Upon some final research, Jess has come across the nutrisoil website, that promotes the use of VCL.
Check it out here:
http://www.nutrisoil.com.au/
This page outlines the benefits that farmers have seen from using this VCL. Definitely worth a look!
http://www.nutrisoil.com.au/farmers/
Wednesday, October 16, 2013
Monday, October 14, 2013
SO, where from here?
Wormfarming is an effective waste management technique, in addition to being a good quality organic fertiliser.
From our project, we suggest that VCL be utilised as part of organic farming practices, and, although it may have strong commercial potential, further study is most certainly required. Such further study would investigate factors such as any nutrient deficiencies that standard VCL may have in its ability to support plant growth, large scale methods of production and preservation of Organic Matter, and also its potential to supplement with synthetic NPK fertiliser.
Sunday, October 13, 2013
The results of our study!
After the last couple of months working on our project, here is a brief overview of our results, compiled by Georgia. More comprehensive results to be posted soon!
Did VCL support plant growth?
YES!
Treatment with VCL increased stem and leaf development as well as root development for both soybean and lettuce plants. It resulted in increased plant height of the lettuce but did not increase the plant height of soybeans.
How effective was VCL?
VCL was significantly more effective in supporting plant growth than the controls, however it was less effective than treatment with Aquasol
Are the benefits of VCL due to its chemical composition or its microbial activity?
Both autoclaved leachate and normal leachate resulted in similar plant growth. This means that the study found the benefits of VCL are primarily due to its chemical composition, rather than microbial activity.
This is a surprising result as microbial activity is known to be crucial in supporting plant growth. Possible explanations why our experiment did not demonstrate this is as we used sand as the growth medium, its poor structure and lack of biological activity may not have provided an environment that would benefit from microbial activity. Also, the short timeframe of our study may have not been sufficient to demonstrate a significant benefit of microbial activity for plant growth.
Was there any differences between plants treated with the normal leachate and the autoclaved leachate?
Plants treated with the autoclaved leachate resulted in slightly greater above ground weights than the normal leachate. This may have occurred because sterilisation can increase the bioavailability of micronutrients and hence increase plant growth.
Also, plants treated with normal leachate resulted in a greater total fresh weight than plants treated with autoclaved leachate. This indicates that microbial activity may support plant growth that has better water uptake and water holding capacity.
Wednesday, October 9, 2013
Quick survey!
Hey guys,
If you have a spare minute, it would be great if you'd be able to fill out our super-brief survey:
http://www.surveymonkey.com/s/DJZP6Z8
It will literally take you less than one minute, and will help us out enormously!
Thanks everyone!
If you have a spare minute, it would be great if you'd be able to fill out our super-brief survey:
http://www.surveymonkey.com/s/DJZP6Z8
It will literally take you less than one minute, and will help us out enormously!
Thanks everyone!
Monday, September 30, 2013
Pot trial results processing! 2 weeks till due date
This morning, Jono, Georgia and Polly met at the poly house, as the end of the pot trial had finally arrived!
Gathering results involved counting the number of leaves on each plant, measurement of plant heights, then the removal of sand from all pots. After this step, photos were taken for comparative purposes, then above/below ground mass measured.
Later in the day, dry weights were measured.
Below are some photos from the day. More will be posted when results are interpreted.
Final result of the 40 pots
Lettuces
Soybeans
Gathering results involved counting the number of leaves on each plant, measurement of plant heights, then the removal of sand from all pots. After this step, photos were taken for comparative purposes, then above/below ground mass measured.
Later in the day, dry weights were measured.
Below are some photos from the day. More will be posted when results are interpreted.
Final result of the 40 pots
Lettuces
Soybeans
Monday, September 16, 2013
FAQs - The basic science
Recently, when we have been telling people about our project, we have been getting the same responses back. Therefore, Georgia kindly compiled the following:
1. What is vermicomposting and vermicompost
leachate?
Vermicomposting, also known as
wormfarming, is a waste management technique using worms to transform organic
waste into biologically-rich manure (Carlos et al, 2008). Vermicompost leachate
(VCL), or ‘worm tea’, is the liquid released by earthworms (Kandari et al,
2011). VCL is said to stimulate plant nutrient uptake and support plant
development due to the humic acids, fluvic acids and plant growth regulators it contains. (Carlos et al, 2008).
2. What is the aim of your experiment?
Our experiment aims to determine if VCL is more effective fertiliser compared to an inorganic equivalent, which, in our case, is Aquasol.
3. Why are you using aquasol?
We chose to
use aquasol as it is a common purely synthetic fertiliser, which means it has
no biological component. Other common commercial fertilisers such as Seasol and Nitrosol were not chosen, as they are organically based (from seaweed extract and blood and bone respectively) have growth promoters added (Zodape, 2001).
4. Why are you growing lettuce and soybean
plants?
As nitrogen is the key element in
most fertilisers, we chose test the effectiveness of VCL and Aquasol on a nitrogen fixing
plant (soybean) as well as a non-nitrogen fixer (lettuce) that is common in urban gardens. These plants
were also chosen due to their rapid growth to suit our study’s limited timeframe.
5. Why are you growing the plants in sand?
Soil structure has a great affect on plant growth as it
influences the movement of water, air and nutrients to plants (Charman and
Murphey, 1992). As we did not want any differences in soil structure between pots, sand is being used, as it has very low inherit biological activity, and little to no structure.
6. What is the difference between normal
leachate and autoclaved leachate?
As vermicomposting is an organic process,
VCL contains both a biological component (micro-organisms) and a
chemical component. Autoclaving is a process of sterilising, or killing the
biological component that would be present. By comparing plants grown with normal leachate and
autoclaved leachate, this will show us if VCL’s fertilising ability is due to
its inherit biological activity, or if it is the chemical composition alone, that makes it a viable fertiliser.
7. Why are some of the plants being only
given water?
As with any scientific investigation, there are control plants being grown, that are only receiving water daily. These plants will show the growth of plants in absence of fertiliser.
If you have any more questions, please keep them coming!
Watering the lettuces last saturday
References
- Carlos, G, Dendooven, L, Antonio, G, 2008, Vermicomposting leachate (worm tea) as liquid fertiliser for maize (Zea mays L.), Academic Journals Inc, USA.
- Kandari, L, Kulkarni, M, Staden, J, 2011, Vermicompost leachate improves seedling emergence and vigour of aged seeds of commercially grown Eucalyptus species, Southern Forest: Journal of Forest Science, vol 77, 2, 534-535.
- Zodape, S, 2001, ‘Seaweeds as a biofertiliser’, Journal of Scientific & Industrial Research Volume, vol. 60, 5, 378-382.
- Charman, P, Murphey, B, 1992, Soils their properties and management. Soil Conservation Commission of NSW. Sydney University Press. Chapter 16. Soils and farming practice. Harte, A.J.
Thursday, September 12, 2013
Day 16 of pot trial!
After some problems with our time lapse camera during the week, Jono has made a new structure that is less likely to fall, and re-started the camera yesterday (Wednesday) when he watered the plants.
Some photos from today are below. I was pretty excited to see that some differences are beginning to occur between treatments. I was surprised to see that the lettuces being fed aquasol look far healthier than those under leachate, autoclaved leachate or control treatments. Alternatively, in the soybeans, the leachate treated pots are looking far healthier. Time will tell!
Pot 28: Aquasol lettuce
Pot 29: Aquasol Lettuce
So much growth! :D
Some photos from today are below. I was pretty excited to see that some differences are beginning to occur between treatments. I was surprised to see that the lettuces being fed aquasol look far healthier than those under leachate, autoclaved leachate or control treatments. Alternatively, in the soybeans, the leachate treated pots are looking far healthier. Time will tell!
Camera set up
Pot 6: Aquasol soybeans
Pot 16: Leachate soybeans
Thursday, September 5, 2013
Day 9 of Pot trial!
Today I visited the poly house to water the lettuce and soybeans, and was pretty excited to see so much progress!
Pot 19 (Leachate)
Our lettuces
Pot 29 (Aquasol)
Pot 39 (Leachate)
Can't wait to see what happens by next week!
Jess
Sunday, September 1, 2013
Background to our problem
Concerns have been raised worldwide concerning the production and use of conventional chemical fertilisers (Quaik et al, 2012). These issues include:
• The challenges associated with meeting the increased demand for these fertilisers
• The decreased land availability for agriculture and food production
• Environmental contamination and degradation
• Concerns for human health as a result of consuming synthetically fertilised crops that haven’t been prepared appropriately
Commercially available chemical fertilisers can be inappropriate for a long term nutrient management solutions to increase crop yields because they can cause soil pollution and pose a health threats to humans if the subsequent produce is not prepared appropriately (Quaik et al, 2012).
Worm farming is an organic, waste management approach that uses worms to decompose organic waste, forming a compost material in addition to a natural liquid fertiliser enriched with humus (Carlos et al, 2008).
These products are produced through the process of Vermicomposting. Vermicomposting is a biotechnological process that transforms energy-rich and complex organic substances into stablised humus-like product (Suthar, 2007). The process takes semi-decayed organic wastes and transforms it into biologically organic manure by passing it through the digestive tract of earthworms, impregnating it with gastrointestinal mucosa, vitamins and enzymes (Abduli et al, 2013). Vermicompost leachate (VCL) is the liquid released by the earthworms and microorganisms during the decomposition process (Kandari et al, 2011). VCL, also known as ‘worm tea’, stimulates plant nutrient uptake and supports plant development due to the presence of humic acids, fluvic acids and plant growth regulators (Carlos et al, 2008). As Worm farming has become an increasingly popular organic farming waste management technique on a domestic scale(Kandara et al, 2011) there is the potential to explore the outputs of these farms, by analysing both the chemical composition of this output and thus its suitability as an alternative source of nutrients for plant growth. Furthermore a comparison of the growth implications of VCL and liquid fertilisers can provide a measure of its effectiveness for plant growth.
The popularity of organic fertilisers has increased significantly in recent years. (Webster and Taylor, 2009) report that the sale of vermiliquids has grown by 38% from 1997 to 2009. Although there is raised interest in VCL due to its ease of production and use, particularly on the local scale, currently there are no standards or guidelines for the production of consistent vermicompost leachates. Furthermore there is a lack of studies that provide analysis for appropriate application rates of VCL and how it should be packaged and stored(Webster and Buckerfield, 2010).
When using VCL to assist plant growth, there are two key factors to take into account. The VCL nutrient content varies depending on the initial substrate for the vermicomposting process (Quaik and Ibrahim, 2013).
This may be an issue for commercial potential for VCL in which controlling the inputs is difficult. The concentration of the leachate being applied also has a significant impact on plant growth. At high concentrations, VCL can inhibit seed germination and growth and cause leaf burning (Carlos et al, 2008, Quaik et al, 2012., Kandari et al, 2011). The majority of plant species have varied nutrient requirements for optimum plant growth. As a result, different plants may benefit from the addition of VCL formed from varied substrates and with varied concentrations. These issues create an added complexity in how to determine an optimal method for application of VCL on varying plant species.
An important issue for the use of VCL as a commercial biofertiliser is that the end product is strongly dependent on the substrates used (Quaik and Ibrahim, 2013). Due to the heavy dependence on the inputs of the vermicomposting, the effectiveness of the produced VCL to assist plant growth is highly dependent on the substrate for the process. The resultant inconsistency in product performance due to varied substrates presents an issue for VCL’s commercial application because industry relies on producing and supplying consumers with a product that has guaranteed effective and consistent performance.
Previous studies have shown that VCL offers strong potential for assisting plant growth. This is primarly because, due to its formation process, the nutrients present are completely soluble in water (Quaik and Ibrahim, 2013). Its solubility allows its nutrients to be easily diluted, which is why VCL may be considered a good foliar fertiliser. Furthermore, using VCL as a foliar fertiliser
helps to compensate for the loss of nutrients through leaching by adding excess nutrients to the soil (Quaik and Ibrahim, 2013).
Additionally, VCL alone may improve plant growth, however it is most beneficial when used to supplement traditional chemical fertilisers (Carlos et al, 2008., Quaike et al, 2013, Quaik and Ibrahim, 2013). As shown by Arthur et al (2012), using VCL on tomato plants found the application of VCL to be effective in improving plant growth in plants deficient in phosphorus or potassium. However, it was not very effective for plants deficient in nitrogen. This study found that plants fertilised with VCL may require supplementary use of conventional chemical fertilisers to provide additional nitrogen to ensure optimal plant growth.
It is important to note the drawbacks of VCL as alternative fertiliser. (Sherman and Appelhoff, 2011) critised the use of VCL commercially because VCL is liquid that has passed through undigested organic material, and thus it may contain pathogens or excess nutrients that may cause the application of VCL to be harmful to plants. Sherman and Appelhof (2011) states that VCL does not have potential as an alternative to commercial liquid fertilisers for this reason alone.
Our method aims to assess the plant growth of soybean and lettuce when fertilised with VCL compared to commercial Aquasol. Liquid feeding makes nutrients more readily available to plants, as opposed to solid fertiliser, which requires the breakdown and solvation of nutrients before it can be taken up by plants.
Furthermore, because VCL is formed as the by-product of an organic process, it may benefit plant growth due to its microbial activity. Thus when exploring VCL's effectiveness as a fertiliser both its chemical composition and biological activity will need to be considered.
Currently, the main ways to obtain information about the benefits and issues associated with worm farming and how to set up and use worm farms and the subsequent leachate produce are in the form of internet podcasts and television shows, council brochures and workshops, in schools, and advice at nurseries or gardening centers. These resources lack a scientific backing for the claims they make about the process and the benefits of the VCL. Additionally, as current scientific literature cannot entirely explain the vermicompost process, this further prevents worm farming from being embraced as an alternative for the improvement and enhancement of plant growth.
Thus it is evident that there is a large potential in this area for research to provide better understanding about the outputs from the wormfarming process. In addition, educational activities and programs with scientific backing are required to inform and justify the effectiveness of vermicomposting and the use of vermicompost leachate to the public, businesses and the agricultural sector if it is to be utilised more commonly on both a local scale and potentially a commercial scale.
• The challenges associated with meeting the increased demand for these fertilisers
• The decreased land availability for agriculture and food production
• Environmental contamination and degradation
• Concerns for human health as a result of consuming synthetically fertilised crops that haven’t been prepared appropriately
Commercially available chemical fertilisers can be inappropriate for a long term nutrient management solutions to increase crop yields because they can cause soil pollution and pose a health threats to humans if the subsequent produce is not prepared appropriately (Quaik et al, 2012).
Worm farming is an organic, waste management approach that uses worms to decompose organic waste, forming a compost material in addition to a natural liquid fertiliser enriched with humus (Carlos et al, 2008).
These products are produced through the process of Vermicomposting. Vermicomposting is a biotechnological process that transforms energy-rich and complex organic substances into stablised humus-like product (Suthar, 2007). The process takes semi-decayed organic wastes and transforms it into biologically organic manure by passing it through the digestive tract of earthworms, impregnating it with gastrointestinal mucosa, vitamins and enzymes (Abduli et al, 2013). Vermicompost leachate (VCL) is the liquid released by the earthworms and microorganisms during the decomposition process (Kandari et al, 2011). VCL, also known as ‘worm tea’, stimulates plant nutrient uptake and supports plant development due to the presence of humic acids, fluvic acids and plant growth regulators (Carlos et al, 2008). As Worm farming has become an increasingly popular organic farming waste management technique on a domestic scale(Kandara et al, 2011) there is the potential to explore the outputs of these farms, by analysing both the chemical composition of this output and thus its suitability as an alternative source of nutrients for plant growth. Furthermore a comparison of the growth implications of VCL and liquid fertilisers can provide a measure of its effectiveness for plant growth.
The popularity of organic fertilisers has increased significantly in recent years. (Webster and Taylor, 2009) report that the sale of vermiliquids has grown by 38% from 1997 to 2009. Although there is raised interest in VCL due to its ease of production and use, particularly on the local scale, currently there are no standards or guidelines for the production of consistent vermicompost leachates. Furthermore there is a lack of studies that provide analysis for appropriate application rates of VCL and how it should be packaged and stored(Webster and Buckerfield, 2010).
When using VCL to assist plant growth, there are two key factors to take into account. The VCL nutrient content varies depending on the initial substrate for the vermicomposting process (Quaik and Ibrahim, 2013).
This may be an issue for commercial potential for VCL in which controlling the inputs is difficult. The concentration of the leachate being applied also has a significant impact on plant growth. At high concentrations, VCL can inhibit seed germination and growth and cause leaf burning (Carlos et al, 2008, Quaik et al, 2012., Kandari et al, 2011). The majority of plant species have varied nutrient requirements for optimum plant growth. As a result, different plants may benefit from the addition of VCL formed from varied substrates and with varied concentrations. These issues create an added complexity in how to determine an optimal method for application of VCL on varying plant species.
An important issue for the use of VCL as a commercial biofertiliser is that the end product is strongly dependent on the substrates used (Quaik and Ibrahim, 2013). Due to the heavy dependence on the inputs of the vermicomposting, the effectiveness of the produced VCL to assist plant growth is highly dependent on the substrate for the process. The resultant inconsistency in product performance due to varied substrates presents an issue for VCL’s commercial application because industry relies on producing and supplying consumers with a product that has guaranteed effective and consistent performance.
Previous studies have shown that VCL offers strong potential for assisting plant growth. This is primarly because, due to its formation process, the nutrients present are completely soluble in water (Quaik and Ibrahim, 2013). Its solubility allows its nutrients to be easily diluted, which is why VCL may be considered a good foliar fertiliser. Furthermore, using VCL as a foliar fertiliser
helps to compensate for the loss of nutrients through leaching by adding excess nutrients to the soil (Quaik and Ibrahim, 2013).
Additionally, VCL alone may improve plant growth, however it is most beneficial when used to supplement traditional chemical fertilisers (Carlos et al, 2008., Quaike et al, 2013, Quaik and Ibrahim, 2013). As shown by Arthur et al (2012), using VCL on tomato plants found the application of VCL to be effective in improving plant growth in plants deficient in phosphorus or potassium. However, it was not very effective for plants deficient in nitrogen. This study found that plants fertilised with VCL may require supplementary use of conventional chemical fertilisers to provide additional nitrogen to ensure optimal plant growth.
It is important to note the drawbacks of VCL as alternative fertiliser. (Sherman and Appelhoff, 2011) critised the use of VCL commercially because VCL is liquid that has passed through undigested organic material, and thus it may contain pathogens or excess nutrients that may cause the application of VCL to be harmful to plants. Sherman and Appelhof (2011) states that VCL does not have potential as an alternative to commercial liquid fertilisers for this reason alone.
Our method aims to assess the plant growth of soybean and lettuce when fertilised with VCL compared to commercial Aquasol. Liquid feeding makes nutrients more readily available to plants, as opposed to solid fertiliser, which requires the breakdown and solvation of nutrients before it can be taken up by plants.
Furthermore, because VCL is formed as the by-product of an organic process, it may benefit plant growth due to its microbial activity. Thus when exploring VCL's effectiveness as a fertiliser both its chemical composition and biological activity will need to be considered.
Currently, the main ways to obtain information about the benefits and issues associated with worm farming and how to set up and use worm farms and the subsequent leachate produce are in the form of internet podcasts and television shows, council brochures and workshops, in schools, and advice at nurseries or gardening centers. These resources lack a scientific backing for the claims they make about the process and the benefits of the VCL. Additionally, as current scientific literature cannot entirely explain the vermicompost process, this further prevents worm farming from being embraced as an alternative for the improvement and enhancement of plant growth.
Thus it is evident that there is a large potential in this area for research to provide better understanding about the outputs from the wormfarming process. In addition, educational activities and programs with scientific backing are required to inform and justify the effectiveness of vermicomposting and the use of vermicompost leachate to the public, businesses and the agricultural sector if it is to be utilised more commonly on both a local scale and potentially a commercial scale.
Saturday, August 31, 2013
Who are we?
As part of our Third year Soil Science subject, four Science and Agriculture students, Jess, Jono, Polly and Georgia, are undertaking an investigation into how worm leachate compares to commercial liquid fertilisers.
We have found that there is a clear lack of scientific research into the topic, and are going to carry out research in the following areas:
- Lettuce and Soybeans 30 day pot trial
- Lab Chemical analysis on Fertilisers (Pea, Rockmelon and mixed leachate) , Aquasol, Seasol
- Plating of the leachate to identify any microbial activity present
- Survey
- Educational awareness (Client Requirement) – Blog and Video
More posts to come!
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