero waste. Agricultural wastes that have been a lot of environmental problems will be reduced and processed into added value, environmentally friendly and sustainable materials such as biochar production.

In large pineapple plantations, the amount of pineapple waste produced is also large. Besides producing biochar, pyrolysis of pineapple waste will also generate electricity. Electricity as a form of energy that is easily converted to various other forms of energy is certainly very useful, especially the pineapple industry. Pineapple processing can use the electricity generated, thereby reducing or even eliminating the need for external electricity. But it is possible that if the pineapple industry needs heat more than electricity, the excess energy from pyrolysis does not need to be converted into electricity but only heat is enough and this is easier and simpler. Of course, these things also further reduce the production costs of these pineapple-based products, thus providing even greater profit.

There are many products from the pineapple industry, including candied pineapple, pineapple jam, pineapple paste, pineapple chips, pineapple juice, pineapple juice probiotics, pineapple jelly, canned pineapple, and dried fruit. As one fruit that is quite popular throughout the world, the demand for pineapple is also increasing. With the prediction of the world's population reaching nearly 10 billion by 2050, the need for food, especially fruit, will also increase. Pineapple peels are also commonly used as animal feed, especially cattle, and cow dung is used for biogas production. The addition of biochar to cow dung for biogas will increase biogas production, more details can be read here and the sideproduct in the form of digestate which is then composted will be of better quality in the presence of biochar. Biochar makes the nutrients in compost not easy washed but is released slowly (slow release fertilizer).