Bokashi (horticulture) explained

Bokashi is a process that converts food waste and similar organic matter into a soil amendment which adds nutrients and improves soil texture. It differs from traditional composting methods in several respects. The most important are:

Other names attributed to this process include bokashi composting, bokashi fermentation and fermented composting.

Nomenclature

The name bokashi is transliterated from spoken Japanese (Georgian: ぼかし). However, Japanese-English dictionaries give the word an older artistic meaning: "shading or gradation" of images – especially applied to woodblock prints.[1] [2] This later extended to mean pixellation or fogging in censored photographs. Therefore, its application to fermented organic matter is of uncertain origin; if both uses are related, unifying concepts may be "alteration" or "fading away".

Bokashi as a food waste process is borrowed in many other languages. As a noun, it has various meanings depending on context, in particular the process itself, the inoculant and the fermented output. This variety can lead to confusion. As an adjective, it qualifies any related noun, such as bokashi bin (a household fermentation vessel), bokashi soil (after adding the preserve), and even bokashi composting – a contradiction in terms.

Process

The basic stages of the process are:

  1. Organic matter is inoculated with yeast, photosynthetic bacteria, and lactic acid bacteria.[3] These will convert a fraction of the carbohydrates in the input to lactic acid by homolactic fermentation.[4]
  2. Fermented anaerobically (more precisely, microaerobically)[5] for a few weeks at typical room temperatures in an airtight vessel, the organic matter is preserved by the acid, in a process closely related to the making of some fermented foods and silage. The preserve is normally applied to soil when ready, or can be stored unopened for later use.
  3. The preserve is mixed into soil that has naturally occurring micro-organisms.
  4. When water is present (as in the preserve itself or in the soil) the lactic acid progressively dissociates by losing protons to become lactate – the acid's conjugate base or ion salt.[6] Lactate is a fundamental energy carrier in biological processes. It can pass through cell membranes and almost all living organisms have the enzyme lactate dehydrogenase to convert it to pyruvate for energy production.
  5. Suffused with lactate, the preserve is readily consumed by the indigenous soil life, primarily the bacteria, 'disappearing' within a very few weeks at normal temperatures. Earthworm action is typically prominent as bacteria are themselves consumed, such that the amended soil acquires a texture associated with vermicompost.

Characteristics

Accepted inputs

The process is typically applied to food waste from households, workplaces and catering establishments, because such waste normally holds a good proportion of carbohydrates. It is applied to other organic waste by supplementing carbohydrates and hence lactic acid production. Recipes for large scale bokashi in horticulture often include rice, and molasses or sugar.[7] [8] Any carbohydrate-poor waste stream would benefit from this.

Homolactic fermentation can process significantly more kinds of food waste than home composting. Even items considered problematic in traditional composting, such as cooked leftovers, meat and skin, fat, cheese and citrus waste are, in effect, pre-digested to enable soil life to consume them. Large pieces may take longer to ferment and concave surfaces may trap air, in which cases cutting down is advised in support literature.[9]

Pieces of input are discarded if they are already badly rotten, or show green or black mould. These harbour putrefying organisms which may overwhelm the fermentation.

Emissions

Carbon, gases and energy

Homolactic fermentation and similar anaerobic fermentation pathways in general provide a very small amount of energy to the cell compared to the aerobic process. In homolactic fermentation, 2 ATP molecules are made when one glucose molecule (produced by digesting complex carbohydrates) is converted to 2 lactic acid molecules,[10] only of what aerobic respiration provides.[11] The process will also halt before all available carbohydrates are used, as the acidity ends up inhibiting all bacteria. As a result, a bokashi bucket barely heats up and remains at ambient temperature.

As a waste processing technique, bokashi is notable in that minimal loss of mass in the form of offgassing happens. Compost, which is aerobic, "burns up" much of the carbon into carbon dioxide to sustain the metabolism of microbes as it matures. Biogas production does not burn the carbon, but the bacterial culture is optimized to extract the carbon in the form of methane – a potent greenhouse gas and a useful fuel. In addition, compost can also lose the key plant nutrient nitrogen (in the potent greenhouse gas nitrous oxide and in ammonia), while bokashi almost does not.[12]

Runoff

When fermentation begins, physical structures start to break down and release some of the input's water content as a liquid runoff. Over time this constitutes more than 10% of the input by weight. The quantity varies with the input: for example cucumber and melon flesh lead to a noticeable increase.

The liquid leaches out a valuable fraction of proteins, nutrients and lactic acid. To recover them, and to avoid drowning the fermentation, runoff is captured from the fermentation vessel, either through a tap, into a base of absorbent material such as biochar or waste cardboard, or into a lower chamber. The runoff is sometimes called "bokashi tea".

The uses of bokashi tea are not the same as those of "compost tea". It is used most effectively when diluted and sprinkled over a targeted area of soil to feed the soil ecosystem. Dilution makes it less acidic and thus less dangerous to plants. Dilution also causes more acid to convert into lactate which is an attractive food for soil microbes. Other uses are either potentially damaging (e.g. feeding plants with acidic water) or wasteful (e.g. cleaning drains with plant nutrients, feeding plants with nutrients in a form they cannot take up).

Volumes

Household containers ("bokashi bins") typically give a batch size of . This is accumulated over a few weeks of regular additions. Each regular addition is best accumulated in a caddy, because it is recommended that one opens the bokashi bin no more frequently than once per day to let anaerobic conditions predominate.

In horticultural settings batches can be orders of magnitude greater.[12] Silage technology may be usable if it is adapted to capture runoff. An industrial-scale technique mimics the windrows of large-scale composting, except that bokashi windrows are compacted, covered tightly and left undisturbed, all to promote anaerobic conditions. One study suggests that such windrows lose only minor amounts of carbon, energy and nitrogen.

Hygiene

Bokashi is inherently hygienic in the following senses:

Addition to soil

Fermented bokashi is added to a suitable area of soil. The approach usually recommended by suppliers of household bokashi is along the lines of "dig a trench in the soil in your garden, add the waste and cover over."[18]

In practice, regularly finding suitable sites for trenches that will later underlie plants is difficult in an established plot. To address this, an alternative is a 'soil factory'.[19] This is a bounded area of soil into which several loads of bokashi preserve are mixed over time. Amended soil can be taken from it for use elsewhere. It may be of any size. It may be permanently sited or in rotation. It may be enclosed, wire-netted or covered to keep out surface animals. Spent soil or compost, and organic amendments such as biochar may be added, as may non-fermented material, in which case the boundary between bokashi and composting becomes blurred.

A proposed alternative[20] is to homogenise (and potentially dilute) the preserve into a slurry, which is spread on the soil surface. This approach requires energy for homogenisation but, logically from the characteristics set out above, should confer several advantages: thoroughly oxidising the preserve; disturbing no deeper layers, except by increased worm action; being of little use to scavenging animals; applicable to large areas; and, if done repeatedly, able to sustain a more extensive soil ecosystem.

History

The practice of bokashi is believed to have its earliest roots in ancient Korea. This traditional form ferments waste directly in soil, relying on native bacteria and on careful burial for an anaerobic environment. A modernised horticultural method called Korean Natural Farming includes fermentation by indigenous micro-organisms (IM or IMO) harvested locally, but has numerous other elements too. A commercial Japanese bokashi method was developed by Teruo Higa in 1982 under the 'EM' trademark (short for Effective Microorganisms).[21] EM became the best known form of bokashi worldwide, mainly in household use, claiming to have reached over 120 countries.

While none have disputed that EM starts homolactic fermentation and hence produces a soil amendment, other claims have been contested robustly. Controversy relates partly to other uses, such as direct inoculation of soil with EM and direct feeding of EM to animals, and partly to whether the soil amendment's effects are due simply to the energy and nutrient values of the fermented material rather than to particular microorganisms.[22] Arguably, EM's heavy focus on microorganisms has diverted scientific attention away from both the bokashi process as a whole and the particular roles in it of lactic acid, lactate, and soil life above the bacterial level.

Alternative approaches

Some organisms in EM, specifically photosynthetic bacteria and yeast, appear to be logically superfluous, as they will first be suppressed by the dark and anaerobic environment of homolactic fermentation, then killed by its lactic acid. Consequently, practitioners have sought to reduce costs and to widen the scale of operations. Success has been reported with:

Uses

The main use of bokashi that is described above is to recover value from organic waste by converting it into a soil amendment.

In Europe, food and drink material that is sent to animal feed does not legally constitute waste because it is regarded as 'redistribution.'[28] This may apply to bokashi made from food, because it enters the soil food web, and furthermore is inherently pathogen-free.

A side effect of diverting organic waste to the soil food web is to divert it away from local waste management streams and their associated costs of collection and disposal. To encourage this, for example most UK local authorities subsidise household bokashi starter kits through a National Home Composting Framework.[29]

Another side effect is to increase the organic carbon content of the amended soil. Some of this is a relatively long-term carbon sink – insofar as the soil ecosystem creates humus – and some is temporary for as long as the richer ecosystem is sustained by measures such as permanent planting, no-till cultivation and organic mulch. An example of these measures is seen at the in France.[30] Bokashi would therefore have potential uses in enabling communities to speed up the conversion of land from chemical to organic horticulture and agriculture, to regenerate degraded soil, and to develop urban and peri-urban horticulture close to the sources of input.

The anti-pathogenic nature of bokashi is applied to sanitation, in particular to the treatment of faeces. Equipment and supplies to treat pet faeces are sold commercially[31] but do not always give prominence to the hygiene risks.[32] Treatment of human faeces for soil amendment has been extensively studied, notably with the use of biochar (a soil improver in its own right) to remove odours and retain nutrients.[33] Social acceptability is a major obstacle, but niche markets such as emergency aid sanitation, outdoor events and temporary workplaces may develop the technology into a disruptive innovation.

See also

Notes and References

  1. Web site: Tangorin Dictionary. 9 January 2019.
  2. Web site: Meaning of bokashi in Japanese. RomajiDesu.
  3. Web site: Effect of Microaerobic Fermentation in Preprocessing Fibrous Lignocellulosic Materials .
  4. Yamada. Kengo. Xu. Hui-lian. 2000. Properties and Applications of an Organic Fertilizer Inoculated with Effective Microorganisms. Journal of Crop Production. 3. 255–268. ResearchGate. 10.1300/J144v03n01_21. 73574288.
  5. Alattar . MA . Green . TR . Henry . J . Gulca . V . Tizazu . M . Bergstrom . R . Popa . R . Effect of microaerobic fermentation in preprocessing fibrous lignocellulosic materials. . Applied Biochemistry and Biotechnology . June 2012 . 167 . 4 . 909–17 . 10.1007/s12010-012-9717-5 . 22639359 . 13497839 .
  6. Web site: Lactic acid and Lactate. 19 Aug 2021. Lactic Acid. 19 August 2021. https://web.archive.org/web/20210819094625/https://www.lactic-acid.com/lactate_and_lactic_acid.html. dead.
  7. Web site: February 2017. Bokashi du Costa Rica – Recette. 5 October 2021. Alterculteurs. https://web.archive.org/web/20190114044510/https://www.alterculteurs.net/2017/02/19/bokashi-du-costa-rica-recette/. 2019-01-14.
  8. Web site: Honduras – Making Bocashi Fertilizer. January 2011. Paper Bokashi. 9 January 2018.
  9. Web site: Can I put shells, coffee grounds, egg shells, and large items into my bokashi bin?. 2020-12-15. Bokashi Living. 4 July 2016 . en-US.
  10. AP Biology. Anestis, Mark. 2nd Edition. McGraw-Hill Professional. 2006. . p. 61
  11. P. R. . The molecular machinery of Keilin's respiratory chain . Biochemical Society Transactions . 31. Pt 6 . 1095–1105 . 2003. 14641005. Rich . 10.1042/BST0311095.
  12. Web site: Fermentation (Bokashi) versus Composting of Organic Waste Materials: Consequences for Nutrient Losses and CO2 footprint. Bosch. Marlou. Hitman. Anke. Hoekstra. Jan Feersma. 2016. Agriton.nl. 17 January 2019.
  13. Book: Bacteriocins of Lactic Acid Bacteria. De Vuyst. L.. Vandamme. E.J.. Springer. 1994. 978-1-4613-6146-6. Boston, MA, USA. 91–129. Antimicrobial Potential of Lactic Acid Bacteria. 10.1007/978-1-4615-2668-1_3.
  14. Web site: Toilet Duck® Thick Liquid Toilet Bowl Cleaner. 2019. SC Johnson. 9 January 2019.
  15. Ligocka. A.. Paluszak. Z.. 2009. Effectiveness of different sanitisation technologies on the inactivation of Ascaris suum eggs in organic waste. Bulletin of the Veterinary Institute in Puławy. 53. 641–644.
  16. Web site: Can you smell that?. Foxx. D.S.. August 2009. Bokashislope. 9 January 2019.
  17. Web site: Composting without pests. Casley. Nikki. August 2015. Bokashi Living. 9 January 2019.
  18. Web site: Using your bokashi bucket. June 2016. Bokashi Direct. 9 January 2019. 27 April 2019. https://web.archive.org/web/20190427090808/https://www.bokashidirect.co.uk/news/using-your-bokashi-bucket/. dead.
  19. Web site: How to make a soil factory. Harlen. Jenny. 4 March 2013. Bokashi World. 9 January 2019.
  20. Web site: Soil Factory Using Bokashi Ferment. Pavlis. Robert. Garden Myths. 5 November 2017.
  21. Web site: The History of Bokashi & How It Works. 16 October 2012. EM Bokashi Composting. 9 January 2019.
  22. Mayer, J.. Scheid. 1. 2010. How effective are 'Effective microorganisms® (EM)' Results from a field study in temperate climate. Applied Soil Ecology. 46. 2. 230–239. 10.1016/j.apsoil.2010.08.007.
  23. Park. Hoon. DuPonte. Michael W.. August 2008. How to Cultivate Indigenous Microorganisms. Biotechnology. University of Hawaii. 9. 1–7. 10125/12174.
  24. Web site: How to Make and Use Your Own Lactobacillus Culture. 11 January 2017. Dude Grows. 9 January 2019.
  25. Web site: Paper Bokashi. 2008. "Newspaper Bokashi" Blog. 9 January 2019.
  26. Factura. H.. Bettendorf. T.. Buzie. C.. Pieplow. H.. Reckin. J.. Otterpohl. R.. Terra Preta sanitation: re-discovered from an ancient Amazonian civilisation – integrating sanitation, bio-waste management and agriculture. Water Science & Technology. May 2010. 61. 10. 2673–9. 10.2166/wst.2010.201. 20453341. https://web.archive.org/web/20160916020956/http://www.terra-preta-sanitation.net/cms/fileadmin/publications/pdf/Terra_Preta_Sanitation_WS_T_2010.pdf . 2016-09-16 . 25 August 2016. free.
  27. Web site: Recipe for Regeneration in Honduras. 25 August 2017. USC Canada. 9 January 2019. 30 September 2019. https://web.archive.org/web/20190930165226/https://www.usc-canada.org/resources/news/item/591-recipe-for-regeneration-in-honduras/591-recipe-for-regeneration-in-honduras. dead.
  28. Web site: Digest of Waste and Resource Statistics, 2018 edition. 24 May 2018. GOV.UK for Department for Environment, Food & Rural Affairs. 9 January 2019.
  29. Web site: The National Home Composting Framework. Straight Ltd (see Partners tab for local authorities). 9 January 2019. 18 January 2021. https://web.archive.org/web/20210118044104/http://www.straight.co.uk/services/the-national-home-composting-framework/. dead.
  30. Book: Hervé-Gruyer, Perrine & Charles. Vivre avec la Terre. Actes Sud. 2019. 9782330119478. Arles. 261–267. French.
  31. Web site: Pet use. Bokashi Cycle. 13 January 2019.
  32. Web site: Dog Poo Wormeries and Composting Cat & Dog Faeces (subheading "Bokashi fermentation of dog and cat faeces"). 2014. Carry on Composting. 13 January 2019. 13 January 2019. https://web.archive.org/web/20190113232344/http://www.carryoncomposting.com/142941462. dead.
  33. Book: Terra Preta Sanitation 1 – Background, Principles and Innovations. Yemaneh. Asrat. Itchon. Gina. Deutsche Bundesstiftung Umwelt. 2015. 978-3-00-046586-4. Otterpohl. Ralf. 127–132. etal.