Friday, October 3, 2014

Sandstone pathways

Here is an example of a pathway we just compleated in Pymble.

 

Tuesday, November 12, 2013

How to Grow Chervil

How to Grow Chervil

Grown mainly for its bright green, feathery leaves, chervil is a hardy biennial herb, normally grown as an annual.

Chervile

The plant looks rather like parsley and its fresh leaves are used in much the same way – it has a delicate, sweet anise flavour with a hint of parsley. A native of southeastern Europe and western Asia, it grows to 30–45 cm tall and bears clusters of white flowers in midsummer. Successional sowing and growing indoors in winter will give you a year-round supply.

Planning the crop

Early- and late-sown plants will thrive in full sun, but those grown in summer benefit from partial shade in hot, dry areas. The herb will do well in any soil provided the drainage is good.

How much to grow- The best way to grow chervil is as a short-term crop, making four to six sowings at intervals throughout the year and using only tender young leaves. In this way, you’ll have plenty of leaves if you grow five or six plants at any one time. Chervil will grow well in pots and window boxes.

Growing tips

Sow the seeds 5 mm deep in an open seedbed at any time between spring and late summer. Allow 30 cm between rows if you are sowing more than one row, and thin the seedlings to about 30 cm spacings. Water the plants in dry weather and remove flowering stems as soon as they appear. This will not only encourage the growth of young, tender leaves for a longer period, it will also prevent self-sown seedlings from sprouting like weeds in the surrounding soil. However, if you want to collect seeds for later use, let one of the heads mature and then gather the ripe seeds before they fall.

Herbs for winter- Chervil can be grown outdoors in most districts during winter. Alternatively, plant two or three seeds in a 15 cm pot filled with seed compost. Remove all but the strongest seedling and grow it on the kitchen windowsill for a supply of fresh leaves throughout winter.

Pests and diseases

Chervil is usually trouble-free.

Harvesting and storing

Cut or pick the leaves six to eight weeks after sowing. The leaves are too tender for drying but can be preserved by freezing.

From: Grow Your Own Fruit & Vegetables The Easy Way

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Monday, September 30, 2013

Echium or pride of Madira


Perennial
Light: Full Sun
Height: 5 feet to 8 feet
Width: 5 feet to 6 feet
Bloom Color: Blue
Leaf Color: Green, Silvery
Special Features: All or parts of this plant are poisonous, Not North American native
Shape: Rounded
Fertilizer: Sea sol Water Soluble All Purpose Plant Food
Want to know where Pride of Madeira will thrive in your house or garden? A Plant Sensor will give you a plant's-eye view of your environment to measure soil, sunlight, temperature and humidity.

Plant Care

Planting:
Sow seeds of annuals species in spring; sow perennial and biennial species in summer. Root semi-ripe cuttings of shrubby perennials in midsummer.

Plant Growth:
Echium grows best with full sun, and thrives in areas with hot summers. Species are drought tolerant, but cannot withstand temperatures below 30ºF. Where hardy, grow Echium in an annual, mixed, or herbaceous border. They also make good container plants. Elsewhere, raise Echium indoors.

Blooming:
Flowers are borne from spring to summer. They attract bees, butterflies, and birds.
Soil that is too rich will hinder flower formation.
Soil and Irrigation:
Outdoors, Echium does well with poor, dry soils. For indoor plants, use a standard soil-based potting mix. Water freely during the growing season; water sparingly in winter.

Pruning:
Plants should be cut back hard before winter.
Pests:
Slugs are known to attack young growth. Other pests include whiteflies and spider mites.

 

Sunday, September 29, 2013

Echium or pride of Madira


Perennial
Light: Full Sun
Height: 5 feet to 8 feet
Width: 5 feet to 6 feet
Zones: 10a to 11b
Bloom Color: Blue
Leaf Color: Green, Silvery
Special Features: All or parts of this plant are poisonous, Not North American native
Shape: Rounded
Fertilizer: Miracle-Gro® Water Soluble All Purpose Plant Food
Want to know where Pride of Madeira will thrive in your house or garden? The EasyBloom Plant Sensor will give you a plant's-eye view of your environment to measure soil, sunlight, temperature and humidity.

Plant Care

Planting:
Sow seeds of annuals species in spring; sow perennial and biennial species in summer. Root semi-ripe cuttings of shrubby perennials in midsummer.

Plant Growth:
Echium grows best with full sun, and thrives in areas with hot summers. Species are drought tolerant, but cannot withstand temperatures below 30ºF. Where hardy, grow Echium in an annual, mixed, or herbaceous border. They also make good container plants. Elsewhere, raise Echium indoors.

Blooming:
Flowers are borne from spring to summer. They attract bees, butterflies, and birds.
Soil that is too rich will hinder flower formation.
Soil and Irrigation:
Outdoors, Echium does well with poor, dry soils. For indoor plants, use a standard soil-based potting mix. Water freely during the growing season; water sparingly in winter.

Pruning:
Plants should be cut back hard before winter.
Pests:
Slugs are known to attack young growth. Other pests include whiteflies and spider mites.

 

Saturday, September 28, 2013

Plants And Potassium

 

Using Potassium And Potassium Deficiency Plants


The effects of potassium on plants is well known in that it improves how well a plant grows and produces but exactly why and how is not known. As a gardener, you do not need to know the why and how in order to be hurt by a potassium deficiency in plants. Keep reading to learn more about how potassium affects the plants in your garden and how to correct a potassium deficiency.


Effects Of Potassium On Plants


Potassium is important to plant growth and development. Potassium helps:
Plants grow faster
Use water better and be more drought resistant
Fight off disease
Resist pests
Grow stronger
Produce more crops
With all plants, potassium assists all functions within the plant. When a plant has enough potassium, it will simply be a better overall plant.
Signs Of Potassium Deficiency In Plants
Potassium deficiency in plants will cause a plant to perform more poorly overall than it should. Because of this reason, it can be difficult to see specific signs of potassium deficiency in plants.
When severe potassium deficiency happens, you may be able to see some signs in the leaves. The leaves, especially older leaves, may have brown spots, yellow edges, yellow veins or brown veins.


What Is In Potassium Fertiliser


Potassium fertilizer is sometimes called potash fertilizer. This is because potassium fertilizers often contain a substance called potash. Potash is a naturally occurring substance that occurs when wood is burned away or can be found in mines and the ocean.
While potash is technically a naturally occurring substance, only certain kinds of potassium fertilizers containing potash are considered organic.
Some sources refer to high potassium fertilizer. This is simply a fertilizer that is exclusively potassium or has a high K value.d


If you wish to add potassium to your soil at home, you can do so in several ways without having to use potash or other commercial potassium fertilizer. Compost made primarily from food byproducts is an excellent source of potassium. In particular, banana peels are very high in potassium.
Wood ash can also be used, but make sure that you apply wood ash only lightly as too much can burn your plants.


Greensand, which is available from most nurseries, will also add potassium to you garden.
Because potassium deficiency in plants can be hard to spot through looking at the plant, it is always a good idea to have your soil tested before adding more potassium.

 

Friday, September 27, 2013

Cankers On Trees

How To Treat Cankers
You may have noticed some unsightly cankerous looking wounds in your tree. What are tree cankers and what causes them, and how do you treat cankers in a tree once you see them? Continue reading to learn more about the types of canker in trees and how to go about preventing tree cankers.
What Are Tree Cankers?
Cankers on trees appear as isolated dead areas on the bark, stems, branches or twigs. Cankers may appear as discolored areas or depressed places on the bark.
A fungus that enters the tree and grows between the bark and the wood killing the bark generally causes cankers.
However, cankers can also be caused by damage from weed eaters, lawnmowers, chemicals, insects or environmental conditions.
The canker itself makes the tree highly vulnerable to bacteria, fungus and insects. Young fruit trees have an especially difficult time recovering from cankers. Established shade trees may weaken and become susceptible to wind damage.
The healthier the tree is, the more likely it is to ward off serious damage from a canker disease. Trees that are weakened by temperature, drought, poor nutrition or other present diseases are much more susceptible to canker diseases. Canker diseases are more common with hardwood trees than on conifers.
Type of Cankers in Trees can Vary
Depending on the region where you live, different cankers on trees are found. Some of the more common types of canker in trees include:
Thyronectria canker is caused by a fungus and is most common on the honey locust tree.
Nectria canker tends to attack deciduous shade trees, crabapples and pears.
Cytospora canker is found most often in fruit trees, hardwood forest trees and shrubs, as well as over 70 species of conifers.
Hypoxylon canker is seen in different species of oak including red and white.
How Do You Treat Cankers in a Tree Effectively?
So how do you treat cankers in a tree? Preventing tree cankers is the best method of protection. It is best to plant native or well-adapted species for your growing region. These tree species will suffer less stress and adapt well to the soil type, sun exposure and overall environmental conditions in your area.
The avoidance of stress is the best and most effective protection against canker diseases. Proper tree care including watering, feeding, mulching and pruning will help to keep trees as healthy as possible.
Once a tree has canker, it is essential to remove as much of the canker fungi as possible from the tree to avoid infection and spread. Prune only during dry weather and make cuts with a sterilized cutting tool at least 4 inches below the edge of the canker on trees.

Friday, September 13, 2013

What is Humus


What is Humus?

The etymological root of the word “humus” is strongly linked to the word “human” with both words meaning “of and for the earth”. The biblical “dust to dust” concept is about the simple reality that we came from humus and it is to humus that we all return. Both words are also linked to the word “humility” and ironically it is our lack of humility, our arrogant attempts to master Earth that may well prove our downfall.

Humus is the chocolate brown, sweet smelling substance that drives healthy, productive soils

Humus is created by soil biology but also serves as the living quarters for this vital workforce.

Humus is the soil glue without which our rivers run brown and dust storms strip our thin veil of precious top soil. Humus provides the single most efficient storage of water, minerals and carbon and it is this trio that will most impact soil health, human health and planetary health in the coming years. The reclamation of humus is the shape of the future or we may not have much of one.


Recent findings are so grim and the trends so alarming, I often found myself fighting back the tears. One thing became increasingly clear. If we do not act urgently our world will be a very different place. Our current inaction represents the greatest example of collective denial in the history of mankind.



The new studies often refer to “irreversibility” and the only debate seems to relate to whether the estimated temperature increases peak out at 3, 4 or 5 degrees. There is little mention of the fact that a 5.5 degree increase in global temperatures is considered to be beyond human adaptability.



You may be thinking, “Big deal! I won’t need a singlet in winter”, but it’s a bit more serious than that. We are currently witnessing the climatic disruption linked to a rise of just one degree and the chaos does not simply double at two degrees, it is exponential.




Here in Australia we have just experienced the hottest January in recorded history and across the Tasman in New Zealand they are suffering the worst drought in their history. England has just experienced their coldest March in history and the list goes on. However, there is more bad news. These extremes in climate are actually less serious than the more pressing issue of ocean acidification from excess CO2.




The oceans have absorbed almost 50% of the man-made CO2 produced since the industrial revolution and we should be thankful for this planetary, self-balancing act. However, the resulting 30% increase in acidity threatens ocean life dependent on calcium to build their outer shell.




This includes corals, shellfish and algae. 500 million people are directly reliant on coral reefs for their food. Algae and krill are the building blocks for ocean life as we know it and phytoplankton produce over 50% of the planet’s oxygen. The impact is already measurable but will become serious in just 20 years. It doesn’t get much more serious than this and action must replace apathy.




It has become increasingly obvious that emission reductions will not stem the tide. If we were to reduce emissions by 100% tomorrow morning, then in 200 years time, the CO2 in the atmosphere will drop down to 1975 levels, which is still too high. The oceans continue to heat and acidify and not many experts will agree that we have 200 years to play with. Are we too late and are now locked into a planetary calamity? No we are not! The sense of despair that can sponsor the shutdown of a personal action-based response is not necessary. There is a solution that can save the day and I would like to think that some of you may soon feel motivated to share this message.


The Message

There has only ever been the same number of carbon molecules on the planet and they alternate between the soil, the biomass and the atmosphere as part of the carbon cycle. Currently a great deal of what was once in the soil is now in the atmosphere. In fact we have lost two thirds of our humus to the atmosphere following two centuries of extractive agriculture. This represents 476 gigatonnes of CO2 that is now stored in the atmosphere where it thickens the greenhouse blanket, traps the heat and sponsors climate extremes. Just for a sense of perspective – all of mankind’s other activities since 1860 have released a total of just 250 gigatonnes of CO2. We desperately need to redistribute atmospheric CO2 back into the soil as humus and everyone can contribute.

Here’s how it is done.


Planet Saving Strategies

We buy our food from those that practise regenerative farming. i.e. organic or biological growers – the rise and rise of farmers’ markets supports this kind of discretion.

We pay carbon credits to primary producers for increases in soil humus. We need to motivate rapid action in a sector that is often already reeling from the economic impact of climate extremes.

Composting becomes the mantra for everyone including farmers, home gardeners, Councils and Governments. Councils, for example, could collect food scraps and plant matter separately to avoid the methane emission linked to anaerobic decay in rubbish tips.

These scraps are a good protein base for composting green waste and biosolids. Vermi-composting (utilising earthworms) is the ultimate composting technology as it produces an end-product that is twenty times more effective than any other compost option. Large scale vermicomposting of city wastes has been mastered by a New Zealand company in Auckland and these specialists are prepared to share their hard won technology with any council anywhere. 

Of course, consumers must recognise the importance of these critically important initiatives and support them by purchasing this compost as their primary soil fertility tool.

We inoculate our soils with the organisms that build stable humus in the soil, with a particular emphasis upon beneficial fungi. Mycorrhizal fungi are directly responsible for 30% of the humus in the soil and their numbers are just 10% of what they were before the advent of extractive agriculture. 

These creatures burrow into the plant root and provide a massive attachment of fine filaments that represents aten-fold increase in root surface area. This fungal root extension scavenges difficult-to-access minerals, retains moisture and nutrients and produces a range of beneficial biochemicals to boost the immune system of its host. 

Mycorrhizal fungi can be reintroduced to our soils for as little as ten dollars per hectare and soil, plant, animal, human and planetary health are improved as a result. Other free living cellulose digesting fungi have also been seriously depleted and they can be easily and inexpensively brewed (multiplied) to repopulate biologically depleted soils.

We legislate to protect the organisms that will save the day. Anything that compromises the humus-building performance of these key organisms must be restricted. This includes some farm chemicals, over cultivation and faulty grazing practices. 

Dr Margaret Roper from the CSIRO in Perth has shown that Paraquat and Atrazine seriously impact humus building organisms. Nematicides are similarly destructive and the world’s most widely used farm chemical, glyphosate, has recently been shown to be a serious microbicide.

The burning of crop residues should be immediately banned. Not only are we destroying the soil food that could become humus and sustenance for precious soil biology but we are directly contributing large amounts of CO2 to the atmosphere. Particulation, where ash rises from the flames and is deposited elsewhere by the breeze, is also a form of demineralisation, as this ash effectively contains the minerals that grew the crop.

We include a carbon source with every nitrogen-based fertiliser to buffer the microbial damage, reduce emissions of nitrous oxide and to prevent nitrogen stimulated bacteria from consuming humus to satisfy their tight C:N ratio of 5:1. Mismanagement of nitrogen is actually a major root cause of humus loss, as the bacteria, when fed excess nitrogen, seek out carbon to balance out this tight ratio (and humus is lost in the process).

Humates extracted from brown coal become indispensable humus-building tools for everyone. Humic acid promotes cellulose digesting fungi while fulvic acid promotes beneficial bacteria. These are accessible, inexpensive, high carbon inputs which also buffer salt fertilisers and magnify mineral uptake. It is ironic that the brown coal, that is the biggest contributor of CO2 to the atmosphere (via coal-fired power stations) can be of so much more value if it is used to boost soil fertility.

We direct our superannuation/pension funds to invest in enterprises involved in developing renewable energy rather than those adding to the problem. The relatively new concept of a carbon budget is rapidly gaining acceptance around the globe. 

Here we recognise that 80% of the known carbon reserves (coal and oil) must stay in the ground if we are to have a viable future. Why then are just 2% of total pension funds currently supporting renewable enterprises, while 55% of our money supports the carbon polluting enterprises? Why would we be so actively funding companies seeking to discover more coal, oil and gas when most of what we have already found must stay locked within the ground. This is our money and our future and we should all pressure for a redirection of these funds. 

Well funded human initiative is the key to success here and there are massive amounts of money available that could be directed to planet saving enterprises (assuming cash-strapped governments don’t plunder this resource beforehand).


Humus Offers More than Climate Change Reversal

Humus determines profitability – Several years ago The National Bank in Australia conducted a comprehensive study to ascertain exactly what determines profitability in farming. In an attempt to better understand why so many rural loans were failing, they discovered that the single most important factor in farming success was organic matter (humus).They actually priced the farms in their large study based upon relative humus levels. A variation of just 0.15% organic matter attracted a substantial increase in the proposed valuation of the farm land involved.

Humus saves water – 74% of the planet is covered by water but only 3% of that is fresh. Most of that fresh water is tied up in ice and glaciers and only 0.3% is in liquid form. 90% of that fresh water is used for irrigation. Water is a precious resource for which wars will be fought in the future. Large dams are our preferred water storage strategy at present but they are notoriously inefficient. 

Evaporation accounts for massive losses; there is often a large carbon footprint involved in pumping the water around the countryside and more energy involved in the actual irrigation process on-farm. A percentage of water applied as overhead irrigation accounts for more evaporation, and flood irrigation is even less efficient. Humus holds its own weight in water and it is the obvious way to store and deliver water. There is no evaporation beneath the ground and there is also no delivery energy involved. The plant roots simply take water from the humus as required. 

A 1% increase in organic matter (humus) in your soil means that soil can now hold 170,000 litres per hectare of water it could not previously hold. That is 17 litres of extra water per square meter. Humus offers a double benefit here because it is the home base for bacteria which produce a biofilm that absorbs and stores additional moisture. This sticky exudate stores water in much the same fashion as commercial water crystals.

Humus improves the nutritional value of our food – Humus stores more than water. It is also the primary vehicle for mineral storage and delivery. Humus features both negative and positive charged sites which can attract and hold all minerals, preventing them from leaching. 

There is no other storage facility in the soil with this capacity. The loss of humus from our soils spells the loss of mineral storage and it also impacts mineral delivery. Science is increasingly realising that every mineral has a microbe behind it. Microbes are the bridge between the soil and the plant and humus is the living quarters for these beneficial organisms. 

Many studies have chronicled the declining nutrition in our food and there is a direct link to the declining humus levels in our soils. Nutritionists contend that our food now contains just 20%of the nutrition found in the food consumed by our grandparents when they were children. We suffer a plague of degenerative illness and very often the root cause can be linked to nutrition. We are what we eat and what we eat comes from soils that are a shadow of their former selves.

Humus reduces chemical contamination of our food – This is a major health issue as chemical safety trials did not factor in the largely unresearched, cocktail effect or the phenomenon of bio-accumulation. Studies with rodents may have determined minimum residue limits of farm chemicals on our food but there was no consideration of how the body manages these contaminants. 

In many cases our detox systems are not equipped to process man-made chemicals and they are shunted off to the fat cells to keep them away from key organs. Here they accumulate and can pose health problems. When considering strategies to reduce our reliance upon farm chemicals it is a worthwhile exercise to consider the root cause of pest pressure in plants. 

A fungal disease does not reflect a deficiency of a fungicide. Disease is a response to compromised plant immunity based upon a lack of key supportive minerals or a lack of the bio-chemicals produced by microorganisms to enhance the resilience of their hosts. It is very much a case of “I will look after you if you look after me” and there is a direct parallel to our relationship with our own gut biology. At the soil/plant interface, the plant feeds glucose to the soil microbes in return for delivery of immune-enhancing minerals and biochemicals. However, the protection is even more profound than this. Many of the beneficial organisms surrounding the roots can also predate upon or antagonise disease organisms. The good guys literally eat our enemies. Humus, as the home base for minerals and microbes, is the key to enhanced pest resistance and less need for farm chemicals. The higher the humus, the less the chemical contamination of our food and the greater our health.

Humus cleanses soil contaminants and prevents nitrate leaching – Nitrates are a proven carcinogen and our ground water is seriously contaminated with this byproduct of nitrogen fertilisers. Humus is the only storage system in the soil for nitrate nitrogen. The loss of 2/3 of our humus means we have much less capacity to prevent nitrates from leaching and hence contamination of waterways is currently inevitable. Humus also serves as a carbon filter isolating heavy metals and farm chemicals that might otherwise enter our food chain.

Humus sponsors soil structure improvements – The bacteria living in humus constantly release a sticky, alkaline substance that binds together soil particles to form tiny aggregates. Fungi then bind these particles into larger aggregates to form crumb structure, the most desirable of all soil conditions. When crumb structure is present, plant roots can expand readily and as earthworms and beneficial nematodes can move unimpeded in these soils, their numbers increase. 

These soils also facilitate gas exchange,where oxygen moves freely into the soil to satisfy the requirements of plant roots and the organisms surrounding those roots. When the roots and microbes “breathe out”, the resulting CO2 can also move freely upward where it is captured by the tiny breathing pores on the underside of the plant leaf called stomates. The capacity of a soil to “breathe” in this fashion determines the amount of CO2 for photosynthesis and, of course, photosynthesis, in turn, governs production and impacts resilience.


In Conclusion

Humus is literally the lifeblood of this planet and we have used and abused this magical substance to the point that our future viability is at stake. When we build humus in the soil, we reclaim carbon from the atmosphere, we improve plant, soil and animal health, we manage precious water more effectively and we lift the vitality and resilience of every last one of us. We need to refer back to the ancient wisdom where the words “humus” and “human” mean “of and for the earth” and we need to rediscover the humility to work with nature rather than striving for mastery. We can all contribute; lobby your Councils, pressure your super fund, compost, compost, compost and buy your food from those doing the right thing. We can all help save the world with humus.