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Effectiveness of Mole Drains for Soybean Crop in Temporary Waterlogged Vertisols of Madhya Pradesh

S. S Dhakad1 * , K. V2 and K. P Mishra3

1 KrishiVigyan Kendra (RVSKVV), Shajapur, 465001 Madhya Pradesh India

2 Central Institute of Agricultural Engineering (ICAR), Bhopal, Madhya Pradesh India

3 Faculty of Agricultural Engineering, Mahatma Gandhi Chitrakoot, GramodayaVishwavidyala, Chitrakoot, Madhya Pradesh India

DOI: http://dx.doi.org/10.12944/CWE.9.2.19

Field experiments were conducted during kharif 2010 to 2011 for sustaining productivity of soybean through mole drainage technology in temporary waterlogged vertisols at farmer’s fields in Hoshangabad district of Madhya Pradesh.The mole drain spacing selected includes 2, 4, 6 and 8 m and these drains were formed at an average depth of 0.4, 0.5 and 0.6 m from ground surface under a split plot designed experiment with 3 replications.Under various treatment combinations, the plant height, number of branches per plant, root nodules per plant, dry weight of root nodules per plant and yield of soybean crop are highest in 2 m drain spacing followed by 4m, 6m, 8m and control plot in all selected depths.The highest B: C ratio was recorded under S2D1 followed by S3D1, while the lowest net return was recorded under S4D3 in the year 2010-11. In 2011-12 and in pooled data analysis the B:C ratio was recorded higher under S1D1 followed by S1D2  respectively. The lowest B: C ratio under mole drain treatment was found under control plot.Pipe less drainage (mole) technology for vertisols of Madhya Pradesh is found better in view of soybean productivity.


Drainage; Drain Spacing; Drain Depth; Mole Drains; Soybean; Vertisols

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Dhakad S. S, Rao K. V. R, Mishra K. P. Effectiveness of Mole Drains for Soybean Crop in Temporary Waterlogged Vertisols of Madhya Pradesh. Curr World Environ 2014;9 (2) DOI:http://dx.doi.org/10.12944/CWE.9.2.19

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Dhakad S. S, Rao K. V. R, Mishra K. P. Effectiveness of Mole Drains for Soybean Crop in Temporary Waterlogged Vertisols of Madhya Pradesh. Curr World Environ 2014;9(2). Available from: http://www.cwejournal.org/?p=6325


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Received: 2014-03-09
Accepted: 2014-06-19

Introduction

Mole drainage is a temporary method of drainage. There maximum life of Mole drainage is 10- 30 years. Mole drainage alone, on the hand, usually offers a good solution to drainage problems in most clayed soils. Soil loosening by deep ploughing or subsoilingto improve hydraulic conductivity is only justified in situation where mole drainage would be unsuccessful. Drainage is a big problem in vertisolsspecially in the area having rainfall. There are several drainage technologies available in these area but low cost semi-permanent structure mole drains may be a best option. Mole drains are pipeless drains that are formed a with a mole plough. The mole plough consists of a cylindrical foot attached to a narrow leg connected to the back of the foot is a slightly larger diameter cylindrical expander. The foot and expander form the drainage channel as the implement is drawn through the soil and the leg leaves a slot and associated fissures. The fissures extend from the surface and laterally out into the soil. Any surplus water above moling depth can therefore move rapidly through these fissures into the mole channel.  Mole drains are generally installed at a depth varying between 40 to 60 cm below the surface. The mole drains should be deep enough to be protected from the loads of heavy farm machinery and fro m the swelling and thawing effect of vertisols. The spacing of mole drains generally varies from 2 to 10 m. However, it depends on the soil permeability and the necessity of drainage also. If the spacing is less than 2 m, there is a danger of damage of the previously constructed drain, where as if the spacing is greater than 5 m, the fissuring effect may not cover the intervening space.

Several researchers, mostly outside India have studied the influence of mole drainage on crop production. Eggelsmenn (1987) reported an increase in crop yield from 20 to over 100% due to pipeless drainage. Mueller and Schindler (1992) also found a significant increase in crop yields due to pipeless drainage over 10 years. Jha and Koga (1995) examined the impact of pipeless drainage on soil properties and on soybean growth in Bangkok soils. The effects of pipeless drainage on soil physical and chemical properties were found to be very significant : basic infiltration rate increased by about 2.7 fold, porosity increased by 14% at 25 cm depth and by 19% at 40 cm depth, soil aeration improved markedly, saturated hydraulic conductivity increased by 34 fold at 25 cm depth and by 61 fold at 40 cm depth, and pipeless drains with liming showed along-lasting improvement in soil pH and EC in the lower soil profile. Because of these improvements in the soil properties it was found that the soyabean crop responded very well to pipe less drainage. There was about 46% increase in grain yield and 118% increase in the dry matter per plant. K.V.Ramana Rao et.al. (2009) a 4- year (2004-2009) field experiment was carried out at Central Institute of Agricultural Engineering (CIAE), Bhopal feasibility of mole drainage for draining excess rain water in Vertisols. A 56 PS wheel tractor was used in the drawing of mole drains at 2, 4 and 6 m spacings and at a constant depth of 0.60 m at grade of 0.8 % .The soil moisture content was 22.5% at moling depth. The quantity of drained water from the plots under each of drain spacing was monitored using water meter. The drained area between each was 480 m2, 960 m2 and 1080 m2 for 2, 4 and 6 m drain spacings respectively. The crop yields increased by about 50% in the mole drained plots as compared to the control. The field capacity of  mole plough during formation of mole drains at 2,4 and 6 m drain spacing were 0.14,0.28 and 0.42 ha/h respectively while the cost per ha for construction of mole drains at 2,4 and 6 m drain spacing were Rs 3200,Rs 1800 and Rs 1200 respectively.

Considering the above aspects an attempt has been made under the present study to assess effectiveness of mole drains for soybean crop in temporary waterlogged vertisols of Madhya Pradesh.

Materials and Methods

The study area is located in the farmer’s fields inthe village Bamuriya in Hoshangabad district of Madhya Pradesh. The study area is situated between 22o37’30’’ to 22o38’10’’ N latitude and 77o39’30” to 77o40’59” E longitude with an altitude of 307 meters from mean sea level (MSL). The slope of the area is less than 1% with good drainage outlets.The dimensions of the mole plough designed and developed at CIAE include a leg with 1250 × 250 × 25 mm and a foot of 63 mm with 75 mm bullet or expander diameter. With a 3 point linkage the plough can be mounted on a wheeled tractor. The total weight of the plough was 75 kg. The treatments consisted of 13 combinations of mole drain spacing (4 levels) and mole drain depth (3 levels). The details of treatment combinations are given in Table 1.The mole drains installed 4 spacing (2,4,6 and 8m spacing) at 3 depths (0.4,0.5 and 0.6 m depth) under  a split plot designed experiment with 3 replications.

Table 1: Details of treatment combination for mole drains spacing and depths  

Symbol

Treatments detail for Soybean crop

T0

S0D0 –Control

T1

S1D1 (spacing 2 m + depth 0.4 m)

T2

S1D2 (spacing 2 m + depth 0.5 m)

T3

S1D3 (spacing 2 m + depth 0.6 m)

T4

S2D1 (spacing 4 m + depth 0.4 m)

T5

S2D2 spacing 4 m + depth 0.5 m)

T6

S2D3 (spacing 4 m + depth 0.6 m)

T7

S3D1 (Mole spacing 6 m + depth 0.4 m)

T8

S3D2 (Mole spacing 6 m + depth 0.5 m)

T9

S3D3 (Mole spacing 6 m + depth 0.6 m)

T10

S4D1 (Mole spacing 8 m + depth 0.4 m)

T11

S4D2 (Mole spacing 8 m + depth 0.5 m)

T12

S4D3 (Mole spacing 8 m + depth 0.6 m)

Measurement of different growth characters and yield of soybean Plant height

Plant height at 30, 45 and 60 days after sowing and at harvest stage was recorded. In each net plot five plants were selected randomly and tagged for periodic observation. The height (cm) was recorded at 30, 45, 60 DAS and at harvest stage of the crop in all the plots. It was measured from the ground surface to the main stem apex.

No. of Branches per plant

Number of branches was recorded at 30, 45, 60 DAS and at harvest stage of the crop in all the plots. It was measured on five plants which were selected randomly and tagged.

Root Studies

Root is a major part of the plant which provides anchoring and active participation in nutrient, moisture uptake and play effective role in fixation of atmospheric nitrogen. For root studies, observation on root length and root dry weight were recorded and analysed statistically.

Root Length

Five plants were selected randomly from each plot and the length of root was taken in cm. The observation on root length was taken at 45 and 60 days after sowing.

Root nodules per plant

As the root nodules play a vital role in the productivity, Five random plants dug up randomly in each plot and the root was washed for counting the number of nodules. This study was done at 45 and 60 days after sowing.

Dry weight of root nodules per plant

The dry weight of nodules was taken after oven drying at 70 ± 1 °C for 48 hours. This was also done at 45 and 60 DAS.

Seed yield

The soybean plants were harvested net plot-wise and then threshed after the sun drying. The seed yield of each net plot was recorded then converted in to kg/ha.

Benefit: cost ratio (B: C ratio)

It was calculated by dividing the gross return under a treatment by the cost of cultivation  under the same treatment and is expressed as returns per rupee invested.

Results and Discussion

Plant height under various mole drain treatments

The data on plant height, which is an important index of plant growth, were recorded periodically at an interval of 15 days beginning from 30 DAS and analyzed statistically and are presented in Table 2. The interactive effect of mole drain spacings and mole drain depths were found significant at 45 DAS, 60 DAS and at harvest stages of soybean in year 2010-11 and pooled data analysis however it was not found statistically significant at 45 DAS and 60 DAS during the year 2011-12. Maximum plant height was recorded in the case of combination S1D1 (mole drains at the spacing of 2 m on the depth of 0.4 m) followed by S1D2 (mole drains at the spacing of 2 m on the depth of 0.5 m) while it was recorded significantly lowest under S4D3 (mole drains at the spacing of 8 m on the depth of 0.6 m) in all the growth stages during both the years. Jha and Koga (1995), Ramana Rao et.al.(2005) and Kolekar et.al. (2011) also corroborated the same findings due to pipeless drainage.
 
Table 2:Effect of interaction S X D on plant height of soybean. Table 2: Effect of interaction S X D
on plant height of soybean.

Click here to View table

No. of branches per plant under various mole drain treatments

The number of branches per plant increased as the age of the crop advanced. and presented in Table 3 for different  growth  and at harvest stages of soybean. In case of interaction effects, maximum number of branches per plant at almost all the stages of soybean was recorded under S1D1 (mole drains at the spacing of 2 m on the depth of 0.4 m) followed by S1D2 (mole drains at the spacing of 2 m on the depth of 0.5 m). Whereas, the minimum values were noticed under the treatments S4D3 (mole drains at the spacing of 8 m on the depth of 0.6 m) and S0D0: Control. Similar findings were found by  Ramana Rao et.al. (2009) due to pipeless drainage in soybean crop.
 
Table 3:Effect of interaction S X D on No. of branch per plant of soybean at different growth  and at harvest stages Table 3: Effect of interaction S X D on No. of
branch per plant of soybean at different
growth and at harvest stages.

Click here to View table

Root length under various mole drain treatments

The root length under different treatments at 45 and 60 DAS is presented in Table 4.The maximum root length was noticed under combination  S1D1 (mole drains at the spacing of 2 m on the depth of 0.4 m) followed by S1D2 (mole drains at the spacing of 2 m on the depth of 0.5 m) at both the stages. The significantly least values were recorded under S4D3 (mole drains at the spacing of 8 m on the depth of 0.6 m) at 45 DAS and S4D2 (mole drains at the spacing of 8 m on the depth of 0.5 m) at 60 DAS. The values of root length were recorded lowest under the treatment S0D0: Control. Similar findings were obtained Jha and Koga (1995) due to pipeless drainage in soybean crop.

Table 4: Effect of interaction S X D on root length of soybean at 45 and 60 DAS  

Treatment

45 DAYS

60 DAYS

2010-11

2011-12

Pooled

2010-11

2011-12

Pooled

S0D0

10.80

9.44

10.12

12.26

13.47

12.87

S1D1

19.29

17.16

18.23

24.34

27.52

25.93

S1D2

19.48

17.65

18.57

23.77

27.85

25.81

S1D3

17.44

16.51

16.98

23.48

26.87

25.17

S2D1

17.62

16.66

17.14

21.18

25.10

23.14

S2D2

18.31

16.36

17.33

19.09

24.38

21.74

S2D3

16.68

16.10

16.39

20.42

24.47

22.45

S3D1

15.78

15.26

15.52

21.23

23.88

22.56

S3D2

14.30

14.37

14.34

19.21

21.31

20.26

S3D3

14.10

10.40

12.25

14.31

15.00

14.66

S4D1

15.83

14.96

15.40

14.41

16.22

15.32

S4D2

11.12

10.57

10.85

13.24

14.14

13.69

S4D3

11.05

10.20

10.62

13.81

13.97

13.89

SEm=

0.70

0.85

0.46

0.98

1.15

0.59

CD(5%)

2.16

2.62

1.43

3.03

3.55

1.83


Number of root nodules per plantunder various mole drain treatments

The root nodules are responsible for the fixation of atmospheric nitrogen in the soil. The data on number of root nodules per plant were taken at 45 DAS and 60 DAS and analyzed statistically and presented in Table 5.

Table 5: Effect of interaction S X D on Number of root nodules per plant of soybean at 45 and 60 DAS  

Treatment

45 DAYS

60 DAYS

2010-11

2011-12

Pooled

2010-11

2011-12

Pooled

S0D0

9.83

9.36

9.59

18.89

19.42

19.16

S1D1

19.40

19.15

19.27

36.82

35.99

36.41

S1D2

19.18

19.62

19.40

33.14

37.51

35.33

S1D3

18.40

18.54

18.47

35.19

34.79

34.99

S2D1

18.89

18.70

18.79

34.93

32.33

33.63

S2D2

17.35

18.41

17.88

33.54

33.91

33.73

S2D3

15.42

18.13

16.78

32.34

32.36

32.35

S3D1

15.18

15.00

15.09

27.83

28.53

28.18

S3D2

13.81

13.63

13.72

27.35

27.15

27.25

S3D3

12.98

12.96

12.97

23.81

23.08

23.44

S4D1

14.30

13.77

14.04

23.50

23.85

23.67

S4D2

11.58

10.73

11.16

20.17

22.95

21.56

S4D3

10.11

10.22

10.16

19.52

19.86

19.69

SEm=

0.92

1.10

0.70

1.97

1.57

1.05

CD (5%)

NS

NS

NS

NS

NS

NS


Interactive effects of spacing and depth of mole drains were found significant in the year 2011-12 and pooled analysis only at 60 DAS and treatment S1D1 (mole drains at the spacing of 2 m on the depth of 0.4 m) produced maximum root nodules per plant followed by S1D3 (mole drains at the spacing of 2 m on the depth of 0.6 m) in 2010-11 and S1D2 (mole drains at the spacing of 2 m on the depth of 0.5 m) during 2011-12 and pooled data analysis.  These treatments were significantly superior to control (no mole drains), which produced lowest number of root nodules per plant. Similar findings were obtained Jha and Koga (1995)  due to pipeless drainage in soybean crop.

Dry weight of root nodules per plantunder various mole drain treatments

The data on Dry weight of root nodules per plantunder various mole drain treatments were taken at 45 DAS and 60 DAS and analyzed statistically and presented in Table 6.

Table 6: Effect of interaction S X D on dry weight of root nodules per plant of soybean at different growth stages (mg)  

Treatment

45 DAYS

60 DAYS

2010-11

2011-12

Pooled

2010-11

2011-12

Pooled

S0D0

147.47

149.90

148.68

270.60

267.10

268.85

S1D1

260.33

268.23

264.28

450.44

450.50

450.47

S1D2

260.87

261.21

261.04

432.67

423.59

428.13

S1D3

263.13

251.65

257.39

407.93

403.64

405.78

S2D1

237.72

260.83

249.27

415.76

410.61

413.19

S2D2

236.24

240.13

238.18

391.03

370.08

380.55

S2D3

215.22

222.81

219.02

380.09

413.52

396.80

S3D1

209.25

204.39

206.82

404.00

326.43

365.21

S3D2

184.65

231.53

208.09

311.95

370.95

341.45

S3D3

201.99

178.73

190.36

327.93

251.54

289.74

S4D1

182.03

174.93

178.48

281.10

343.39

312.24

S4D2

142.57

154.23

148.40

302.21

270.64

286.43

S4D3

141.03

156.29

148.66

302.07

272.27

287.17

SEm=

6.84

7.78

4.35

15.07

15.35

8.76

CD(5%)

21.07

23.97

13.41

46.42

47.29

27.00


Interaction of spacing and depth of mole drains was found significant in both the years and in pooled analysis of data at 45 DAS while at 60 DAS it was found significant in the year 2011-12 and pooled data analysis. S1D1 (mole drains at the spacing of 2 m on the depth of 0.4 m) and S1D2 (mole drains at the spacing of 2 m on the depth of 0.5 m) produced maximum dry weight of nodules per plant during both the years as well as in pooled data; however they were statistically at par with each other. Minimum values were observed under S4D3 (mole drains at the spacing of 8 m on the depth of 0.6 m) and control (no mole drains).

Seed yields and B:C ratio under various mole drain treatments

Seed yields and B:C ratio under various mole drain treatment are presented in Table 7.The maximum seed yields was  recorded under S1D1 (mole drains at the spacing of 2 m on the depth of 0.4 m) followed by S1D2 (mole drains at the spacing of 2 m on the depth of 0.5 m) and S1D3 (mole drains at the spacing of 2 m on the depth of 0.6 m) during boththe year and pooled data as well. The highest productivity of 16.4 q/ha observed in the treatments with mole drains at 2m spacing with 0.4m depth while it was found lowest under control (8.4 q/ha) followed by S4D3 (mole drains at the spacing of 8 m on the depth of 0.6 m) treatment. The highest B: C ratio was recorded under S2D1 followed by S3D1, while the lowest net return was recorded under S4D3 in the year 2010-11. In 2011-12 and in pooled data analysis the B:C ratio was recorded higher under S1D1 followed by S1D2  respectively. The lowest B: C ratio under mole drain treatment was found under control plot followed by S4D3in pooled data analysis. Under the absolute control the values were found to be lowest as compared to all the treatments. Jha and Koga (1995 and Ramana Rao et.al. (2009 & 2012) also reported an increase in crop yield due to pipeless drainage in Vertisol.

Table 7: Seed and benefit cost ratio of various mole drain treatment  

Treatment

Seed yield (kg/ha)

B: C ratio

2010-11

2011-12

Pooled

2010-11

2011-12

Pooled

S0D0: Control

888.19

805.46

846.83

1.04

1.12

1.08

S1D1: 2m S X 0.4 m D

1630.68

1650.63

1640.66

1.52

2.32

1.92

S1D2: 2m S X 0.5 m D

1621.58

1645.97

1633.77

1.50

2.31

1.91

S1D3: 2m S X 0.6 m D

1572.49

1536.90

1554.70

1.43

2.16

1.79

S2D1: 4m S X 0.4 m D

1566.79

1502.15

1534.47

1.62

2.10

1.86

S2D2: 4m S X 0.5 m D

1541.18

1425.79

1483.48

1.59

2.00

1.79

S2D3: 4m S X 0.6 m D

1479.30

1482.15

1480.73

1.52

2.08

1.80

S3D1: 6m S X 0.4 m D

1482.30

1453.55

1467.93

1.61

2.05

1.83

S3D2: 6m S X 0.5 m D

1478.51

1432.17

1455.34

1.59

2.01

1.80

S3D3: 6m S X 0.6 m D

1382.01

1284.60

1333.31

1.48

1.80

1.64

S4D1: 8m S X 0.4 m D

1078.59

1077.58

1078.08

1.18

1.51

1.35

S4D2: 8m S X 0.5 m D

1036.99

1035.77

1036.38

1.14

1.45

1.30

S4D3: 8m S X 0.6 m D

1034.12

1016.80

1025.46

1.11

1.42

1.27

SEm=

15.87

23.59

11.41

0.02

0.03

0.02

CD(5%)

48.91

72.70

35.18

NS

0.10

0.05


Conclusions

Under actual field conditions studies on mole drains were taken up in Hoshangabad district of MP. Mole drain formation has bearing on the crop performance, which is also influenced by moledrain spacing and drain depth. In the present study plant height, number of branches per plant, root nodules per plant , dry weight of root nodules per plant and yield of soybean under different treatments were monitored. Mole drain with S1D1 (spacing of 2 m at the depth 0.4 m) was found better in comparison with other spacing and depth as well as the control. B:C ratio of mole drain with S2D1 (spacing of 4 m at the depth 0.4 m) &S1D1 (spacing of 2 m at the depth 0.4 m) were found most profitable during 1st year  and 2nd year of experiment respectively. Effect of mole drainagetechnology  on the yield &growth parameterof soybean under waterlogged conditions was found better.  Pipe less drainage (mole) technology for vertisols of Madhya Pradesh is found better in view of soybean productivity.

References
 

  1. Eggelsmann, R. (1987). Subsurface Drainage Introductions. Bulletin of the German Association for Water Resources and Land Improvement, Verlag Paul Parey, Hamburg, Germany, , 83 -120 (1987)
  2. Mueller, L. and U. Schindler (1992).Durability and hydraulic performance of mole channels in  alluvial clay soils. Proc. of the Int. Agril. Engg. Con., 7-10 Dec., 1992,Bangkok, Thailand, , 889-896 (1992)
  3. Jha, M. K. and Koga . Mole drainage: prospective drainage solution to Bangkok clay soil. Agriculture water management, 28(3) ,253-270 (1995).
  4. Ramana Rao K.V., Ravi Kishore and RamadharSingh..Mole drainage to enhance soybean production in waterlogged Vertisols.Jouranal of Agricultural Engineering46 (4) ,54-58 (2009).
  5. Kolekar O.L.,S.A.Patil, S.B.Patil and S.D.Rathod. Effect of different mole spacing on the yield of summer groundnut. International Journal of Agricultural Engineering ,4 (01),82-85 (2011).
  6. Ramana Rao K.V., Ravi Kishore and Ramadhar Singh.. Mole drainage studies in vertisols of Bhopal region- a case study”. Proce. of All India Seminar on Reclamation of waterlogged saline soils through drainage” held at Kota during 4-5 December,124-132 (2005).
  7. Ramana Rao K.V., and Ramadhar Singh.Pipe Less Drainage (Mole Drainage) Studies Under Actual Farmers’ Field Conditions  – A Case Study in India . Proceeding of 11th ICID International Drainage Workshop on Agricultural Drainage Needs and Future Priorities Pyramisa Hotel, Cairo, Egypt, September 23 – 27, 1-6 (2012).