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3.4. SMSs as controlled suppliers o
3.4. SMSs as controlled suppliers of nutrient
Adsorption is a well-established technology for waste water
purification, however, its success for environmental and economic
reasons depends on the possibility of desorbing the target contam-
inant and reusing the adsorbent for a valuable resource such as
nutrient supplier or SRFs.
The results obtained from funnel analytical test (Fig. 9a) clearly
indicate that SMSs can be used as slow release nutrient supplier.
They have a greater tendency to hold the nutrients and also release
them slowly. Unmodified silicates release around 25–35% of nitrate
after first irrigation. More than 75% of applied nutrient is leached
out after 6th irrigation in case of soil. On the other hand SMSs show
its slow release tendency with only 15–20% of leaching after first
irrigation and around 40% after 6th irrigation and still show nearly
4% leaching after 24th irrigation which suggests its slow release
capacity. These results clearly demonstrate the slow release of N
from nutrient loaded SMSs. Also the level of N released after 24th
irrigation is sufficient for plant growth. 3.4. SMSs as controlled suppliers of nutrient
Adsorption is a well-established technology for waste water
purification, however, its success for environmental and economic
reasons depends on the possibility of desorbing the target contam-
inant and reusing the adsorbent for a valuable resource such as
nutrient supplier or SRFs.
The results obtained from funnel analytical test (Fig. 9a) clearly
indicate that SMSs can be used as slow release nutrient supplier.
They have a greater tendency to hold the nutrients and also release
them slowly. Unmodified silicates release around 25–35% of nitrate
after first irrigation. More than 75% of applied nutrient is leached
out after 6th irrigation in case of soil. On the other hand SMSs show
its slow release tendency with only 15–20% of leaching after first
irrigation and around 40% after 6th irrigation and still show nearly
4% leaching after 24th irrigation which suggests its slow release
capacity. These results clearly demonstrate the slow release of N
from nutrient loaded SMSs. Also the level of N released after 24th
irrigation is sufficient for plant growth.3.4. SMSs as controlled suppliers of nutrient
Adsorption is a well-established technology for waste water
purification, however, its success for environmental and economic
reasons depends on the possibility of desorbing the target contam-
inant and reusing the adsorbent for a valuable resource such as
nutrient supplier or SRFs.
The results obtained from funnel analytical test (Fig. 9a) clearly
indicate that SMSs can be used as slow release nutrient supplier.
They have a greater tendency to hold the nutrients and also release
them slowly. Unmodified silicates release around 25–35% of nitrate
after first irrigation. More than 75% of applied nutrient is leached
out after 6th irrigation in case of soil. On the other hand SMSs show
its slow release tendency with only 15–20% of leaching after first
irrigation and around 40% after 6th irrigation and still show nearly
4% leaching after 24th irrigation which suggests its slow release
capacity. These results clearly demonstrate the slow release of N
from nutrient loaded SMSs. Also the level of N released after 24th
irrigation is sufficient for plant growth.3.4. SMSs as controlled suppliers of nutrient
Adsorption is a well-established technology for waste water
purification, however, its success for environmental and economic
reasons depends on the possibility of desorbing the target contam-
inant and reusing the adsorbent for a valuable resource such as
nutrient supplier or SRFs.
The results obtained from funnel analytical test (Fig. 9a) clearly
indicate that SMSs can be used as slow release nutrient supplier.
They have a greater tendency to hold the nutrients and also release
them slowly. Unmodified silicates release around 25–35% of nitrate
after first irrigation. More than 75% of applied nutrient is leached
out after 6th irrigation in case of soil. On the other hand SMSs show
its slow release tendency with only 15–20% of leaching after first
irrigation and around 40% after 6th irrigation and still show nearly
4% leaching after 24th irrigation which suggests its slow release
capacity. These results clearly demonstrate the slow release of N
from nutrient loaded SMSs. Also the level of N released after 24th
irrigation is sufficient for plant growth.3.4. SMSs as controlled suppliers of nutrient
Adsorption is a well-established technology for waste water
purification, however, its success for environmental and economic
reasons depends on the possibility of desorbing the target contam-
inant and reusing the adsorbent for a valuable resource such as
nutrient supplier or SRFs.
The results obtained from funnel analytical test (Fig. 9a) clearly
indicate that SMSs can be used as slow release nutrient supplier.
They have a greater tendency to hold the nutrients and also release
them slowly. Unmodified silicates release around 25–35% of nitrate
after first irrigation. More than 75% of applied nutrient is leached
out after 6th irrigation in case of soil. On the other hand SMSs show
its slow release tendency with only 15–20% of leaching after first
irrigation and around 40% after 6th irrigation and still show nearly
4% leaching after 24th irrigation which suggests its slow release
capacity. These results clearly demonstrate the slow release of N
from nutrient loaded SMSs. Also the level of N released after 24th
irrigation is sufficient for plant growth.3.4. SMSs as controlled suppliers of nutrient
Adsorption is a well-established technology for waste water
purification, however, its success for environmental and economic
reasons depends on the possibility of desorbing the target contam-
inant and reusing the adsorbent for a valuable resource such as
nutrient supplier or SRFs.
The results obtained from funnel analytical test (Fig. 9a) clearly
indicate that SMSs can be used as slow release nutrient supplier.
They have a greater tendency to hold the nutrients and also release
them slowly. Unmodified silicates release around 25–35% of nitrate
after first irrigation. More than 75% of applied nutrient is leached
out after 6th irrigation in case of soil. On the other hand SMSs show
its slow release tendency with only 15–20% of leaching after first
irrigation and around 40% after 6th irrigation and still show nearly
4% leaching after 24th irrigation which suggests its slow release
capacity. These results clearly demonstrate the slow release of N
from nutrient loaded SMSs. Also the level of N released after 24th
irrigation is sufficient for plant growth.3.4. SMSs as controlled suppliers of nutrient
Adsorption is a well-established technology for waste water
purification, however, its success for environmental and economic
reasons depends on the possibility of desorbing the target contaminant and reusing the adsorbent for a valuable resource such as
nutrient supplier or SRFs.
The results obtained from funnel analytical test (Fig. 9a) clearly
indicate that SMSs can be used as slow release nutrient supplier.
They have a greater tendency to hold the nutrients and also release
them slowly. Unmodified silicates release around 25–35% of nitrate
after first irrigation. More than 75% of applied nutrient is leached
out after 6th irrigation in case of soil. On the other hand SMSs show
its slow release tendency with only 15–20% of leaching after first
irrigation and around 40% after 6th irrigation and still show nearly
4% leaching after 24th irrigation which suggests its slow release
capacity. These results clearly demonstrate the slow release of N
from nutrient loaded SMSs. Also the level of N released after 24th
irrigation is sufficient for plant growth.3.4. SMSs as controlled suppliers of nutrient
Adsorption is a well-established technology for waste water
purification, however, its success for environmental and economic
reasons depends on the possibility of desorbing the target contaminant and reusing the adsorbent for a valuable resource such as
nutrient supplier or SRFs.
The results obtained from funnel analytical test (Fig. 9a) clearly
indicate that SMSs can be used as slow release nutrient supplier.
They have a greater tendency to hold the nutrients and also release
them slowly. Unmodified silicates release around 25–35% of nitrate
after first irrigation. More than 75% of applied nutrient is leached
out after 6th irrigation in case of soil. On the other hand SMSs show
its slow release tendency with only 15–20% of leaching after first
irrigation and around 40% after 6th irrigation and still show nearly
4% leaching after 24th irrigation which suggests its slow release
capacity. These results clearly demonstrate the slow release of N
from nutrient loaded SMSs. Also the level of N released after 24th
irrigation is sufficient for plant growth.
Adsorption is a well-established technology for waste water
purification, however, its success for environmental and economic
reasons depends on the possibility of desorbing the target contam-
inant and reusing the adsorbent for a valuable resource such as
nutrient supplier or SRFs.
The results obtained from funnel analytical test (Fig. 9a) clearly
indicate that SMSs can be used as slow release nutrient supplier.
They have a greater tendency to hold the nutrients and also release
them slowly. Unmodified silicates release around 25–35% of nitrate
after first irrigation. More than 75% of applied nutrient is leached
out after 6th irrigation in case of soil. On the other hand SMSs show
its slow release tendency with only 15–20% of leaching after first
irrigation and around 40% after 6th irrigation and still show nearly
4% leaching after 24th irrigation which suggests its slow release
capacity. These results clearly demonstrate the slow release of N
from nutrient loaded SMSs. Also the level of N released after 24th
irrigation is sufficient for plant growth. 3.4. SMSs as controlled suppliers of nutrient
Adsorption is a well-established technology for waste water
purification, however, its success for environmental and economic
reasons depends on the possibility of desorbing the target contam-
inant and reusing the adsorbent for a valuable resource such as
nutrient supplier or SRFs.
The results obtained from funnel analytical test (Fig. 9a) clearly
indicate that SMSs can be used as slow release nutrient supplier.
They have a greater tendency to hold the nutrients and also release
them slowly. Unmodified silicates release around 25–35% of nitrate
after first irrigation. More than 75% of applied nutrient is leached
out after 6th irrigation in case of soil. On the other hand SMSs show
its slow release tendency with only 15–20% of leaching after first
irrigation and around 40% after 6th irrigation and still show nearly
4% leaching after 24th irrigation which suggests its slow release
capacity. These results clearly demonstrate the slow release of N
from nutrient loaded SMSs. Also the level of N released after 24th
irrigation is sufficient for plant growth.3.4. SMSs as controlled suppliers of nutrient
Adsorption is a well-established technology for waste water
purification, however, its success for environmental and economic
reasons depends on the possibility of desorbing the target contam-
inant and reusing the adsorbent for a valuable resource such as
nutrient supplier or SRFs.
The results obtained from funnel analytical test (Fig. 9a) clearly
indicate that SMSs can be used as slow release nutrient supplier.
They have a greater tendency to hold the nutrients and also release
them slowly. Unmodified silicates release around 25–35% of nitrate
after first irrigation. More than 75% of applied nutrient is leached
out after 6th irrigation in case of soil. On the other hand SMSs show
its slow release tendency with only 15–20% of leaching after first
irrigation and around 40% after 6th irrigation and still show nearly
4% leaching after 24th irrigation which suggests its slow release
capacity. These results clearly demonstrate the slow release of N
from nutrient loaded SMSs. Also the level of N released after 24th
irrigation is sufficient for plant growth.3.4. SMSs as controlled suppliers of nutrient
Adsorption is a well-established technology for waste water
purification, however, its success for environmental and economic
reasons depends on the possibility of desorbing the target contam-
inant and reusing the adsorbent for a valuable resource such as
nutrient supplier or SRFs.
The results obtained from funnel analytical test (Fig. 9a) clearly
indicate that SMSs can be used as slow release nutrient supplier.
They have a greater tendency to hold the nutrients and also release
them slowly. Unmodified silicates release around 25–35% of nitrate
after first irrigation. More than 75% of applied nutrient is leached
out after 6th irrigation in case of soil. On the other hand SMSs show
its slow release tendency with only 15–20% of leaching after first
irrigation and around 40% after 6th irrigation and still show nearly
4% leaching after 24th irrigation which suggests its slow release
capacity. These results clearly demonstrate the slow release of N
from nutrient loaded SMSs. Also the level of N released after 24th
irrigation is sufficient for plant growth.3.4. SMSs as controlled suppliers of nutrient
Adsorption is a well-established technology for waste water
purification, however, its success for environmental and economic
reasons depends on the possibility of desorbing the target contam-
inant and reusing the adsorbent for a valuable resource such as
nutrient supplier or SRFs.
The results obtained from funnel analytical test (Fig. 9a) clearly
indicate that SMSs can be used as slow release nutrient supplier.
They have a greater tendency to hold the nutrients and also release
them slowly. Unmodified silicates release around 25–35% of nitrate
after first irrigation. More than 75% of applied nutrient is leached
out after 6th irrigation in case of soil. On the other hand SMSs show
its slow release tendency with only 15–20% of leaching after first
irrigation and around 40% after 6th irrigation and still show nearly
4% leaching after 24th irrigation which suggests its slow release
capacity. These results clearly demonstrate the slow release of N
from nutrient loaded SMSs. Also the level of N released after 24th
irrigation is sufficient for plant growth.3.4. SMSs as controlled suppliers of nutrient
Adsorption is a well-established technology for waste water
purification, however, its success for environmental and economic
reasons depends on the possibility of desorbing the target contam-
inant and reusing the adsorbent for a valuable resource such as
nutrient supplier or SRFs.
The results obtained from funnel analytical test (Fig. 9a) clearly
indicate that SMSs can be used as slow release nutrient supplier.
They have a greater tendency to hold the nutrients and also release
them slowly. Unmodified silicates release around 25–35% of nitrate
after first irrigation. More than 75% of applied nutrient is leached
out after 6th irrigation in case of soil. On the other hand SMSs show
its slow release tendency with only 15–20% of leaching after first
irrigation and around 40% after 6th irrigation and still show nearly
4% leaching after 24th irrigation which suggests its slow release
capacity. These results clearly demonstrate the slow release of N
from nutrient loaded SMSs. Also the level of N released after 24th
irrigation is sufficient for plant growth.3.4. SMSs as controlled suppliers of nutrient
Adsorption is a well-established technology for waste water
purification, however, its success for environmental and economic
reasons depends on the possibility of desorbing the target contaminant and reusing the adsorbent for a valuable resource such as
nutrient supplier or SRFs.
The results obtained from funnel analytical test (Fig. 9a) clearly
indicate that SMSs can be used as slow release nutrient supplier.
They have a greater tendency to hold the nutrients and also release
them slowly. Unmodified silicates release around 25–35% of nitrate
after first irrigation. More than 75% of applied nutrient is leached
out after 6th irrigation in case of soil. On the other hand SMSs show
its slow release tendency with only 15–20% of leaching after first
irrigation and around 40% after 6th irrigation and still show nearly
4% leaching after 24th irrigation which suggests its slow release
capacity. These results clearly demonstrate the slow release of N
from nutrient loaded SMSs. Also the level of N released after 24th
irrigation is sufficient for plant growth.3.4. SMSs as controlled suppliers of nutrient
Adsorption is a well-established technology for waste water
purification, however, its success for environmental and economic
reasons depends on the possibility of desorbing the target contaminant and reusing the adsorbent for a valuable resource such as
nutrient supplier or SRFs.
The results obtained from funnel analytical test (Fig. 9a) clearly
indicate that SMSs can be used as slow release nutrient supplier.
They have a greater tendency to hold the nutrients and also release
them slowly. Unmodified silicates release around 25–35% of nitrate
after first irrigation. More than 75% of applied nutrient is leached
out after 6th irrigation in case of soil. On the other hand SMSs show
its slow release tendency with only 15–20% of leaching after first
irrigation and around 40% after 6th irrigation and still show nearly
4% leaching after 24th irrigation which suggests its slow release
capacity. These results clearly demonstrate the slow release of N
from nutrient loaded SMSs. Also the level of N released after 24th
irrigation is sufficient for plant growth.
0/5000
3.4. SMSs as controlled suppliers of nutrientAdsorption is a well-established technology for waste waterpurification, however, its success for environmental and economicreasons depends on the possibility of desorbing the target contam-inant and reusing the adsorbent for a valuable resource such asnutrient supplier or SRFs.The results obtained from funnel analytical test (Fig. 9a) clearlyindicate that SMSs can be used as slow release nutrient supplier.They have a greater tendency to hold the nutrients and also releasethem slowly. Unmodified silicates release around 25–35% of nitrateafter first irrigation. More than 75% of applied nutrient is leachedout after 6th irrigation in case of soil. On the other hand SMSs showits slow release tendency with only 15–20% of leaching after firstirrigation and around 40% after 6th irrigation and still show nearly4% leaching after 24th irrigation which suggests its slow releasecapacity. These results clearly demonstrate the slow release of Nfrom nutrient loaded SMSs. Also the level of N released after 24thirrigation is sufficient for plant growth. 3.4. SMSs as controlled suppliers of nutrientAdsorption is a well-established technology for waste waterpurification, however, its success for environmental and economicreasons depends on the possibility of desorbing the target contam-inant and reusing the adsorbent for a valuable resource such as
nutrient supplier or SRFs.
The results obtained from funnel analytical test (Fig. 9a) clearly
indicate that SMSs can be used as slow release nutrient supplier.
They have a greater tendency to hold the nutrients and also release
them slowly. Unmodified silicates release around 25–35% of nitrate
after first irrigation. More than 75% of applied nutrient is leached
out after 6th irrigation in case of soil. On the other hand SMSs show
its slow release tendency with only 15–20% of leaching after first
irrigation and around 40% after 6th irrigation and still show nearly
4% leaching after 24th irrigation which suggests its slow release
capacity. These results clearly demonstrate the slow release of N
from nutrient loaded SMSs. Also the level of N released after 24th
irrigation is sufficient for plant growth.3.4. SMSs as controlled suppliers of nutrient
Adsorption is a well-established technology for waste water
purification, however, its success for environmental and economic
reasons depends on the possibility of desorbing the target contam-
inant and reusing the adsorbent for a valuable resource such as
nutrient supplier or SRFs.
The results obtained from funnel analytical test (Fig. 9a) clearly
indicate that SMSs can be used as slow release nutrient supplier.
They have a greater tendency to hold the nutrients and also release
them slowly. Unmodified silicates release around 25–35% of nitrate
after first irrigation. More than 75% of applied nutrient is leached
out after 6th irrigation in case of soil. On the other hand SMSs show
its slow release tendency with only 15–20% of leaching after first
irrigation and around 40% after 6th irrigation and still show nearly
4% leaching after 24th irrigation which suggests its slow release
capacity. These results clearly demonstrate the slow release of N
from nutrient loaded SMSs. Also the level of N released after 24th
irrigation is sufficient for plant growth.3.4. SMSs as controlled suppliers of nutrient
Adsorption is a well-established technology for waste water
purification, however, its success for environmental and economic
reasons depends on the possibility of desorbing the target contam-
inant and reusing the adsorbent for a valuable resource such as
nutrient supplier or SRFs.
The results obtained from funnel analytical test (Fig. 9a) clearly
indicate that SMSs can be used as slow release nutrient supplier.
They have a greater tendency to hold the nutrients and also release
them slowly. Unmodified silicates release around 25–35% of nitrate
after first irrigation. More than 75% of applied nutrient is leached
out after 6th irrigation in case of soil. On the other hand SMSs show
its slow release tendency with only 15–20% of leaching after first
irrigation and around 40% after 6th irrigation and still show nearly
4% leaching after 24th irrigation which suggests its slow release
capacity. These results clearly demonstrate the slow release of N
from nutrient loaded SMSs. Also the level of N released after 24th
irrigation is sufficient for plant growth.3.4. SMSs as controlled suppliers of nutrient
Adsorption is a well-established technology for waste water
purification, however, its success for environmental and economic
reasons depends on the possibility of desorbing the target contam-
inant and reusing the adsorbent for a valuable resource such as
nutrient supplier or SRFs.
The results obtained from funnel analytical test (Fig. 9a) clearly
indicate that SMSs can be used as slow release nutrient supplier.
They have a greater tendency to hold the nutrients and also release
them slowly. Unmodified silicates release around 25–35% of nitrate
after first irrigation. More than 75% of applied nutrient is leached
out after 6th irrigation in case of soil. On the other hand SMSs show
its slow release tendency with only 15–20% of leaching after first
irrigation and around 40% after 6th irrigation and still show nearly
4% leaching after 24th irrigation which suggests its slow release
capacity. These results clearly demonstrate the slow release of N
from nutrient loaded SMSs. Also the level of N released after 24th
irrigation is sufficient for plant growth.3.4. SMSs as controlled suppliers of nutrient
Adsorption is a well-established technology for waste water
purification, however, its success for environmental and economic
reasons depends on the possibility of desorbing the target contam-
inant and reusing the adsorbent for a valuable resource such as
nutrient supplier or SRFs.
The results obtained from funnel analytical test (Fig. 9a) clearly
indicate that SMSs can be used as slow release nutrient supplier.
They have a greater tendency to hold the nutrients and also release
them slowly. Unmodified silicates release around 25–35% of nitrate
after first irrigation. More than 75% of applied nutrient is leached
out after 6th irrigation in case of soil. On the other hand SMSs show
its slow release tendency with only 15–20% of leaching after first
irrigation and around 40% after 6th irrigation and still show nearly
4% leaching after 24th irrigation which suggests its slow release
capacity. These results clearly demonstrate the slow release of N
from nutrient loaded SMSs. Also the level of N released after 24th
irrigation is sufficient for plant growth.3.4. SMSs as controlled suppliers of nutrient
Adsorption is a well-established technology for waste water
purification, however, its success for environmental and economic
reasons depends on the possibility of desorbing the target contaminant and reusing the adsorbent for a valuable resource such as
nutrient supplier or SRFs.
The results obtained from funnel analytical test (Fig. 9a) clearly
indicate that SMSs can be used as slow release nutrient supplier.
They have a greater tendency to hold the nutrients and also release
them slowly. Unmodified silicates release around 25–35% of nitrate
after first irrigation. More than 75% of applied nutrient is leached
out after 6th irrigation in case of soil. On the other hand SMSs show
its slow release tendency with only 15–20% of leaching after first
irrigation and around 40% after 6th irrigation and still show nearly
4% leaching after 24th irrigation which suggests its slow release
capacity. These results clearly demonstrate the slow release of N
from nutrient loaded SMSs. Also the level of N released after 24th
irrigation is sufficient for plant growth.3.4. SMSs as controlled suppliers of nutrient
Adsorption is a well-established technology for waste water
purification, however, its success for environmental and economic
reasons depends on the possibility of desorbing the target contaminant and reusing the adsorbent for a valuable resource such as
nutrient supplier or SRFs.
The results obtained from funnel analytical test (Fig. 9a) clearly
indicate that SMSs can be used as slow release nutrient supplier.
They have a greater tendency to hold the nutrients and also release
them slowly. Unmodified silicates release around 25–35% of nitrate
after first irrigation. More than 75% of applied nutrient is leached
out after 6th irrigation in case of soil. On the other hand SMSs show
its slow release tendency with only 15–20% of leaching after first
irrigation and around 40% after 6th irrigation and still show nearly
4% leaching after 24th irrigation which suggests its slow release
capacity. These results clearly demonstrate the slow release of N
from nutrient loaded SMSs. Also the level of N released after 24th
irrigation is sufficient for plant growth.
nutrient supplier or SRFs.
The results obtained from funnel analytical test (Fig. 9a) clearly
indicate that SMSs can be used as slow release nutrient supplier.
They have a greater tendency to hold the nutrients and also release
them slowly. Unmodified silicates release around 25–35% of nitrate
after first irrigation. More than 75% of applied nutrient is leached
out after 6th irrigation in case of soil. On the other hand SMSs show
its slow release tendency with only 15–20% of leaching after first
irrigation and around 40% after 6th irrigation and still show nearly
4% leaching after 24th irrigation which suggests its slow release
capacity. These results clearly demonstrate the slow release of N
from nutrient loaded SMSs. Also the level of N released after 24th
irrigation is sufficient for plant growth.3.4. SMSs as controlled suppliers of nutrient
Adsorption is a well-established technology for waste water
purification, however, its success for environmental and economic
reasons depends on the possibility of desorbing the target contam-
inant and reusing the adsorbent for a valuable resource such as
nutrient supplier or SRFs.
The results obtained from funnel analytical test (Fig. 9a) clearly
indicate that SMSs can be used as slow release nutrient supplier.
They have a greater tendency to hold the nutrients and also release
them slowly. Unmodified silicates release around 25–35% of nitrate
after first irrigation. More than 75% of applied nutrient is leached
out after 6th irrigation in case of soil. On the other hand SMSs show
its slow release tendency with only 15–20% of leaching after first
irrigation and around 40% after 6th irrigation and still show nearly
4% leaching after 24th irrigation which suggests its slow release
capacity. These results clearly demonstrate the slow release of N
from nutrient loaded SMSs. Also the level of N released after 24th
irrigation is sufficient for plant growth.3.4. SMSs as controlled suppliers of nutrient
Adsorption is a well-established technology for waste water
purification, however, its success for environmental and economic
reasons depends on the possibility of desorbing the target contam-
inant and reusing the adsorbent for a valuable resource such as
nutrient supplier or SRFs.
The results obtained from funnel analytical test (Fig. 9a) clearly
indicate that SMSs can be used as slow release nutrient supplier.
They have a greater tendency to hold the nutrients and also release
them slowly. Unmodified silicates release around 25–35% of nitrate
after first irrigation. More than 75% of applied nutrient is leached
out after 6th irrigation in case of soil. On the other hand SMSs show
its slow release tendency with only 15–20% of leaching after first
irrigation and around 40% after 6th irrigation and still show nearly
4% leaching after 24th irrigation which suggests its slow release
capacity. These results clearly demonstrate the slow release of N
from nutrient loaded SMSs. Also the level of N released after 24th
irrigation is sufficient for plant growth.3.4. SMSs as controlled suppliers of nutrient
Adsorption is a well-established technology for waste water
purification, however, its success for environmental and economic
reasons depends on the possibility of desorbing the target contam-
inant and reusing the adsorbent for a valuable resource such as
nutrient supplier or SRFs.
The results obtained from funnel analytical test (Fig. 9a) clearly
indicate that SMSs can be used as slow release nutrient supplier.
They have a greater tendency to hold the nutrients and also release
them slowly. Unmodified silicates release around 25–35% of nitrate
after first irrigation. More than 75% of applied nutrient is leached
out after 6th irrigation in case of soil. On the other hand SMSs show
its slow release tendency with only 15–20% of leaching after first
irrigation and around 40% after 6th irrigation and still show nearly
4% leaching after 24th irrigation which suggests its slow release
capacity. These results clearly demonstrate the slow release of N
from nutrient loaded SMSs. Also the level of N released after 24th
irrigation is sufficient for plant growth.3.4. SMSs as controlled suppliers of nutrient
Adsorption is a well-established technology for waste water
purification, however, its success for environmental and economic
reasons depends on the possibility of desorbing the target contam-
inant and reusing the adsorbent for a valuable resource such as
nutrient supplier or SRFs.
The results obtained from funnel analytical test (Fig. 9a) clearly
indicate that SMSs can be used as slow release nutrient supplier.
They have a greater tendency to hold the nutrients and also release
them slowly. Unmodified silicates release around 25–35% of nitrate
after first irrigation. More than 75% of applied nutrient is leached
out after 6th irrigation in case of soil. On the other hand SMSs show
its slow release tendency with only 15–20% of leaching after first
irrigation and around 40% after 6th irrigation and still show nearly
4% leaching after 24th irrigation which suggests its slow release
capacity. These results clearly demonstrate the slow release of N
from nutrient loaded SMSs. Also the level of N released after 24th
irrigation is sufficient for plant growth.3.4. SMSs as controlled suppliers of nutrient
Adsorption is a well-established technology for waste water
purification, however, its success for environmental and economic
reasons depends on the possibility of desorbing the target contaminant and reusing the adsorbent for a valuable resource such as
nutrient supplier or SRFs.
The results obtained from funnel analytical test (Fig. 9a) clearly
indicate that SMSs can be used as slow release nutrient supplier.
They have a greater tendency to hold the nutrients and also release
them slowly. Unmodified silicates release around 25–35% of nitrate
after first irrigation. More than 75% of applied nutrient is leached
out after 6th irrigation in case of soil. On the other hand SMSs show
its slow release tendency with only 15–20% of leaching after first
irrigation and around 40% after 6th irrigation and still show nearly
4% leaching after 24th irrigation which suggests its slow release
capacity. These results clearly demonstrate the slow release of N
from nutrient loaded SMSs. Also the level of N released after 24th
irrigation is sufficient for plant growth.3.4. SMSs as controlled suppliers of nutrient
Adsorption is a well-established technology for waste water
purification, however, its success for environmental and economic
reasons depends on the possibility of desorbing the target contaminant and reusing the adsorbent for a valuable resource such as
nutrient supplier or SRFs.
The results obtained from funnel analytical test (Fig. 9a) clearly
indicate that SMSs can be used as slow release nutrient supplier.
They have a greater tendency to hold the nutrients and also release
them slowly. Unmodified silicates release around 25–35% of nitrate
after first irrigation. More than 75% of applied nutrient is leached
out after 6th irrigation in case of soil. On the other hand SMSs show
its slow release tendency with only 15–20% of leaching after first
irrigation and around 40% after 6th irrigation and still show nearly
4% leaching after 24th irrigation which suggests its slow release
capacity. These results clearly demonstrate the slow release of N
from nutrient loaded SMSs. Also the level of N released after 24th
irrigation is sufficient for plant growth.
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3.4. SMS như các nhà cung cấp kiểm soát lượng chất dinh dưỡng hấp phụ là một công nghệ cũng như thành lập đối với nước thải sạch, tuy nhiên, thành công của nó đối với môi trường và kinh tế lý do phụ thuộc vào khả năng của desorbing mục tiêu nhiễm bẩn inant và tái sử dụng chất hấp phụ cho một nguồn tài nguyên có giá trị như nhà cung cấp chất dinh dưỡng hoặc SRFs. Các kết quả thu được từ phễu kiểm tra phân tích (Hình 9a.) rõ ràng cho thấy rằng hệ thống SMS có thể được sử dụng như là nhà cung cấp phát hành chậm dinh dưỡng. Họ có xu hướng lớn hơn để giữ các chất dinh dưỡng và cũng giải phóng chúng từ từ. Silicat chưa sửa đổi thả khoảng 25-35% của nitrat sau khi rửa đầu tiên. Hơn 75% các chất dinh dưỡng được áp dụng rửa trôi ra sau khi tưới thứ 6 trong trường hợp của đất. Trên hệ thống SMS mặt khác cho thấy xu hướng phát hành chậm chạp của nó chỉ có 15-20% sau khi lọc đầu tiên tưới và khoảng 40% sau khi tưới thứ 6 và vẫn hiển thị gần 4% sau khi lọc thủy lợi ngày 24 mà thấy phát hành chậm chạp của nó năng lực. Những kết quả này chứng minh rõ ràng việc phát hành chậm của N từ hệ thống SMS nạp chất dinh dưỡng. Ngoài ra mức độ của N phát hành sau ngày 24 thủy lợi là đủ để cây phát triển. 3.4. SMS như các nhà cung cấp kiểm soát lượng chất dinh dưỡng hấp phụ là một công nghệ cũng như thành lập đối với nước thải sạch, tuy nhiên, thành công của nó đối với môi trường và kinh tế lý do phụ thuộc vào khả năng của desorbing mục tiêu nhiễm bẩn inant và tái sử dụng chất hấp phụ cho một nguồn tài nguyên có giá trị như nhà cung cấp chất dinh dưỡng hoặc SRFs. Các kết quả thu được từ phễu kiểm tra phân tích (Hình 9a.) rõ ràng cho thấy rằng hệ thống SMS có thể được sử dụng như là nhà cung cấp phát hành chậm dinh dưỡng. Họ có xu hướng lớn hơn để giữ các chất dinh dưỡng và cũng giải phóng chúng từ từ. Silicat chưa sửa đổi thả khoảng 25-35% của nitrat sau khi rửa đầu tiên. Hơn 75% các chất dinh dưỡng được áp dụng rửa trôi ra sau khi tưới thứ 6 trong trường hợp của đất. Trên hệ thống SMS mặt khác cho thấy xu hướng phát hành chậm chạp của nó chỉ có 15-20% sau khi lọc đầu tiên tưới và khoảng 40% sau khi tưới thứ 6 và vẫn hiển thị gần 4% sau khi lọc thủy lợi ngày 24 mà thấy phát hành chậm chạp của nó năng lực. Những kết quả này chứng minh rõ ràng việc phát hành chậm của N từ hệ thống SMS nạp chất dinh dưỡng. Ngoài ra mức độ của N phát hành sau ngày 24 thủy lợi là đủ cho growth.3.4 thực vật. SMS như các nhà cung cấp kiểm soát lượng chất dinh dưỡng hấp phụ là một công nghệ cũng như thành lập đối với nước thải sạch, tuy nhiên, thành công của nó đối với môi trường và kinh tế lý do phụ thuộc vào khả năng của desorbing mục tiêu nhiễm bẩn inant và tái sử dụng chất hấp phụ cho một nguồn tài nguyên có giá trị như nhà cung cấp chất dinh dưỡng hoặc SRFs. Các kết quả thu được từ phễu kiểm tra phân tích (Hình 9a.) rõ ràng cho thấy rằng hệ thống SMS có thể được sử dụng như là nhà cung cấp phát hành chậm dinh dưỡng. Họ có xu hướng lớn hơn để giữ các chất dinh dưỡng và cũng giải phóng chúng từ từ. Silicat chưa sửa đổi thả khoảng 25-35% của nitrat sau khi rửa đầu tiên. Hơn 75% các chất dinh dưỡng được áp dụng rửa trôi ra sau khi tưới thứ 6 trong trường hợp của đất. Trên hệ thống SMS mặt khác cho thấy xu hướng phát hành chậm chạp của nó chỉ có 15-20% sau khi lọc đầu tiên tưới và khoảng 40% sau khi tưới thứ 6 và vẫn hiển thị gần 4% sau khi lọc thủy lợi ngày 24 mà thấy phát hành chậm chạp của nó năng lực. Những kết quả này chứng minh rõ ràng việc phát hành chậm của N từ hệ thống SMS nạp chất dinh dưỡng. Ngoài ra mức độ của N phát hành sau ngày 24 thủy lợi là đủ cho growth.3.4 thực vật. SMS như các nhà cung cấp kiểm soát lượng chất dinh dưỡng hấp phụ là một công nghệ cũng như thành lập đối với nước thải sạch, tuy nhiên, thành công của nó đối với môi trường và kinh tế lý do phụ thuộc vào khả năng của desorbing mục tiêu nhiễm bẩn inant và tái sử dụng chất hấp phụ cho một nguồn tài nguyên có giá trị như nhà cung cấp chất dinh dưỡng hoặc SRFs. Các kết quả thu được từ phễu kiểm tra phân tích (Hình 9a.) rõ ràng cho thấy rằng hệ thống SMS có thể được sử dụng như là nhà cung cấp phát hành chậm dinh dưỡng. Họ có xu hướng lớn hơn để giữ các chất dinh dưỡng và cũng giải phóng chúng từ từ. Silicat chưa sửa đổi thả khoảng 25-35% của nitrat sau khi rửa đầu tiên. Hơn 75% các chất dinh dưỡng được áp dụng rửa trôi ra sau khi tưới thứ 6 trong trường hợp của đất. Trên hệ thống SMS mặt khác cho thấy xu hướng phát hành chậm chạp của nó chỉ có 15-20% sau khi lọc đầu tiên tưới và khoảng 40% sau khi tưới thứ 6 và vẫn hiển thị gần 4% sau khi lọc thủy lợi ngày 24 mà thấy phát hành chậm chạp của nó năng lực. Những kết quả này chứng minh rõ ràng việc phát hành chậm của N từ hệ thống SMS nạp chất dinh dưỡng. Ngoài ra mức độ của N phát hành sau ngày 24 thủy lợi là đủ cho growth.3.4 thực vật. SMS như các nhà cung cấp kiểm soát lượng chất dinh dưỡng hấp phụ là một công nghệ cũng như thành lập đối với nước thải sạch, tuy nhiên, thành công của nó đối với môi trường và kinh tế lý do phụ thuộc vào khả năng của desorbing mục tiêu nhiễm bẩn inant và tái sử dụng chất hấp phụ cho một nguồn tài nguyên có giá trị như nhà cung cấp chất dinh dưỡng hoặc SRFs. Các kết quả thu được từ phễu kiểm tra phân tích (Hình 9a.) rõ ràng cho thấy rằng hệ thống SMS có thể được sử dụng như là nhà cung cấp phát hành chậm dinh dưỡng. Họ có xu hướng lớn hơn để giữ các chất dinh dưỡng và cũng giải phóng chúng từ từ. Silicat chưa sửa đổi thả khoảng 25-35% của nitrat sau khi rửa đầu tiên. Hơn 75% các chất dinh dưỡng được áp dụng rửa trôi ra sau khi tưới thứ 6 trong trường hợp của đất. Trên hệ thống SMS mặt khác cho thấy xu hướng phát hành chậm chạp của nó chỉ có 15-20% sau khi lọc đầu tiên tưới và khoảng 40% sau khi tưới thứ 6 và vẫn hiển thị gần 4% sau khi lọc thủy lợi ngày 24 mà thấy phát hành chậm chạp của nó năng lực. Những kết quả này chứng minh rõ ràng việc phát hành chậm của N từ hệ thống SMS nạp chất dinh dưỡng. Ngoài ra mức độ của N phát hành sau ngày 24 thủy lợi là đủ cho growth.3.4 thực vật. SMS như các nhà cung cấp kiểm soát lượng chất dinh dưỡng hấp phụ là một công nghệ cũng như thành lập đối với nước thải sạch, tuy nhiên, thành công của nó đối với môi trường và kinh tế lý do phụ thuộc vào khả năng của desorbing mục tiêu nhiễm bẩn inant và tái sử dụng chất hấp phụ cho một nguồn tài nguyên có giá trị như nhà cung cấp chất dinh dưỡng hoặc SRFs. Các kết quả thu được từ phễu kiểm tra phân tích (Hình 9a.) rõ ràng cho thấy rằng hệ thống SMS có thể được sử dụng như là nhà cung cấp phát hành chậm dinh dưỡng. Họ có xu hướng lớn hơn để giữ các chất dinh dưỡng và cũng giải phóng chúng từ từ. Silicat chưa sửa đổi thả khoảng 25-35% của nitrat sau khi rửa đầu tiên. Hơn 75% các chất dinh dưỡng được áp dụng rửa trôi ra sau khi tưới thứ 6 trong trường hợp của đất. Trên hệ thống SMS mặt khác cho thấy xu hướng phát hành chậm chạp của nó chỉ có 15-20% sau khi lọc đầu tiên tưới và khoảng 40% sau khi tưới thứ 6 và vẫn hiển thị gần 4% sau khi lọc thủy lợi ngày 24 mà thấy phát hành chậm chạp của nó năng lực. Những kết quả này chứng minh rõ ràng việc phát hành chậm của N từ hệ thống SMS nạp chất dinh dưỡng. Ngoài ra mức độ của N phát hành sau ngày 24 thủy lợi là đủ cho growth.3.4 thực vật. SMS như các nhà cung cấp kiểm soát lượng chất dinh dưỡng hấp phụ là một công nghệ cũng như thành lập đối với nước thải sạch, tuy nhiên, thành công của nó đối với môi trường và kinh tế lý do phụ thuộc vào khả năng của desorbing các chất gây ô nhiễm mục tiêu và tái sử dụng chất hấp phụ cho một nguồn tài nguyên có giá trị như nhà cung cấp chất dinh dưỡng hoặc SRFs . Các kết quả thu được từ kiểm tra phân tích phễu (Fig. 9a) rõ ràng cho thấy rằng hệ thống SMS có thể được sử dụng như là nhà cung cấp phát hành chậm dinh dưỡng. Họ có xu hướng lớn hơn để giữ các chất dinh dưỡng và cũng giải phóng chúng từ từ. Silicat chưa sửa đổi thả khoảng 25-35% của nitrat sau khi rửa đầu tiên. Hơn 75% các chất dinh dưỡng được áp dụng rửa trôi ra sau khi tưới thứ 6 trong trường hợp của đất. Trên hệ thống SMS mặt khác cho thấy xu hướng phát hành chậm chạp của nó chỉ có 15-20% sau khi lọc đầu tiên tưới và khoảng 40% sau khi tưới thứ 6 và vẫn hiển thị gần 4% sau khi lọc thủy lợi ngày 24 mà thấy phát hành chậm chạp của nó năng lực. Những kết quả này chứng minh rõ ràng việc phát hành chậm của N từ hệ thống SMS nạp chất dinh dưỡng. Ngoài ra mức độ của N phát hành sau ngày 24 thủy lợi là đủ cho growth.3.4 thực vật. SMS như các nhà cung cấp kiểm soát lượng chất dinh dưỡng hấp phụ là một công nghệ cũng như thành lập đối với nước thải sạch, tuy nhiên, thành công của nó đối với môi trường và kinh tế lý do phụ thuộc vào khả năng của desorbing các chất gây ô nhiễm mục tiêu và tái sử dụng chất hấp phụ cho một nguồn tài nguyên có giá trị như nhà cung cấp chất dinh dưỡng hoặc SRFs . Các kết quả thu được từ kiểm tra phân tích phễu (Fig. 9a) rõ ràng cho thấy rằng hệ thống SMS có thể được sử dụng như là nhà cung cấp phát hành chậm dinh dưỡng. Họ có xu hướng lớn hơn để giữ các chất dinh dưỡng và cũng giải phóng chúng từ từ. Silicat chưa sửa đổi thả khoảng 25-35% của nitrat sau khi rửa đầu tiên. Hơn 75% các chất dinh dưỡng được áp dụng rửa trôi ra sau khi tưới thứ 6 trong trường hợp của đất. Trên hệ thống SMS mặt khác cho thấy xu hướng phát hành chậm chạp của nó chỉ có 15-20% sau khi lọc đầu tiên tưới và khoảng 40% sau khi tưới thứ 6 và vẫn hiển thị gần 4% sau khi lọc thủy lợi ngày 24 mà thấy phát hành chậm chạp của nó năng lực. Những kết quả này chứng minh rõ ràng việc phát hành chậm của N từ hệ thống SMS nạp chất dinh dưỡng. Ngoài ra mức độ của N phát hành sau ngày 24 thủy lợi là đủ để cây phát triển.
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