Vermicompost productionPaper, kitch

Vermicompost production
Paper, kitchen wastes, yard wastes, and dry cattle manure were
used as feedstocks. Paper wastes, composed of approximately 80%
old newspaper, 10% office discards, and 10% flyers, were collected
from various sources. The 2 cm wide paper shreds were obtained
by passing the paper wastes through a shredder. The kitchen
wastes, collected at the Nova Scotia Agricultural College (NSAC)
cafeteria, consisted of 65–70% fruit and vegetable peels; the
remainder consisted of egg shells, tea bags, coffee filters, rice, pasta,
bread and cooked potatoes. Meat, fat, and oily foods were not
included in the kitchen waste. The yard wastes consisted of dried
deciduous leaves (a mixture of birch, dogwood, maple, and oak)
and grasses. The cattle manure was taken from a relatively aged
beef and dairy manure pile at the farm of the NSAC during the
summer of 2000; the manure was from cattle fed mixed feed and
who had free-ranged on pasture.
Twenty-seven opaque, rectangular plastic boxes with covers,
each measuring 30.5 cm  61 cm  30.5 cm (56.7 l), were used as
composting bins. Sixty holes, 0.65 cm diameter, were drilled into
the container to allow for adequate aeration. The experiment was
undertaken as a 3  3 factorial in a randomized complete block design
with three replications. Three feedstock combinations (KPW =
Kitchen Paper Waste, KYW = Kitchen Yard Waste, CMY = Cattle
Manure Yard Waste) and the duration of vermicomposting (45,
68 or 90 days) were the independent variables, while the biological
parameters served as the dependent variables.
The three feedstocks were prepared in a 5:1 ratio with the
kitchen waste or cattle manure as the major (5 kg) and the paper
or yard waste as the minor component (1 kg). The kitchen and yard
wastes were prepared by manual chopping to reduce particle size.
Kitchen wastes were placed between bottom and top layers of the
dry component (paper or yard wastes). The CMY components,
however, were thoroughly mixed before placing in the bins to
avoid compaction of the cattle manure upon the addition of moisture.
Three hundred grams of worms, Eisenia fetida, ranging in
length from 5 to 7 cm, and 300 g of old vermicompost were placed
into each bin after the feedstocks were added. The moisture of the
feedstocks was adjusted to 80% at the start of vermicomposting
and maintained throughout the duration of vermicomposting by
taking the weight of the bins every 3 days. Ambient and bin temperatures
were monitored daily during the first 2 weeks, the period
of most active decomposition of feedstocks. The worms were harvested
from the 45, 68, and 90 day bins using the ‘dump and hand
sort technique’ described by Appelhof (1997).
2.2. Plant bioassay materials
Seeds of radish (Raphanus sativus ‘Cherry Belle’), marigold (Tagetes
patula ‘Orange Boy’) and upland cress (Barbarea verna) were
purchased from Vesey’s Seeds Ltd., Charlottetown, P.E.I. These
plants were chosen based on their growth characteristics and their
previous utilization as test plants in experiments with compost. A
low fertility, low organic matter Pugwash sandy loam (Humo-Ferric
Podzol) was collected (0–30 cm depth) from a field at Lower
Onslow, N.S. The soil was air-dried and passed through a 2 mm
sieve. Plastic 8.5 cm-diameter petri dishes were used in the germination
test using compost–water extracts. Cell packs were used in
the germination tests using vermicompost–soil mixes; each pack
had six cells with a capacity of 80 cm3 per cell.
2.3. Germination tests and plant growth measurements
Two germination test procedures were used to determine vermicompost
quality; the vermicompost–water extract method and
the direct seed germination test. The first method used 1:8 and
1:4 vermicompost (V):distilled water (12.5% V and 25% V by
weight, respectively) as described in Warman (1999a). Petri dishes
(9 cm) were lined with Whatman No.1 paper and moistened with
5 mL of the vermicompost:water extracts, while the control received
5 mL of distilled water. In three replications, 30 seeds each
of radish, marigold and upland cress were placed in the dishes and
germinated in the dark at 20 C. The number of seeds sprouted, i.e.
germination, was determined at 48 h. The second method, the direct
seed germination test (Warman, 1999b) of radish, marigold,
and upland cress, in three replicates, was conducted by mixing
each of the three vermicomposts of three maturity dates with Pugwash
sandy loam soil in 5% and 10% compost–soil combinations.
Seventy-five milliliters of moist vermicompost–soil mix was
placed into each cell pack. Each treatment was seeded with 30
seeds of each test plant. The cell packs were moistened with distilled
water (as required) and kept under 12–14 h of light and
24 ± 2 C in the plant growth chamber. Germination count was taken
10 days after seeding, after which, the seedlings were thinned
down to two in each cell.
Twenty-five days after the