Biochar for Energy Plantations

The low productivity of wood from energy plantations is one of the obstacles to the development of energy plantations. Although energy plantation plants such as calliandra can grow on marginal or critical lands, the quality of the soil affects the productivity of the wood produced. This makes it important to improve the quality of the soil of these energy plantations so that they can produce optimal plant productivity. Biochar can be an effective solution for this. Biomass waste that pollutes the environment can be used for biochar production or wood products from these energy plantations can be partly used for biochar production.

Biochar and energy plantations are two positive things for climate solutions. Energy plantations for the production of carbon neutral biomass fuels such as wood pellets, while biochar is to improve soil quality, save fertilizer use and so on and as carbon sequestration / carbon sinks that are carbon negative. The biochar solution for energy plantations will maximize CO2 reduction and sustainability efforts. The vastness of energy plantations is because they are pursuing the target of producing biomass fuel quantities which are comparable to land use and also comparable to the use of biochar. This is so that industrial-scale biochar production is needed to support this, read more details here. The more damaged the land or critical lands are, the greater the need for biochar. And the production of large-capacity biochar has the opportunity to get carbon credit or BCR (Biochar Carbon Removal) credit which can be a driving force for the growth of biochar industries. 

Critical and marginal lands should be prioritized as energy plantation lands. This will not only restore land quality but will also provide added value to land use and efforts to prevent disasters. Land legality is also an important concern. Land must be clear and clean, meaning free from disputes so that it does not cause problems in the future. Furthermore, industrial forest plantation land (HTI) which is indeed in accordance with its designation as a production forest can also be used for energy plantation land. How damaged or degraded the land is will determine how much biochar is used. Meanwhile, the creation of energy plantations from land conversion from protected forests / conservation forests to production forests should be prohibited, because instead of saving the environment, it will actually have a greater negative impact on the environment. So opening forest land (deforestation) for energy plantations is not recommended at all.

Cogeneration in Palm Oil Mills with Pyrolysis, Initial Steps in Biochar Production and Implementation

The analogy is like cofiring carried out in coal-fired power plants by mixing biomass fuels with a certain ratio as an effort to decarbonize the energy sector in power plants. While in palm oil mills, cogeneration with pyrolysis is an innovative initial step to enter the carbon negative era with the application of biochar, the main product of pyrolysis. And because all palm oil mills use biomass fuel for their mill operations, they are already based on carbon neutral fuel, unlike coal-fired power plants which are based on carbon positive fuels because they come from fossils.

Unlike cofiring which mixes coal and biomass fuels with a certain ratio and then burns them together in a furnace such as pulverized combustion, cogeneration is done by producing energy separately but the energy output is for the same use or especially the same boiler. This is done because the types of fuels may be different, such as solid fuels with liquid fuels or the technology for producing the energy is different. With this cogeneration, it means that not all energy is produced from one energy source or energy from cogeneration is a secondary energy source to meet total energy needs, and in the case of cogeneration in this palm oil mill, energy from combustion is still the primary energy.

Then why not just do full pyrolysis? It is easier, gradually for palm oil mills to adopt pyrolysis technology and its characteristics. Because (slow) pyrolysis aims to maximize solid / biochar, the by-products in the form of excess energy (syngas and biooil) as a source of boiler fuel, the calorific value is not as much as combustion which is indeed intended to maximize heat. Only about 1/3 of the excess energy contributes (cogeneration) as boiler fuel. In other words, if full pyrolysis is carried out directly, the amount of biomass as raw material for pyrolysis becomes 3 times greater or the pyrolysis unit becomes very large so that all palm oil mill biomass waste is used, and the mill cannot sell its palm kernel shells.

What are the benefits obtained by palm oil mills if they carry out cogeneration with pyrolysis for biochar production? Among the biochar products, it can save fertilizer use in oil palm plantations, overcome the problem of empty oil palm bunches (EFB) so that palm oil mills can achieve zero waste, palm kernel shells (PKS) that have been used for boiler fuel can be sold to increase income, the productivity of fresh fruit bunches (FFB) of palm oil increases, the application of biochar in palm oil plantations is also a climate solution (carbon sequestration / carbon sink) so that it can get carbon credit compensation and with good waste management, even zero waste and the application of biochar in palm oil plantations, palm oil companies will get a good image in terms of the environment and sustainability.  

Urgency of Biochar Production Industrial Capacity

The provision or application of biochar to agricultural land follows the 4Rs rule, namely the right source (appropriate biochar raw material), right place (appropriate application area), right rate (appropriate dosage) and right timing (appropriate time). The physical and chemical properties of biochar differ depending on the raw material and production process. By following the 4R rules, biochar performance can be maximized. The effect of biochar on plants will be clearly visible (significant) when the 4R rules are met. With a dose / rate reaching 20 tons / ha (depending on the influencing condition factors), the need for biochar is also large. This is why biochar products are rarely sold online, namely because of the large volume.

Unlike soil amendments such as compost, the effects of biochar can be felt for quite a long time or for several types of agricultural crops, namely not only in one planting season, but repeatedly. This also makes the provision or application of biochar not as frequent as compost. And in the end, of course, the economic aspect is a determining parameter whether biochar makes agricultural businesses more profitable or not. The price of biochar on the market is an important concern for users or farmers.

The lack of biochar production in Indonesia is currently a barrier to biochar application in large agricultural lands, even when farmers' awareness of biochar is also increasing. This is the driving force for the importance of adequate biochar production, especially industrial capacity. Only with adequate biochar production can biochar application in agricultural lands or degraded lands be carried out optimally. The urgency of industrial capacity biochar production is even greater, especially when the biochar production also gets carbon credit, of course this will be even more interesting. 

Biochar and Food & Energy Security

As the population increases, so does the need for food and energy. This is why food and energy production must also be increased. Increasing food production is closely related to the quality and quantity of land. However, although the quantity of land is very large, its quality tends to decline so that plant productivity automatically also decreases. The decline in land quality or land damage occurs on very large areas of land up to millions of hectares. With the area of ​​sub-optimal and degraded lands reaching hundreds of millions of hectares consisting of 122.1 million hectares of dry land; 8 million hectares of post-mining land; 24.3 million hectares of critical land; a total of around 154.4 million ha, it can be said that the potential loss of food products also reaches millions of tons. Meanwhile, damaged land will be further damaged if no repair efforts are made. Efforts to upgrade or improve the quality of this land should be an important priority in efforts to achieve food and energy security.

Biochar application is a solution for improving these lands. Raw materials for biochar production are also very abundant, including dry palm oil EFB of around 30 million tons/year, bagasse of 2 million tons/year, corn cobs of 5 million tons/year, cassava stalks of 3 million tons/year, waste wood of 50 million tons/year, rice husks of 15 million tons/year, cocoa shells and so on. With the application of biochar, agricultural productivity can increase by an average of 20% or even up to 100%. If applied on a macro or national scale, say with a 20% increase in production, for example, rice production will increase to 36 million tons/year from the previous 30 million tons/year, corn will increase to 18 million tons/year from the previous 15 million tons/year, crude palm oil or CPO to 60 million tons/year from the previous 50 million tons/year. This will save land use so that the opening of forest land for food crops and (bio)energy such as food estates may not be necessary or at least slow it down. But why until now has biochar not received attention and been used as a solution?

In addition, biochar production with pyrolysis will also produce a number of by-products that can be used for energy applications or others, as in the diagram above. Many agro-industries require drying in their production processes, so this is an additional advantage of using pyrolysis technology for biochar production. While from the environmental aspect, biochar is also a carbon sequestration so that it is a climate solution and can get carbon credit. Likewise in waste management, because the raw material for biochar is biomass waste from agriculture, plantations and forestry, even from organic waste, the pyrolysis and biochar business is also a solution to this problem.   

Optimizing Pyrolysis and Biochar in the Palm Oil Industry

Indonesia's CPO production currently reaches around 50 million tons per year with a land area of ​​around 17.3 million hectares. This means that the average CPO production per hectare is only 2.9 tons or per million hectares produces 2.9 million tons. If biochar is used and there is a 20% increase, it means there is an increase of 10 million tons of CPO per year and this is equivalent to saving around 3.5 million hectares of land, or the use of biochar will slow down forest clearing (deforestation) for palm oil plantations.

The average speed of Indonesian palm oil plantation area is 6.5% per year or equivalent to about 1 million hectares per year for the last 5 years, while the increase in palm oil fruit production or FFB (fresh fruit bunches) is only 11% on average. Even the largest expansion of palm oil land occurred in 2017, which increased by 2.8 million hectares. By opening 1 million hectares of forest, national CPO production only increased by 11%, while without the need to open forests, namely with the application of biochar, there could be a 20% increase in productivity. And the 20% increase in FFB yield (fresh fruit bunches) using biochar is a low estimate.

With the number of palm oil mills in Indonesia reaching more than 1000 units and tens of millions of tons of biomass waste, especially empty palm fruit bunches (EFB), the volume of biochar production produced is certainly very large. In addition, pyrolysis technology can replace combustion technology which is generally used in palm oil mills to produce steam for electricity production and sterilization of fresh fruit bunches (FFB) in CPO production. With pyrolysis raw materials using palm oil tankos and being able to replace palm kernel shells, 100% of palm kernel shells (PKS) can be sold or exported. The sale of palm kernel shells or PKS (palm kernel shells) will certainly provide additional attractive benefits for the palm oil company. Palm kernel shells or PKS are the main competitors of wood pellets in the global biomass market.

In addition, the use of biochar also saves fertilizer use and the highest operational cost on oil palm plantations is fertilizer so this is very relevant. Tens of billions of costs spent on fertilizer can be reduced by using biochar, especially since the biochar comes from its own waste so that it will automatically become a solution for biomass waste management. Including biopesticides and liquid organic fertilizers can also be produced from the pyrolysis process. Carbon credit is the next business potential. This is because the application of biochar to the soil for agriculture or plantations is an effort for carbon sequestration / carbon sink.

The benefits that can be obtained from this biochar carbon credit are also large, even globally biochar carbon credit ranks first or more than 90% in Carbon Dioxide Removal (CDR) recorded in cdr.fyi. However, there are indeed many large biochar producers who do not sell their carbon credits because of the methodological requirements of standard carbon companies such as Puro Earth and Verra, and these biochar producers are comfortable with their biochar sales business, especially since these producers have existed (established) since before carbon credits were available for biochar.    

Maximizing the Rate of CO2 Absorption from the Atmosphere Based on Biomass

Maximizing the rate of CO2 absorption from the atmosphere is very important considering the rate of addition of CO2 concentration to the atmosphere is not comparable to the rate of CO2 absorption. This is what makes the CO2 concentration continue to increase. To balance this speed, a strategy is needed to increase the rate of CO2 absorption. The use of biomass will be very effective and provide multiple benefits for human life. 

CO2 from the atmosphere needs to be captured through biomass production through the process of photosynthesis in plants. Fast-growing species of plants that have high photosynthesis rates are needed for this. Furthermore, biomass, especially wood from fast-growing species of plants, is used as raw material for biochar. Furthermore, biochar is used to improve soil fertility (soil amendment) in various types of agricultural and forestry plants.

Biochar production with slow pyrolysis will also produce excess heat, syngas and biooil that can be used as energy sources. The benefits of biochar production will be obtained from the sale of biochar, the sale of carbon credits and the use of slow pyrolysis by-products. With conditions like this, efforts to increase the speed of CO2 absorption from the atmosphere should be increased. How fast and how much CO2 volume can be absorbed will depend on the type of fast growing species used, the area of ​​planting and the capacity of biochar production.

Biochar from Wood Waste and Forestry Waste

The era of decarbonization and bioeconomy continues and continues to grow over time. While some people focus on the carbon neutral sector such as the production of biomass fuels such as wood pellets, wood briquettes or wood chips, people who focus on negative carbon seem to be fewer, including the use of CCS (Carbon Capture and Storage) and biochar production. Compared to CCS, biochar production with pyrolysis is easier and cheaper so it is projected to become a future trend. Logically, the negative carbon scenario is actually much better because in addition to reducing the concentration of CO2 in the atmosphere, while the neutral carbon scenario only does not increase CO2 emissions in the atmosphere, but does not reduce or absorb CO2 in the atmosphere. CO2 sequestration or biochar carbon removal (BCR) is currently also the most industrially relevant carbon removal technology. BCR is a key solution for real climate change mitigation today and its development is very rapid. BCR also has a vital role in the carbon removal technology portfolio. 

 

Woody biomass, especially from wood industrial waste and forestry waste, is a potential raw material for biochar production, even this type of wood biomass is the best raw material because it can produce high quality biochar, namely fixed carbon of more than 80%. The potential for wood biomass raw materials in Indonesia is very large, estimated at 29 million m3/year from forest harvesting waste, and 2 million m3/year from wood processing industry waste including 0.78 million m3 in the form of sawdust (the yield of the sawmill industry ranges from 50-60% and as much as 15-20% consists of sawdust). And that does not include if there is a biomass plantation or energy plantation dedicated to biochar production.

With the condition of agricultural land, plantations and forestry which are experiencing a lot of degradation, the need for biochar is also very large. Among the factors causing the decline in land fertility is the use of chemical fertilizers and pesticides for decades continuously and tends to be excessive. This causes a decline in soil quality which has an impact on crop production because it makes the land more acidic and hard which is estimated to reach millions of hectares. In addition, the price of chemical fertilizers is increasingly expensive and difficult to obtain, which results in low agricultural production, so the government is forced to import several agricultural commodities to meet the needs of the community. This actually does not need to happen considering the potential land in Indonesia is very large, it only needs to improve the condition of the land so that it can be optimal again. Making damaged land fertile is not difficult, it only takes perseverance to repair and care for the land so that it continues to be fertile.

Meanwhile, dry land consists of ultisol soil of 47.5 million ha and oxisol of 18 million ha. Indonesia has a coastline of 106,000 km with a potential land area of ​​1,060,000 ha, generally including marginal land. Millions of hectares of marginal land are spread across several islands, have good prospects for agricultural development but are currently not well managed. The land has a low fertility rate, so technological innovation is needed to improve and increase its productivity. Not to mention post-mining land which is almost all very damaged and also covers millions of hectares. And biochar is the right solution that can restore the condition of the land to be fertile again. 

Slow pyrolysis is the best technology for biochar production. But the technology used must be efficient and emissions meet the threshold standards of the country concerned. In addition, excess heat and/or liquid products and gas products from pyrolysis should also be utilized. With the criteria for pyrolysis technology as above, in addition to the quality and quantity of products, namely biochar, can be maximized, the production process also does not cause new problems in the form of environmental pollution. This is very much in line with biochar business activities so that it becomes a solution to the problem of industrial biomass waste from wood and forestry waste as well as a solution to climate problems. Even the utilization of by-products (excess heat and/or liquid products and gas products from pyrolysis) can also encourage the emergence of other environmentally friendly and renewable products.

In economic terms, the outline can be as follows, namely with an investment of 10 million US dollars, approximately 200,000 tons of biochar with more than 400,000 carbon credits will be produced over a period of 10 years. Or if with an investment of 100 million US dollars, almost 2 million tons of biochar and more than 4 million carbon credits will be produced over a period of 10 years. And for example, with a selling price of biochar of 100 dollars per ton and also a carbon credit of 100 dollars per unit (per ton of CO2), then within 10 years the investment has increased 6 times or it only takes about 1.7 years for the initial investment to return (payback period). Of course, when the price of biochar is higher and / or its carbon credits, of course the return on capital will be faster. And that does not include the utilization of liquid and gas products from pyrolysis and excess heat which also have economic potential that is no less interesting. The trend of the future business era will not only focus on financial profit but also provide solutions to environmental problems and climate problems, and of course solutions to social problems by creating jobs.    

Increasing Food Agriculture Productivity: Biochar Application or Forest Clearing for Food Estate?

Indonesia currently ranks 69th out of 113 countries in 2022 in food security and this is lower than Malaysia and Vietnam with indicator points below the global average. This condition is concerning considering that Indonesia was once self-sufficient in food before and even the price of rice in Indonesia is the most expensive in ASEAN. Efforts to maintain food productivity are indeed a challenge, let alone increasing it. Along with increasing population growth, the need for food automatically increases. The condition of declining food production and productivity is related to a number of factors including land conversion to non-agricultural land, and soil / land damage. A number of regulations have been made to stem the rate of decline in food productivity due to these two things.

Regarding land damage, repair efforts need to be made so that agricultural productivity increases. It is estimated that the area of ​​land damage that occurs is very large with a high level of severity. This requires gradual and sustainable repair efforts with various strategies including improving farming patterns and even a number of incentives. Only with these efforts can the agricultural sector as a source of food be repaired or if not, the damage to agricultural land will get worse so that repair efforts will be more difficult.

Biochar application or forest clearing for food estate ?
Biochar application will be able to repair damaged lands. In addition to being a slow-release fertilizer agent so that fertilizer use becomes efficient and does not pollute the environment, increasing soil pH, increasing soil organic carbon and increasing agricultural productivity, biochar will also help overcome the management of agricultural waste that has so far polluted the environment. The increase in agricultural productivity from the use of biochar is on average around 20%. If Indonesia's current rice production is around 31 million tons per year, then the application of biochar will increase total rice production to 37.2 million tons (an increase of 6.2 million tons). With an average rice production per hectare of 6 tons, the increase of 6.2 million tons is equivalent to increasing the area of ​​agricultural land by 1.03 million hectares. Even damaged land from post-mining can be reclaimed and rehabilitated with the application of biochar, with the land area also reaching millions of hectares. This is certainly better than clearing new forest land for food estates because of its environmental impact. 

As the human population grows, the need for food and energy will continue to increase. Indonesia's population in 2045 is estimated to reach 319 million people and the world's population in 2050 is approaching 10 billion people. The need and urgency of biochar to improve soil quality is increasing. Tens of millions of hectares of all Indonesian acidic soils, which are classified as dry land acidic soils, need to be improved with biochar. This means that the business potential reaches billions of dollars or trillions of rupiah. Meanwhile, rice imports in 2024 are targeted to reach 3.6 million tons (as a buffer), a large amount. With an annual rice requirement of around 31 million tons, the contribution of imported rice reaches more than 10%.

Biochar in addition to repairing soil damage so that it increases its fertility which ultimately increases agricultural productivity is also part of the climate solution, namely by means of carbon sequestration. Biochar applied to the soil will last hundreds or even thousands years, and does not decompose. This is another advantageous factor for biochar producers, namely getting carbon credits. The quality of biochar will determine the acquisition or price of the carbon credit, so that the raw materials of biochar and its production process are affected. The price of carbon credits is increasing so that it is increasingly attractive and also the carbon credit market continues to grow.

Damage to land or agricultural land that occurs is mostly caused by excessive use of chemical fertilizers. If the use of chemical fertilizers can be reduced in dosage or with sufficient use, there will be improvements in land quality. Even if chemical fertilizers are gradually reduced in dosage and organic fertilizers / compost are increasingly added so that in the end chemical fertilizers are not used at all, soil fertility will be optimal as well as agricultural productivity.

The photo from here

Of course, this requires time and continuous effort. Livestock must also be encouraged so that compost / organic fertilizer can also be produced sufficiently from the processing of livestock manure. Integrated farming with livestock is the best solution for improving agricultural land with biochar, especially increasing the efficiency of fertilization. If the above can be implemented properly, then forest clearing for food estate land can also be slowed down / held back by considering all aspects comprehensively so that it is not a short-term solution that tends to be forced, and rushed because of the regime's image efforts even at a cost of hundreds of trillions.     

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.     

The Urgency of Ex-Coal Mine Reclamation With Biochar

The large number of ex-coal mines that are not reclaimed causes various environmental problems and even life safety. There have been many casualties from the former coal mine pit. The simple logic should be that after the coal deposit is taken or extracted during the mining activity, the land is returned and repaired so that the quality is better than before the mining activity or at least the same, but not worse so that various environmental problems arise. The era of decarbonization is accelerating because of the driving force of climate change and global warming. Fossil fuels, especially coal, are starting to be abandoned, of course, including the coal mining activity itself. Meanwhile, the area of former coal mines which reaches millions of hectares is a lot of environmental problems today.

When the quality of the soil is improved so that it has high fertility then this becomes a very extraordinary potential so that a number of important activities can be carried out, such as agriculture, animal husbandry and forestry. With such conditions, the effort to self-sufficiency or food sovereignty is not impossible. Technically, it can be analyzed which of the agricultural, livestock and forestry sectors can reach the goal faster, namely food independence or sovereignty. But before going far and doing business on the ex-mining land, to be more specific what products will be made, the basic question is how to improve the condition of the damaged soil and the scale is also massive?

The application of biochar to the soil is a surefire solution in an effort to repair damaged soils. Depending on how severe the damage is, the characteristics of the soil type and the final quality level being targeted will determine the application or dosage of the biochar. In addition to improving the soil, the biochar application also absorbs CO2 from the atmosphere, thereby reducing the concentration of CO2 from the atmosphere or is a carbon negative scenario. Biochar buried in the soil becomes a carbon sink, similar to creating a conservation forest to absorb CO2 from the atmosphere. How much biochar is buried so that it can be calculated that the CO2 absorbed into the carbon sink can be sold on the carbon market and get carbon credit. Biochar itself is able to last in the soil for hundreds of years and is not decomposed for a long time. Even when the land has been repaired with biochar and then a conservation forest is made on it, the carbon credit obtained are double, namely from the application of biochar itself and from the conservation forest. But once again, of course, economic factors are another important consideration, so as above, after soil fertility is improved with biochar, there are a number of options for using the land. Of course which one provides the best economic benefits will be the choice.

Millions of hectares of land can be recovered so that its benefits will be maximized. Say, for example, that one million hectares of land can be recovered and then used for activities that support food security or self-sufficiency such as agriculture and animal husbandry, then how much output can be calculated. Even better if there can be a surplus of food production so that it can export. Or even in the longer term, the land is reforested into conservation forest, so how much CO2 can be absorbed by the forest plus the application of biochar. Of course very much. Then why have to build a food estate but have to clear forest land, while there are other better ways? Namely not only restoring but improving the condition of the land even better before the coal mining activity was carried out.  

Carbon Farming For Palm Oil Plantation Part 2

Leading plantations and agronomist are searching for better ways to manage land for higher production and healthier profit, as well as a buffer against Climate Change. Soil Health is widely recognized as the key to these benefits, and Soil Carbon is the key to Soil Health.

Carbon Farming is the land management system that is the most effective in responding to Climate Change. It can be used to build a buffer against higher temperatures and lower rain fall. It can cut input costs as it taps into the nutrient reserves and productive capacity hidden in the soil. Carbon farming is the only way to increase soil carbon which the engine room of growth in Agriculture. 

photo taken from here

Increasing soil carbon is likely to enhance the long term sustainability of farms as it plays a central role in the physical, chemical, and biological health of the soil and hence the productive capacity of arable soils. Increasing the biomass input, decreasing the decomposition rate and increasing the potential of a soil to store carbon will all act to increase soil carbon. Soils with the greatest potential to sequester carbon will be those that have suffered a  significant loss of carbon with clearing of native vegetation and have a capacity to increase biomass production or can protect added carbon from decomposition (Baldock et al 2009).


Farmers wanting to build soil carbon may be able to achieve this though maintaining and enhancing vegetation cover, maximizing vegetation growth, minimizing soil disturbance, and changing the soil texture. Activities that broad acre farmers may consider to increase soil carbon include :

·        -Converting cropping land to productive pastures and increasing the pasture phases in crop rotation

·         -Increasing practices to retain stubble

·         -Green manuring, particularly legume crops

·         -The application of soil ameliorants such as biochar, compost, or manure  (Sanderman et al 2010), and

·         -Alterations to soil texture through the addition of clay to lighter textured soils.

Photo taken from here

Palm oil industry in Indonesia & Malaysia which in operations generate a lot of waste biomass and on the other hand requires energy in the form of heat and electricity for the process of the fruits and high productivity of palm oil plants, then very potential to apply the continous slow pyrolysis technology to get energy and biocharnya to carbon farming.

photo's taken from here

Carbon farming is a different way of looking at your land. It gives you a different set of priorities, if you get it right, it can deliver everything you ever wanted to get out of farming. And more…..

The Importance Of Standard Biochar

Biochar and charcoal are similar materials with different purposes. Charcoal, a fuel and metal reductant,is considered to be the oldest man-made material. The advantage of charcoal is that it burns with less smoke, which is advantageous when cooking indoors. In addition, charcoal burns hotter than wood, which allows it to be used for metal forming, such as in blacksmithing.

Adsorption is a pivotal property that distinguishes biochar from other carbon-rich natural products. Adsorption also distinguishes superior biochars from less effective “agricultural charcoals”. Since biochar is so new, there are no analytical methods developed specifically to measure adsorption in biochar, nor any experience base to relate adsorption to biochar impact when added to growing system. Thus,  urgently needed the standard biochars. Following paper will give analytical options for biochar adsorption and surface area, please go here.

Three Motivations For Biomass Thermal Conversion

At least, three motivating factors on biomass thermal conversion, like is mentioned below :

A.    Renewability Benefit
Fossil fuel like coal, oil and gas are good and convenient source of energy, and they meet the energy demands of society very effectively. However, there is one major problem: Fossil fuel resources are finite and not renewable.Biomass on the other hand, grows and is renewable. A crop cut this year will grow again next year; a tree cut today may grow up within a decade. Unlike fossil fuel, then, biomass is not likely to be depleted with consumption. For this reason, its use, especially for energy production, is rising fast.

We may argue against cutting trees for energy because they serve as a CO2 sink. This is true, but a tree stops absorbing CO2 after it dies. On the other hand, if left alone in the forest it can release CO2 in a forest fire or release more harmful CH4 when it decomposes in water. The use of a tree as fuel after its life provides carbon-neutral energy as well as avoids greenhouse gas release from deadwood. The best option is new planting following cutting, as is done by some pulp industries. Fast-growing plants like switch grass and Miscanthus are being considered as fuel for new energy projects. These plants have very short growing periods that can be counted in months.

B.    Enviromental Benefit
With growing evidence of global warming, the need to reduce human-made greenhouse gas emissions is being recognized. Emission of other air pollutants, such as NO2, SO2, and Hg, is no longer acceptable, as it was in the  past. In elementary schools and in corporate boardrooms, the environment is a major issue, and it has been major driver for biomass thermal conversion such as pyrolysis for energy production. Biomass has a special appeal in this regard, as it makes no net contribution to carbondioxide emission to the atmosphere.

Regulations for making biomass economically viable are in the place in many countries. For example, if biomass replace fossil fuel in a plant, that plant earns credit for CO2 reduction equivalent to what the fossil fuel was emitting. This credits can be sold on the market for additional revenue in countries where such trades are in practice.

Carbon Dioxide Emissions
When burned, biomass release the CO2 it absorbed from the atmosphere in the recent past, not millions of years ago, as with fossil fuel. The net addition of CO2 to the atmosphere through biomass combustion is thus considered to be zero.

Sulfur Removal
Most virgin or fresh biomass contains little to no sulfur. Biomass-derived feedstock such as municipal solid waste (MSW) or sewage sludge does contain sulfur, which requires limestone for capture of it. Interestingly, such derived feedstock also contains small amounts of calcium, which intrinsically aids sulfur capture.

Nitrogen Removal
A combustion system firing fossil fuel can oxidize the nitrogen in fuel and in air into NO, the acid rain precursor, or into N2O, a greenhouse gas. Both are difficult to remove. In a pyrolysis system, nitrogen appears as either N2 or NH3, which is removed relatively easily in the syngas-cleaning stage.
Nitrous oxide emission results from the oxidation of fuel nitrogen alone. Measurement in a biomass combustion system showed a very low level of N2O emission (Van Loo and Koppejan, 2008, p.295)

Dust and Other Hazardous Gases
 Highly toxic pollutants like dioxin and furan, which can be released in a combustion system, are not likely to form in an oxygen-absenced pyrolyzer. Particulate in the syngas is also reduced significantly by multiple gas clean up systems.

C.    Sociopolitical Benefit

The sociopolitical benefits of biomass are substantial. For one, biomass is locally grown resource. For one, biomass is a locally grown resource. For a biomass-based power plant to be economically viable, the biomass needs to come from within a certain distance from it.  This means that every biomass plant can prompt the development of associated industries for biomass growing, collecting, and transporting.
Some believe that a biomass fuel plant could create up to 20 times more employment than that created by a coal-or oil-based plant (Van Loo and Koppejan, 2008, p.1).  The biomass industry thus has a positive impact on the local economy.

Another very important aspect of biomass-based energy, fuel, or chemicals is that they reduce reliance on imported fossil fuels. The volatile global political landscape has shown that supply and price can change dramatically within a short time, with a sharp rise in the price of feedstock. Locally grown biomass is relatively free from such uncertainties.