در اوایل ماه دسامبر 2002 میلادی در روستای «گورنی» واقع در 250
کیلومتری شهر ساراتوف، اولین محصول کارخانه بازیافت تسلیحات شیمیایی، از خط تولید
خارج گردید. در 10 سال گذشته ، این اولین کارخانه بازیافت سلاح های شیمیایی است که در روسیه احداث شد. این کارخانه قادر
است موادی همچون ایپریت (گاز خردل) و لویسیت را بازیافت نماید.
چندی پیش هیاتی از سازمان منع سلاح های شیمیایی امکان بازدید از
کارخانه «گورنی» را دریافت نمود. خبر اتمام عملیات ساخت و شروع بازیافت برای
کشورهای غربی نیز که جهت خلع سلاح شیمیایی روسیه ، سرمایه گذاری نموده اند، مسرت بخش بود زیرا آنان را از هرگونه شک و شبه خارج نمود. در ضمن بازیافت تسلیحات
شیمیایی به مواد صلح جویانه می تواند در آینده سود بسیاری به همراه آورد.
بازیافت تسلیحات شیمیایی بلوک شرق
پس از فروپاشی اتحاد جماهیر شوروی، تسلیحات شیمیایی از تمام نقاط روسیه و
کشورهای بلوک شرق جمع آوری شده و در 7
انبار مخصوص در استان های بریانسک، پِنـــزا، کورگان، ساراتوف و جمهوری اودمورتیا
(2 انبار)،واقع در فدراسیون روسیه نگهداری
می شوند. بدین ترتیب در روستای گورنی تقریبا 9/2 % از کل ذخایر تسلیحات شیمیایی
روسیه موجود می باشد. زمانی که بازرسان خارجی از انبار بکلی سری فوق الذکر بازدید
نمودند، اظهار داشتند که تصورشان از آنچه که دیده اند بدتر بوده است. روش نگهداری
تسلیحات شیمیایی شوروی ها نسبت به آمریکایی ها از نظر تکنولوژی بالاتر می باشد. از
تسلیحات شیمیایی ساخت آمریکا نمی توان چاشنی های انفجاری را جدا نمود حال آنکه
چاشنی های انفجاری و کانتینرهای مواد شیمیایی روس ها از ابتدا جدا از هم نگهداری
می شوند. به غیر از این آمریکایی ها به علت طرز فکر تجاری، تسلیحات شیمیایی خود را
از آلومینیوم ارزان ساخته اند. اما روس
ها از آلومینیوم گران و آلیاژ مستحکم تر ساخته اند. امروزه فاش شده است که تسلیحات
شیمیایی آمریکایی شروع به نشت کرده اند، اما سلاح های شیمیایی روس ها هنوز قابل
نگهداری هستند و حداکثر 10 تا 15 سال دیگر می توان از آنها نگهداری نمود.
پیشنهادات مختلفی جهت حل
این مشکل وجود دارد. عده ای پیشنهاد نموده اند که آنها را برای همیشه کنسرو
نمایند. عده ای دیگر پیشنهاد نموده اند که همچون روش آمریکایی ها، آنها را
بسوزانند.«انستیتوی دولتی علمی- تحقیقاتی شیمی آلی و تکنولوژی» 
تکنولوژی بازیافت ایپریت و لویسیت را پیشنهاد نموده است.
توسط این تکنولوژی می توان واکنش خنثی سازی مواد سمی را در دما و فشار محیط انجام
داد. تکنولوژی مذکور مطابق آزمونهای تخصصی (اکسپرتیز) زیست محیطی، بی خطری خود را
در وزارت منابع ملی،آکادمی علوم روسیه و همچنین اکسپرتیز بین الملل، 
باثبات رسانده و پاسخ مثبت دریافت نموده است.نتایج بدست آمده، بی
خطری تکنولوژی روسی را نشان می دهد.
کوره های آمریکایی گاه به گاه، منفجر می گردند. چنین خطری هرگز روستای گورنی را
تهدید نمی نماید. حتی مبتکر این تکنولوژی ولادیسلاو شِلوچِنکو آماده است تا ویلای
خود را پشت نرده های کارخانه بنا نماید.
در ماه دسامبر 2002 کارخانه گورنی با استفاده از تکنولوژی خود به
صورت آزمایشی ایپریت و لویسیت را به مواد بی خطر بازیافت نمود و با توجه به حجم
انبار شده این مواد در روستای گورنی، تا 5 سال آینده این کارخانه می تواند از این
تکنولوژی استفاده کرده و پس از نابود سازی تمام ذخایر موجود، کارخانه را برای
تولیدسایر مواد شیمیایی تبدیل و آماده نمود. هرچند روسیه می تواند این تکنولوژی را
صادر و بفروشد برساند اما مواد بدست آمده از هیدرولیز ایپریت و لویسیت، سود
بیشتری دارد. از تبخیر مواد بدست آمده از هیدرولیز، می توان آرسنیک تهیه نمود. هرچند در
دندانپزشکی دیگر از این عنصر استفاده نمی گردد اما آرسنیک در آینده نقش بسزایی در
صنایع ساخت باطری خورشیدی خواهد داشت. طبق محاسبات بعمل آمده حداقل تا سال 2010
اینگونه باطریهای خورشیدی در سطح جهان به میزان 10 میلیارد دلار تولید خواهد شد.
در حال حاضر لهستانی ها خواستار آرسنیک روس ها هستند و در نظر دارند برای استحصال
آرسنیک از لویسیت، سرمایه گذاری نمایند.
به هر حال انبار موجود در روستای گورنی فقط بخش کوچکی از ذخایر
تسلیحات شیمیایی روسیه محسوب می گردد. قبلا صنایع شیمیایی شوروی بیش از تمام صنایع
شیمیایی جهان این مواد را سنتز نموده اند. ذخایر تسلیحات شیمیایی روسیه بیش از 40 هزار تن برآورد می گردد که تقریبا 10
هزار تن بیشتر از ذخایر آمریکایی ها است که رسما" از سال 1969 تولید آن را متوقف نموده اند. روسیه در سال های
دهه 70 میلادی فقط مواد سمی گروه فسفر (زارین، زُمان و وی-گاز)را به میزانی تولید
نمود که با آن می توان تمام جمعیت جهان را چندین هزار بار هلاک نمود.
راجع به اینکه این مواد را در صورت عدم آغاز جنگ جهانی سوم چگونه
باید از بین برد، تا سال 1984 هیچکس
تصمیمی نگرفته بود تا اینکه در آن سال کمیته 
مرکزی حزب کمونیست اتحاد جماهیر
شوروی و شورای وزیران وقت تصمیم گرفتند، کارخانه عظیم نابود سازی تسلیحات شیمیایی
را در شهر چاپایِفسک احداث نمایند. ساخت کارخانه در سال 1989 پایان یافت اما راه
اندازی آن به علت اعتراض اکولوژیست ها و فروپاشی شوروی انجام نگرفت. در حال حاضر
این کارخانه به یکی از بزرگترین مراکز آموزشی جهان برای مبارزه با تسلیحات شیمیایی
برای کشورهای جهان سوم تبدیل شده است.
از سال 1993 که روسیه پیمان منع استفاده از سلاح های شیمیایی را
امضاء نمود، متعهد شد که تا سال 
2000، 1% از ذخایر تسلیحات شیمیایی و تا
29 آوریل 2007 کلیه 40 هزار تن سلاح شیمیایی خود را نابود نماید. اما به علت
مشکلات اقتصادی این امر بدینگونه عملی نخواهد شد. طبق برنامه جدید تنظیم شده از
جانب دولت روسیه قرار است تا سال 2007 ، 20% مواد سمی، تا سال 2009 - 45% و تا سال 2012 تمام ذخایر خود
را در صورت دریافت کمک های خارجی، از بین 
ببرد. در بودجه سال 2003 دولت روسیه
برای نابود سازی تسلیحات شیمیایی، مبلغ 3/5 میلیارد روبل در نظر گرفته شده است که
کمتر از 50% بودجه مورد نیازمی باشد و
مابقی سرمایه طبق توافقات بین المللی از جانب کشورهای خارجی تامین می گردد. رئیس
ذخایر تسلیحاتی روسیه امیدوار است که همکاریهای نزدیک بین روسیه و کشورهای خارجی
باعث شود که طبق موافقت 
سران 8 کشور صنعتی، کمک های
بلاعوض جهت بازیافت و نابود سازی بخشی از تسلیحات شیمیایی روسیه، پرداخت شود.یکی
از کشورهایی که در امر نابودسازی تسلیحات شیمیایی به روسیه کمک می نماید، کشور
آلمان می باشد که از سال 1993 تا کنون مبلغ 5/30 میلیون دلار سرمایه گذاری کرده و
در ساخت کارخانه گورنی نقش بسزایی ایفا نموده است. اما علاقمندی آمریکا جهت نابود
سازی تسلیحات شیمیایی روسیه نسبت به قبل به شدت کاهش یافته است. واشنگتن، روسیه را
متهم می نماید که مقدار 40 هزار تن سلاح شیمیایی که رسما از جانب روسیه اعلام
گردیده است، نادرست می باشد زیرا ظرفیت تولیدی صنایع شیمیایی شوروی بسیار بالا
بوده است. به غیر از این آمریکا نسبت به دریافت حق کنترل یکجانبه بر روی کلیه
مناطق روسیه که به نظر آنان ممکن است تسلیحات
شیمیایی تولید و یا نگهداری شود، پافشاری می نماید. اما به نظر می رسد که علت
اساسی چیز دیگری است. پس از اینکه روسیه تولیدتسلیحات شیمیایی خویش را متوقف و
نسبت به جمع آوری آنها از کشورهای بلوک شرق و ذخیره سازی اقدام نمود، دیگر نگرانی
ای از جانب آمریکایی ها وجود ندارد و تنها روس ها و اروپایی ها هستند که باید
نگران وجود این همه تسلیحات شیمیایی و مواد سمی در منطقه باشند و نه آمریکایی ها
که در آن طرف اقیانوس قرار گرفته اند.
| n |
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|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|
| H |
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| He | |||||||||||||
| Li | Be | B | C | N | O | F | Ne | ||||||||||
| Na | Mg | Al | Si | P | S | Cl | Ar | ||||||||||
| K | Ca | Sc | Ti | V | Cr | Mn | Fe | Co | Ni | Cu | Zn | Ga | Ge | As | Se | Br | Kr |
| Rb | Sr | Y | Zr | Nb | Mo | Tc | Ru | Rh | Pd | Ag | Cd | In | Sn | Sb | Te | I | Xe |
| Cs | Ba | La | Hf | Ta | W | Re | Os | Ir | Pt | Au | Hg | Tl | Pb | Bi | Po | At | Rn |
| Fr | Ra | Ac | Rf | Db | Sg | Bh | Hs | Mt | Ds | Rg | 112 | 114 |
| ||||
| Ce | Pr | Nd | Pm | Sm | Eu | Gd | Tb | Dy | Ho | Er | Tm | Yb | Lu | ||||
| Th | Pa | U | Np | Pu | Am | Cm | Bk | Cf | Es | Fm | Md | No | Lr |
یک شیمیدان ایرانی با همکاری محققان کانادایی به تکنیک جدیدی برای رهاسازی نانوذرات آلی متصل به نانوذرات طلا دست یافت که میتواند در درمان بدون عوارض سرطان موثر باشد.
دکتر عبدالحمید علیزاده، دانشجوی ایرانی با همکاری محققان دانشکده شیمی دانشگاه Western Ontario کانادا در تحقیقات خود به روش جدیدی برای رهاسازی نانو ذرات آلی متصل به نانوذرات طلا دست یافتند که میتواند در آینده در ساخت حسگرهای شیمیایی پیشرفته و همچنین رهایش هدفمند و موثر دارو در مبتلایان به سرطان مورد استفاده قرار گیرد.
این دانشجوی مقطع دکتری شیمی آلی دانشگاه بوعلیسینای همدان پس از یک سال تلاش مداوم بر روی پایان نامه خود در دانشکده شیمی دانشگاه (Western Ontario (UWO کانادا موفق به دستیابی و انتقال دانش «بارگذاری و رهاسازی کنترل شده نانو ذرات متصل به نانوذرات طلا» به کشور شد.
وی گفت: اگر از این فناوری در درمان سرطان استفاده شود، با توجه به این که نانوذرات طلا با ابعاد کوچکتر از 2 نانومتر هیچگونه سمیتی برای بدن و سلولهای سالم ندارند شاید بتوان با اتصال داروی مورد نظر بر روی این نانوذرات کوچک و تزریق دقیق محلول آن به بافتهای بیمار، از طریق مکانیزم رهاسازی کنترلشده، دارو را تنها در محل سلولهای آسیبدیده فعال کرد.
Compost is partially decomposed organic matter. It is dark, easily crumbled, and has an earthy aroma. It is created by biological processes in which soil-inhabiting organisms break down plant tissue. When decomposition is complete, compost has turned to a dark brown, powdery material called humus. The processes occurring in a compost pile are similar to those that break down organic matter in soil. However, decomposition occurs much more rapidly in the compost pile because the environment can be made ideal for the microbes to do their work (Figure 1).
Gardeners often have difficulty disposing of leaves, grass clippings and other garden refuse, particularly in urban areas. Missouri law bans these materials from landfills, so it has become even more important to find environmentally sound ways to dispose of them. These byproducts of the garden and landscape can be turned into useful compost with no more effort than it takes to bag and haul them away. Home composters avoid hauling or utility costs associated with centralized composting facilities and end up with a valuable soil conditioner or mulch for the landscape and garden.
Good compost consists primarily of decomposed or partially decomposed plant and animal residues, but may also contain a small amount of soil. Compost improves both the physical condition and the fertility of the soil when added to the landscape or garden. It is especially useful for improving soils low in organic matter.
Organic matter in compost improves heavy clay soils by binding soil particles together into "crumbs," making the soil easier to work. Binding soil particles also helps improve aeration, root penetration and water infiltration and reduces crusting of the soil surface. In sandy soils, additional organic matter also helps with nutrient and water retention. Compost also increases the activity of soil microorganisms that release nutrients and other growth-promoting materials into the soil.
Although compost contains nutrients, its greatest benefit is in improving soil characteristics. You should consider it as a valuable soil amendment rather than a fertilizer, because additional fertilization may be necessary to obtain acceptable growth and yields.
Compost also is a valuable mulching material for garden and landscape plants. It may be used as a topdressing for lawns and, when it contains a small amount of soil, as part of a growing medium for houseplants or for starting seedlings.
Figure 2
A succession of organisms decompose organic matter in compost.
Composting is a method of speeding natural decomposition under controlled conditions. Raw organic materials are converted to compost by a succession of organisms (Figure 2). During the first stages of composting, bacteria increase rapidly. Later actinomycetes (filamentous bacteria), fungi and protozoans go to work. After much of the carbon in the compost has been utilized and the temperature has fallen, centipedes, millipedes, sowbugs, earthworms and other organisms continue the decomposition.
As microorganisms decompose the organic materials, their body heat causes the temperature in the pile to rise dramatically. The center of a properly made heap should reach a temperature of 110 to 140 degrees Fahrenheit in four to five days. At this time the pile will begin "settling," which is a good sign that the pile is working properly. The pH of the pile will be very acidic at first, at a level from 4.0 to 4.5. By the time the process is complete, the pH should rise to approximately 7.0 to 7.2.
The heating in the pile will kill some of the weed seeds and disease organisms. However, this happens only in areas where the most intense temperatures develop. In cooler sections toward the outside of the pile, some weed seeds or disease organisms may survive. Proper turning is important to heat all parts of the pile.
The organisms that break down the organic materials require large quantities of nitrogen. Therefore, adding nitrogen fertilizer, or other materials that supply nitrogen, is necessary for rapid and thorough decomposition. During the breakdown period, the nitrogen is incorporated into the bodies of the microbes and is not available for plant use. This nitrogen is released when the decomposition is completed and the compost is returned to the garden.
Many types of organic materials can be used for compost. Sod, grass clippings, leaves, hay, straw, weeds, manure, chopped corncobs, corn stalks, sawdust, shredded newspaper, wood ashes, hedge clippings and many kinds of plant refuse from the garden are some of the possibilities.
Weed plants heavily laden with seeds might be better left out of the compost pile if the compost is to be returned to the garden. Even though some seeds are killed during composting, those that survive might create an unnecessary weed problem.
Most kitchen scraps also may be used in the compost heap. Some items that should not be used are grease, fat, meat scraps and bones. These materials may attract dogs, rats or other animals. They also may develop an unpleasant odor during decomposition. Fats are slow to break down and greatly increase the time required before the compost can be used.
Unless compost is completely and thoroughly turned during its formation or allowed to remain unused for several years, it is best not to place diseased plants from the flower or vegetable garden on the compost heap. Even though some diseases may be killed by the heating during the compost formation, there is a chance of returning some of these disease organisms to the garden.
The length of time necessary for the composting process depends on several conditions:
Carbon-to-nitrogen ratios
All organic material contains carbon and nitrogen. Carbon is a major component of the cellulose and lignin that give cell walls their strength. Nitrogen is found in proteins and many other compounds inside plant cells. The carbon-to-nitrogen ratio (C:N) of a material is an estimate of the relative amounts of these two elements it contains. It is usually based on the percent dry weight of carbon and nitrogen in the material. A ratio of about 30:1 is ideal for the activity of the microbes in the compost. This balance can be achieved by controlling the materials included in the compost or by adding nitrogen either from fertilizer or from organic materials high in nitrogen, such as manure or grass clippings.
Table 1 shows the approximate ratios for some materials commonly added to compost piles. The items at the beginning of the list are highest in nitrogen; those at the bottom are highest in carbon.
These ratios represent comparative weights. Therefore, in the first example, 5 to 7 pounds of dry pig manure would contain one pound of nitrogen, while near the other extreme, 500 pounds of sawdust might contain only 1 pound of nitrogen.
The 30:1 ratio in compost is the most desirable to supply the microorganisms with the proper amount of carbon they need for energy and the proper amount of nitrogen they need for protein synthesis so they can function efficiently and quickly. To estimate the C:N of a mixture, average the ratios of the individual materials. For example, a mixture of equal parts grass clippings and leaves might have a C:N of (20 + 50) ÷ 2 = 35.
Table 1
Carbon to nitrogen ratios in various materials.
Figure 3
Proper layering in a compost bin.
Compost piles develop best if they are built in layers (Figure 3). Layering is a good way to ensure that the materials are added in the proper proportion. Once several layers are formed, however, composting will be most rapid if the layers are mixed before making new layers. It is usually best also to add water to each layer of dry material rather than try to wet the entire pile after it is built. The entire pile should be as wet as a well-wrung sponge. It may not always be practical to build a pile in this way if available materials are limited. When organic materials are accumulated rather slowly, they may be stockpiled until enough are available to layer properly.
The pile normally may be started directly on the ground. However, to provide the best aeration to the base and improve drainage, dig a trench across the center of the base and cover it with stiff hardware cloth before you begin the layers. Branches or brush may be placed on the bottom as another means of improving lower aeration. However, they may interfere with removal of the finished compost since they will decompose more slowly than finer materials.
Begin the pile by placing a 6- to 8-inch layer of organic matter in the enclosed area. Shredded or chopped materials decompose faster, so if a shredder is available, coarse, organic matter should be run through it. Materials that tend to mat, such as grass clippings, should be placed in layers only 2 to 3 inches thick or mixed with coarser materials for thicker additions. After the organic layer is built, moisten but do not soak it.
Over the layer of plant material, add a layer of a material high in nitrogen, such as manure, or a sprinkling of a high-nitrogen garden fertilizer. A layer of animal manure 1 to 2 inches deep should be satisfactory. If organic materials high in nitrogen such as grass clippings are used, these should be layered to about a 4-inch depth. Although adding grass clippings or other materials that have been treated with herbicides may cause concern, most pesticides break down quickly in a compost pile.
If garden fertilizers such as 12-12-12 are used as a nitrogen source, use about 1 cup per 25 square feet of the top surface of each layer.
When using fertilizer materials, about 0.8 ounce of actual nitrogen per bushel of organic matter such as leaves is needed. Since one cubic yard (3 feet x 3 feet x 3 feet) of leaves contains about 23 bushels, it would require about 18 ounces (1.1 pounds) of nitrogen or about 5.5 pounds of a fertilizer containing 20 percent N. It is best to add fertilizer to the pile in several doses as the pile is turned to avoid overwhelming the microorganisms. More uniform distribution on each layer can be obtained if a water-soluble fertilizer is mixed with water and sprinkled over the surface. Table 2 shows the amount of each material needed to apply 1 pound of actual nitrogen.
It was once thought that ground limestone should be added to the compost pile. This is no longer considered necessary since the organisms function well with a pH of between 4.2 and 7.2. The compost naturally will become less acid as it matures. Adding lime helps convert ammonium nitrogen to ammonia gas, which can create an odor problem as it escapes from the pile and can reduce the nutrient content of the finished compost. Adding lime may also cause the pH of the finished compost to be higher than optimal for plant growth.
Next, add a layer of soil or sod about an inch thick. The soil contains microorganisms that help to start the decomposition process. If there is not an adequate source of soil, a layer of finished compost may be used as a soil substitute. Compost activators may also be used to introduce organisms into the pile.
Continue to develop and alternate the layers until a height of 3 to 5 feet is developed. Firm each layer of organic material as it is added, but do not compact it so much that air cannot move freely through it. Water each layer lightly as it is added. Homogenize the layers as you go for faster results. During construction of the pile, remember the C:N ratios and that it will take about one pound of actual nitrogen for each 30 pounds of lightly moist organic matter for best decomposition.
Build the heap in a convenient but inconspicuous place. If the compost is to be used mainly in the garden, then a nearby location would be logical. Since the compost pile may need to be kept moist during dry weather, a convenient source of water should be available. Don"t locate the pile where water may stand. Excess moisture in the bottom of the pile can cause the process to stop or lead to odor problems. Locate the pile where occasional earthy odors are not likely to offend neighbors.
A shaded area is generally desirable for best composting. If possible, do not locate the pile or structure close to trees. Tree roots may be attracted to the loose moist organic material in the bottom. During summer, roots of some trees may invade the lower areas of the bin and make the compost difficult to dig and use.
Table 2
Quantities of nitrogen sources to provide a pound of nitrogen
Making compost does not require a structure and can be done simply in a pile. However, piles will require more space. The minimum size of a pile should be 5 feet by 5 feet and 3 feet high. Materials can be added as they become available, but when the first pile is high enough, a second one should be started until the first has decomposed enough to be used. Piles may be turned regularly or not at all. However, if they are not turned, the upper portions will not be totally decomposed and will have to be pulled off when the compost is used.
Figure 4
You can build a composter from available materials. Wrap the bin with weed-barrier fabric or perforated plastic sheeting to reduce moisture loss.
Although it is possible to stack the compost in a pile, decomposition is best and space is used more efficiently if it is placed in some type of bin or enclosure (Figure 4). The sides should allow air movement through them. The pile may be round, square, rectangular or any other convenient shape. An open side or a fastener will facilitate pile turning and removal of finished compost.
The speed at which compost forms depends on the conditions already discussed. Controlling these factors, along with frequent turning of the compost, speeds up the process. But many gardeners are content with the slower, more traditional methods that require less attention.
Figure 5
Compost bin constructed from landscape timbers. To turn the compost, disassemble the bin and restack the timbers close by; then fork the compost into the new enclosure.
Figure 6
A three-compartment turning unit constructed with concrete blocks and metal ties.
Fast method
Fast composting methods depend on the use of turning units. They can create good compost in as little as six weeks, depending on how the compost pile is managed. Materials that can be used include nonwoody yard waste, nonfat kitchen waste and similar materials. Structures or containers that allow frequent, easy turning are essential.
Turning units for the fast method are of two general types: a series of bins (usually three) that allow manual turning of the compost from one bin into the next (Figures 5 and 6); or a rotating, horizontally mounted drum, such as a 55-gallon barrel. The materials for fast composting should be added in larger amounts rather than frequent additions of small amounts. Therefore, organic matter should be collected until there is enough to properly fill a barrel composter or other unit such as a bin 3 feet square. To reduce odor problems, grass clippings should be spread to dry before stockpiling, and food wastes should be covered or buried in the compost.
Traditional or slow method
In this system, material may be added to the enclosure at any time. Turning can help, but it is not required. When only one unit is developed, finished compost may be taken from the bottom while new materials are still being added to the top. Two bins are always better where space permits, since one bin can be allowed to mature while new materials are being added to the other.
Woven wire fencing, chicken wire, chain link, hardware cloth, wood slat fencing (snow fence), concrete blocks, bricks or lumber can be used to enclose the compost heap. Fencing wires need corner supports, although some can be used to make cylinders that need little or no support. If woven wire fencing is too loose to contain finer materials, line the enclosure with plastic that contains some aeration holes to keep the pile neat and speed decomposition. The plastic lining will also prevent excessive drying of the vertical pile surfaces.
Bricks or concrete blocks may be piled without mortar, but 1/2-inch spaces should be left between them to allow adequate air movement through the sides. Line up the holes facing upward as you stack them and drive metal posts down through a few of the holes to make the bin more stable (Figure 6).
Lumber, whether new or scrap, is suitable for sides of compost bins. Allow enough space between the boards for air movement. Lumber is gradually ruined by exposure to the damp compost, and boards occasionally have to be replaced as they decay. Discarded pallets can be used to make an inexpensive, yet durable composting enclosure.
A properly built pile should develop a temperature of at least 110 degrees Fahrenheit at the center in about a week during summer or up to a month in cooler seasons. When that temperature is reached, the pile should be opened, any compacted materials should be loosened, and the material should be turned or stirred so that the material previously on the top and sides is moved to the center. During warm weather, the pile may need another turning after a second week. The optimum temperature in an active compost pile is 135 to 140 degrees Fahrenheit. Compost piles occasionally reach temperatures as high as 170 degrees, hot enough to kill some of the microorganisms. This usually happens when excessive amounts of wet, high-nitrogen materials are added to the pile.
The rate of heat buildup and decomposition also will depend on external temperatures. In winter, little decomposition occurs except in the center of large piles.
Piles may be turned by slicing through them with a spade and turning each slice over. The main ive in turning is to aerate the pile and shift materials from the outside closer to the center, where they may also be heated and decomposed.
As materials decompose, the pile heats up and should also shrink, eventually becoming no more than half its original height. Often the pile"s volume may shrink by 70 to 80 percent.
Compost is ready to use when it is dark brown, crumbly and has an earthy smell. For those who want a very fine product, it can be run through a 1/2-inch screen and the coarser material can be used for mulch or returned to the pile for continued decomposition with other materials.
When compost is ready to use, it should be dark and crumbly, and you should not be able to recognize the original composted items. If compost is not used promptly, it still makes a good soil amendment, but nitrogen may be lost through leaching.
Fast composting may produce good compost in three to eight weeks. Conventional composting methods will produce a product in three to nine months, depending on the types of organic materials used, temperatures, and how often the compost is turned.
In some cases, screening compost through a 1-inch wire mesh will help sort out incompletely decomposed materials before use. Twigs decompose slowly, and if they have become a part of the debris, they may have to be removed from finished compost to be returned to the heap.
Compost is also very suitable to use for potting houseplants or starting many types of seeds. Recent research has shown that microorganisms found in mature compost can actually suppress plant diseases such as those causing "damping off" as effectively as fungicides. Generally, best results are obtained when compost is mixed with other materials such as perlite and vermiculite with about 30 percent of the volume being compost.
Compost should be added annually if you are using it to build good soil. The best time to add compost to the vegetable or flower garden is during fall or spring tilling. It can be added to the soil when planting trees, shrubs, annuals or perennials. Compost is an excellent mulch or topdressing around flowers, vegetables, shrubs and trees. If used as a mulch, the compost need not be completely finished.
Compost may be used as a lawn topdressing, but it should not be applied more than 1/4 inch thick. For this purpose, the compost should be screened so that only the finer particles are used.
Further information
