Section One: Chapter 5 Making Certain It "Works"!

What can go wrong with your new compost pile?

Actually, quite a few things. Most "wrongs" are caused by the pile build itself, but some, like adequate watering, apply to after-build issues. Another biggy is having and adding proper ratios of each raw material type. Always keep in mind the rule of 31 parts dry "Brown" raw material(Also called "Carbon" material as it is essentially dry carbon mass) to 1 part nitrogen. This loosely translates to one part green or rotting mown grass to three parts "Brown."

In the build method this book focuses on, the biggest key success factor is the addition of adequate brush to the base of the pile and then layered in as the pile goes up. Otherwise, you have a major turning job on your hands for every other day or so for two weeks! Longer if not adequate mown grass!

Go back and re-read the key points of pile building in the last chapter. Do the best you can with your raw materials and skills to follow those points carefully.

Now that the pile is finished per the last chapter, do a mental run-through of your work. Actually, it is best if you've read this chapter Before building the pile!

First Exercise

1. Good Job building! Now, sit back and relax, just a bit. You deserve it! We need the simple temperature gauging tool mentioned in the Tools Appendix. Any sturdy metal rod will do. Plastic and fiberglass resist heat so it's best to stick to metal. Remember, the thicker the rod the longer it requires to heat up to the temperature of the pile. Also, the rod will cool the material it touches, so a second placement for thicker rods will be necessary for accurate sense of actual heat.

Compare This Soil-Producing System To Other Systems

This period of comparable rest opens up time to check out other soil-producing methods. Perhaps the worst ones are those silly rotating drum thingies! In theory they appeal to mobility-challenged gardeners, and just plain lazy folk, so they sell well. But two things make them useless. Well, let's add a third:

A. They take dedication to turning frequently. Lazy gardeners DO NOT do this! That makes the raw material inside turn foul and stink!

B. They are "tiny"! Even the largest only holds a few forks of raw material, compared to your free-standing pile! Then that tiny bit of raw material produces just several gallons of soil.

C. The worst part is all that labor! The pile you just finished is FINISHED! Now you sit back and allow natural laws of gravity to pull water down through the pile, and heated air to rise through it bottom to top, carrying vital oxygen to keep the pile fresh-smelling and continue its proper heating process.

As it is reduced to basic nutrient elements, gravity does all that turning work as it pulls the pile down on itself.

There is just one labor left to your new soil; separating out the brush from the finer material.

*IF* you do not want that valuable, partly-decomposed brush in the grow beds. For back-filling tree planting holes, the brush is perfect, and should remain in the soil. The vegetables you grow in the soil don't care a bit if brush is in their soil, and actually grow better with it!



So, go ahead and check out other soil-producing systems. I've never discovered one that produces ready-2-use soil. Only large commercial hot compost producers' methods produce soil ready to plant in.

This mention of commercial producers brings up a point I want to stress. By federal law and very stiff fines, commercial composters are barred from allowing their material to NOT reach very nutrient-destroying temperatures. Upwards of 200, 300, 400, and more degrees F is required, by law. The reason is valid, too.

Commercial operations by nature of their size and need to generate profit, require massive intake of raw material. That raw material comes from thousands of uncontrollable content sources. Chemicals, waste oils, diseased dead creatures, baby diapers, rotting yuk of all sorts, and who knows what else can, and does enter those processors' raw materials stream.

So . . . the "soil" the commercial composter bags and sells you at the grocery store is *NOT* nutrient-dense at all! Rather, it is inert like sand. Oh, it does have a little nutrient for YOUR soil bugs to slowly enter and start the process of composting all over. But, essentially, it's like a bag of sand.

That said, let's return to your pile now. That metal temperature monitoring rod is your ticket to great management! Use it frequently to "see" your pile's hot spots and not so hot areas. Check the pile water content throughout the pile. I like my rods to be rusty, as the rust retains moisture and shows where there is lack of same. Learn to "read" this tool, and it's OK to dig small holes into the side of the pile to see and feel the progress, or lack of it. Be sure to repack the hole and wet it good!


At this point it's insightful to know how fully decomposed organic material looks and feels. This is where the trip to, and close, careful observation of the rich, verdant soil in a local woods is invaluable!

Finished raw organic material decomposition to its basic elements is when the lignon - woody content that shapes and maintains the structure of all plants - is reduced to soft, water-retaining mass. If it is undisturbed as it decomposes, the original shape and texture of the plant part remains intact. I once enjoyed the awesome experience of finding completely undisturbed ancient coal chunks on an outcropping of a seam of coal along the Appalachian Trail in Pennsylvania. That 60 pound block of completely decomposed ancient vegetation held a little snake smashed to a thin, oily sheen of its scales and shape in one paper thin layer! Another layer had a tiny imprint of a baby dear, or other split-hooved creature! The perfectly preserved shapes of ferns, small branches, and other plants of that ancient time made one of the most fascinating finds of my life!

The point here is that those organic raw materials still held their original form and substance, due to their being undisturbed during their decomposition. Just as you new soil pile will produce near-perfect form and substance of each piece of raw material. With this in mind, as your pile processes to completed reduction to elemental nutrients, its appearance with fully shaped leaves, grass, small branches, and some thicker food plant stalks has no bearing on the fact it is ready to grow your garden in.

The one criteria to gauge full decomposition by is nitrogen consumption by the decaying material. This is the reason for carefully building the pile by the method I share. There are any number of other ways to build a pile of organic material to produce soil, but all others take far longer to completely decompose, or require very tiring, intensive labor to turn repeatedly during the process, if a speedy source of soil is desired.

Your new pile is fully reduced to elemental components when the following is true . . .

1. You have maintained moisture throughout the build so that squeezing a handful of material at any point during the decay process leaves your hand slightly wet, but not so wet as to stay wet more than a minute or two.

2. You have built the pile carefully adding the proportions of components as defined in chapter 4.

3. You have followed the guide to compress the pile as defined in chapter 4.

4. Your monitoring the pile's progress kept up with water, air flow and even pile heat requirements.

5. In the last days of a two or three week time from first watering and pile compression, the temperature drops from a steady, even heat to below 110 degrees F. This signals that the combination of oxygen, aerobic bacteria, water and compressed contents is completed. The carbon content is near fully reacted with nitrogen and water and oxygen to form decomposition of the complex plant molecules to their basic nutrients.

6. Your entire management of this soil production process is finished when YOU realize that there now is your very own nutrient-dense soil in your hands! This is a moment to remember!

Note: Tale lots of photos ALL during this entire process! You will be very happy you did!



Let's remember . . .

1. Two things are "musts" for good decomposing activity: A. The right moisture. B. The right air flow.
2. 
   To make the pile wet enough, add water to the pile at about the half-built point, then over the top of the finished pile. Watch the bottom of the pile to tell when the water penetrates the entire pile. We'll call this the "first" watering.
   
   The second requirement for good success: When the pile is built, cover the top and sides with 1 to 2 inches of sand, sod, or other fine material that will benefit plant health. Do not cover with anything that blocks air or water!

Section One: Chapter 4 Let's Build It!

Chapter 4: Let's Build It!

Apartment dweller! May I have your attention!

This project may well seem ONLY for outdoor gardeners!

Fact is, your INDOOR garden can easily produce nutrient-dense soil!

The entire system I share is scalable to any size operation. Inside your home, use a flower pot, a wood box with screen bottom setting on a water-holding tray, a plastic pail with many holes in the bottom and half way up the side(s), even an old water can with many holes punched in bottom and sides!

The point is this: Even if you add raw organic material to the top of your planters to decompose right on top of the soil your plants grow in, producing rich, nutrient-dense soil should be a major part of your garden health and your own nutritious food. Just follow along as this book unfolds. Scale the methods, ideas, tools, and concepts to your indoor gardening space. It works!

On with the book!

Hallelujah! We made it through the tough stuff!

For the sake of me not knowing your experience, or lack of experience with composting, let's assume you are a newbie to producing soil this way. In fact, I continually meet Master Gardeners who never knew how simple and easy hot composting really is, nor do their know the extreme benefit to plant and consumer health this nutrient-dense soil provides. If you are a Master Gardener, I do apologize for what must feel like a put down, But the old saying goes here: "If you don't know that you don't know, how would you know?"

Let's learn together!

The two activities in the last chapter focused on gathering raw materials.

Here's Activity One for this chapter

1. First things first! If not done already, make sure there is enough of each type of raw material for building each part of the pile. If there is enough first layer material but too little second or third, either wait or place the first layer then wait and collect the next layer material. The build can take all the time necessary to build as material becomes available. However, be sure to follow the "recipe" as it is key for success!

Here's a little concept drawing with the first four layers. Remember those small branches? That first layer is 6 to 8 inches thick entirely of these short branches. This provides critical air flow bottom to top through the pile above.  Next the "brown," dead, dry more woody material is a 4 to 6 inch layer. On top of the brown about 2 inches of green or rotting grass clippings. The fourth layer will be a couple to 4 inches of small branch material again.

Here's a photo of my pile building just today, January 10, 2016.

Follow these main points for a successful build.

A. Maintain air flow through the layers

B. Shred or tear paper and cardboard to less than 8 inches across the wider dimension

C. For matted leaves, grass, paper and cardboard, add thin layers to the pile and separate these layers by adding equally thin layers of branch material to keep the material from matting.

D. Form the sides vertical as possible.

E. The highest the pile should go so as to not compress the lower layers to tight is 5 to 6 feet. 

F. Be sure to add branch material through finer material to keep from matting

G. About half way up, stop and soak the pile. Climb on top and walk-jump the pile to compress far as you can. This aids the heating as the materials are compressed together.

H. Cover the top with fine soil from a finished pile or sand, sod or wood chips. Something to keep moisture in much as possible, while permitting air flow and entering water.



Remember those weeds? The way I see these nutrient-dense treasures may become your vision too. That means the weeds growing randomly in the garden are prize soil producing elements which you welcome and even show a little favor for until they are mature enough to be a substantial part of the next pile build.

But, let's have a little common sense here, too! Weeds competing with food plants reduce available nutrients, so I follow a simple method to discourage weeds in food plant beds. I plant each bed's plants quite a bit closer than common recommendations. For two reasons.

The first is that common gardening advice comes from gardeners used to native, nutrient-depleted soils. In our nutrient-dense natural soil, the plant thrive planted at half the spacing necessary in nutrient-depleted soils.

The other reason for planting closely is weed discouragement. Shaded soil from close planting makes it difficult to impossible for seed seed to sprout, or grow if they do sprout.

Another benefit that you will love natural soil for is the ease of pulling roots out. Only large, established plants will develop large enough roots to make pulling out a bit difficult. Young plants of any kind take merely a slight tug to pull the entire roots out.

Your pile built?

Now, Activity Two

Reread the building guide. Note any differences the pile you are building requires.


The rest of Section One, except for chapter 10, follows up the pile build with fairly straight forward, simple guides to assure that your soil is truly the nutrient-dense growing medium you desire.

The many years I've produced soil this way taught me numerous "secrets" about the process with many different raw materials and numerous factors such as weather, watering, weed seed control, uses and post production nutrient addition. These and more topics appear in following chapters.

Section One: Chapter 3 Did We Forget To Plan Ahead For Use of Our Soil?

• Chapter 3: Did We Forget To Plan Ahead For Use of Our Soil?

This chapter title may sound odd. Allow me to explain.

Each plant has its own preferred soil to grow best in. Many common food plants share a common type of soil. This is not to say that our most productive garden should be one common soil. This is where the "planning" part for producing natural soil enters our soil work.

For instance, corn takes a far different soil type than beans and peas, since corn sucks up nitrogen heavily, while beans and peas add nitrogen to the soil. For good corn soil, plan to add worm castings, or vermicompost soil to the corn bed. For beans and peas, almost no compost soil is required, except that the legume family does require full spectrum minerals and added living enzymes from a good compost is fine!

Legumes need an application of a fungal inoculate that grows symbiotically inside the legume root, which transfers the excess nitrogen the plant captures from the air to the soil. This fungus may or may not be in the soil where your legumes are grown.

Trees are another plant with different soil requirements than most seasonal garden plants. Produce soil that has a high woody content and back fill the holes you dig for new trees and add thick layers of this woody soil under the whole leaf area of each tree, keeping away from the trunk by 12 inches or so. Rodents enjoy nibbling covered tree trunks in Winter!

The woody soil takes years to break down. It shelters the ground and maintains water content while water seeping down through it takes along nutrients to the roots. Also it has enzymes that help break down clays and rocky minerals for the roots to absorb.

Carrots, parsley, parsnip and Swiss chard roots require deep, fertile and friable, loose soil. Rhubarb requires very deep, rich and friable soil. It likes heavier, finer soil, as well.

Most berries do best in very fertile, fine soil that drains but holds water for long periods in the organic matter. 

Tomatoes love airy soil where earth worms are fed daily with rotting raw vegetable wastes, and the high organic content sponges water for sustained release to the roots. The deeper soil they are in the better for their deep-penetrating roots, when watered deep and infrequent.

Squashes love thin, nutrient-dense soil. Their roots spread at least out to the furthest vine tips! Be sure their soil is high in woody material to sponge up and provide long water release. Squashes require lots of Nitrogen for all that vine and leaf production!

The brassicas family - broccoli, cabbage, Brussels sprouts, kohl rabi - require new soil each season. They produce some nasty parasites every year. Best is to hot compost their spent plants and provide new soil every season. They love rich, high nitrogen soil with lots of spongy woody material to provide even root water availability. Their roots grow quite deep, as well.

Beets and onions grow on top of the soil, but like very nutrient-dense soil. Both like fine, silty soil. The compost soil is pretty coarse for these, but I have good crops in it usually.

Chives, leeks, radish, garlic, cucumber, spinach, lettuce, mustard, arugula, and most smaller food plants do well in fairly fine natural soil. All like nutrient-dense soil with lots of woody, spongy content. 

If you produce water cress, a heavy, fine soil that stays underwater is a good choice. For mine, they do great in very wet soil that is not under water. 

Like rhubarb, artichoke requires very deep, somewhat fine, but woody soil. Its roots go down two to three feet. In your natural soil, it will outperform any commercial soil! Just be certain to add LOTS of nitrogen!

Flowering corms, bulbs and rhizomes do well in the most nutrient-dense soil you can produce! Some, like dahlia, grow quite deep roots, so be sure their soil is two feet or deeper. These all do best with well drained, but high water-retaining soil. Your natural soil is superb!

Activity One

1. List the plants to be grown in your new soil. Beside each plant name note the soil and environment it best grows in. This can be numbers or letters that are cross referenced to short details for each type of environment and soil. Be sure to make sure the desired plants have their preferred spot available! There's no substitute for 8 hours of full sun!

Don't Forget the "Weeds"!

Now, let's cover soils for those "weeds"!!

"Weeds" are those native, pesty plants that covered your garden long before you arrived! They are acclimated to the native, original soils. But, when you add your good natural soil to their habitat, very few varieties fail to respond with verdant growth! If you have visitors to the garden, smile when they exclaim about how huge the weeds are! In a moment you will see and I believe appreciate why.

One lady in last my year's community garden lamented that I love to allow native plants to thrive in the empty spaces! So, I said, "Basically, I'm a weed farmer!"

It's true! My love for and use of nutrient-dense "weeds" in natural soil production is the basic mainstay of this awesome soil! So, grow them "weeds"!

Some favorite "weeds" are the food plants with thick, woody trunks that grow tall for seed. Parsnip and artichoke and Jerusalem artichoke are favorites. Siberian kale produces a heavy, woody, long stem. Corn stalks make excellent woody, spongy soil content.

One of the very best spongy, woody soil materials is wild berry brambles! It's nasty to handle dried or growing, but that pithy fiber inside the woody vines is perfect for sponging water up, and roots grow fast down inside those water-filled vine pieces in the soil!

Fully grown thistles have woody stalks, but make certain the pile temp is over 140 degrees F. for over a week to kill-off the seed. Even so, cut and compost new thistle plants for excellent raw material. It's all good.

If you live in an arid area where cactii grow, grow them in your garden for excellent raw material content! The water, enzymes and pile heat reduce needles to soft elemental nutrients. Their woody and pithy parts lend great content to the soil you produce.

Activity Two

• Determine the soil type each plant you grow needs and where to obtain the necessary materials.

•