Submit or Track your Manuscript LOG-IN

Evaluation of DNH-105 Strain for Fibre Yield and Quality in Comparison to Standard Cotton Varieties of Pakistan

SJA_31_2_87-93

Research Article

Evaluation of DNH-105 Strain for Fibre Yield and Quality in Comparison to Standard Cotton Varieties of Pakistan

Khalid Usman1*, Niamatullah Khan2, Fazal Yazdan3

1Department of Agronomy, Faculty of Agriculture, Gomal University, Dera Ismail Khan; 2Cotton Research Station, Dera Ismail Khan; 3Oil Seed Research Programme NARC, Islamabad, Pakistan.

Abstract | Yield and fibre quality performance of DNH-105 strain in comparison with standard cotton varieties (CIM-573, CRIS-342, Gomal-93, NIAB-112 and CIM-612) was assessed at Cotton Research Station, D.I. Khan, Pakistan, during growth season 2011-2013 in a randomized complete block design replicated thrice. The strain DNH-105 gave optimum yield owing to more bolls per plant (37.2), boll weight (3.4 g) plus higher ginning out turn (39.9%) compared to the standard varieties of cotton in Pakistan. The quality characteristics such as fibre length (29.2 mm), strength (28.5 g tex-1), micronaire (4.3µg inch–1) and uniformity (80.2%) were also higher for DNH-105 than other varieties. Ginning out turn ranged from 37.2 (CIM-612) to 39.9% (DNH-105). Fibre length ranged from a low of 28.3 (CIM-612) to a high of 29.2 mm (DNH-105) while fibre strength was observed 25.0 (CIM-612) to 28.5 (DNH-105) g tex-1. Micronaire value ranged from 4.3 (DNH-105) to 4.8 µg inch–1 (CIM-612). Fibre uniformity ranged from a low of 77.1 (CIM-612) to a high of 80.2% (DNH-105). It is concluded that strain DNH-105 has high yield potential and best suited to ago-climatic conditions of Dera Ismail Khan, Pakistan as compared to the other varieties of cotton.

Editor | Tahir Sarwar, The University of Agriculture, Peshawar, Pakistan.

Received | December 11, 2014; Accepted | June 09, 2015; Published | June 19, 2015

*Correspondence | Khalid Usman, Gomal University, Dera Ismail Khan, Pakistan; E-mail | [email protected]

Citation | Usman, K., N. Khan and F. Yazdan. 2015. Evaluation of DNH-105 strain for fibre yield and quality in comparison to standard cotton varieties of Pakistan. Sarhad Journal of Agriculture, 31(2): 87-93.

DOI | http://dx.doi.org/10.17582/journal.sja/2015/31.2.87.93

Keywords | Cotton, DNH-105 strain, Genotype, Yield and quality

Introduction

Cotton (Gossypium hirsutum L) is important cash crop and main stay of the economy of Pakistan. It is cultivated on an area of 3.2 million hectares with total production of 13.21 million bales (PCCC-2013; Ahmed et al., 2009). However, cotton yield is declining in the country due to several biotic and abiotic factors such as adverse weather conditions, heavy insect pests attack, late maturing and lack of resistant varieties, weeds infestation and diseases like leaf curl viruses (Huque, 1994; Arshad et al., 2003). The heavy insect pests and disease attack not only reduce cotton yield but also incur extra cost on crop management (Satpute et al., 1988; Roach and Culp, 1984). One possible remedy to maintain cotton yield and quality is to identify a suitable variety with yield potential and quality in the favourable environments (Razaq et al., 2004). Research results have revealed that existing cotton varieties are early maturing with challenges associated to low yield, high micronaire, short fibre length that needs to be tackled genetically (Hanif et al., 2005).

The new strain (DNH-105) has been developed at Cotton Research Station, D. I. Khan, Khyber Pakhtunkhwa, Pakistan in the year 1999 through hybridization of DPL 70 × E-288. The strain is short duration (180 days) with yield potential (3000 kg ha-1 seed cotton yield), better ginning out turn, excellent fibre characteristics and tolerance to heat stress as compared to the existing variety in cultivation. It is advantageous with spinning on higher counts of fibre. We, therefore, compared the performance of DNH-105 strain in comparison with varieties already in cultivation for higher cotton yield and quality. There is much variability between DNH-105 and standard cotton varieties in yield and quality characters. Literature review also revealed significant variations in cotton lint yield and fibre characteristics among different cultivars for examples CIM-573, CRIS-342, Gomal-93, NIAB-112, and CIM-612 (Muhammad, 2001; Moser et al., 2000; Basbag and Temiz, 2004). These commercial varieties are still under cultivation. However, presently their performance is not satisfactory probably due to loss of their yield potential besides biotic and abiotic stresses (Ehsan et al., 2008). Thus the present study was focused on improving cotton yield and quality through advancement of cotton strain having high yield potential.

Materials and Methods

Experimental location and soil type

A field trial was carried out under irrigated conditions at Cotton Research Area, D. I. Khan, Khyber Pakhtunkhwa, Pakistan, during 2011, 2012 and 2013. Soil of the site was Hyperthermic and Typic Torrifluvents with 0.78% organic matter and a pH of 7.9 with a history of wheat-cotton production under irrigated condition (Soil Survey Staff, 2009). The study area comes in arid to semi-arid region and requires irrigation for raising crops. The annual rainfall ranges from 180-280 mm with more rainfall during monsoon season. Weather data was obtained from Meteorological Station, Dera Ismail Khan situated x km from the experimental site (Table 1). Mean rainfall during 2011, 2012 and 2013 growing seasons were 125, 221and 117 mm, respectively. Mean maximum and minimum temperatures during 2011, 2012 and 2013 growing seasons were 35˚±4 and 14˚±6, 33˚±5 and 14˚±6, 34˚±3 and 14˚±6, respectively. Canal water was main source of irrigation. Soil samples taken from research field before sowing were analysed for soil physico-chemical characteristics. Soil was silty clay in texture, calcareous, having pH 7.9, and deficient in organic matter (0.78 %), total nitrogen (0.05 %), AB-DTPA extractable phosphorus (7.80 mg per kg soil), and rather high in available potash (193 mg per kg soil). Organic matter, total soil nitrogen, phosphorus, and potash were determined through Walkley and Black method (Nelson and Sommers, 1982), Kjeldhal (Bremner and Mulvaney 1982), spectrophotometer and flame photometer, respectively. The extractable phosphorus and potash in soil samples were determined by the AB-DTPA extractable method (Soltanpour, 1985).

Procedure and measurements

Yield and fibre quality of DNH-105 strain in comparison with standard cotton varieties (CIM-573, CRIS-342, Gomal-93, NIAB-112 and CIM-612) was assessed at Cotton Research Station, D.I. Khan, Pakistan, during 2011, 2012 and 2013 in a randomized complete block design replicated thrice. The land was prepared by giving disk plough followed by tiller and rotavator. After levelling, the field was divided into the required experimental units. The subplot size for each treatment was 10 m × 3 m, with row to row distance of 75 cm, and plant to plant 22.5 cm. Cotton was planted on 15th May in 2011, 2012 and 2013 by dibbling method. A week after emergence, cotton seedlings were thinned to one seedling dibble-1. Pre- emergence weedicide Pendimethline 33% @ 2.5 was sprayed at the time of seedbed preparation, while post-emergence herbicides i.e. haloxyfop-R-methyl and lactofen 24 EC were applied 35 days after sowing. Nitrogen and phosphorus were applied to all experimental units at 150 kg N ha-1 as urea and 50 kg P ha-1 as triple superphosphate (TSP). Whole of the P and one third of nitrogen was given at planting whereas rest of the two third of nitrogen was given in 2 equal splits with 2nd and 3rd irrigation. Crop was irrigated six times as per water requirement with two weeks interval from the start of square stage to the bolls through the growing season during both the years. All the agronomic practices were equally adopted. Common pesticides were regularly sprayed to keep crop free from insect pest attack.

Data recording

Data was recorded on bolls per plant, boll weight (g), seed cotton yield (kg ha-1), ginning outturn (GOT, %), micronaire (µg inch–1), fibre strength (g per tex), fibre length (mm), and uniformity. For cotton yield and yield attributes, five plants of cotton were tagged at random in each subplot and open matured bolls were counted at harvest. Data was also recorded on seed cotton yield plant-1 and boll weight (gram seed cotton per boll). Data on seed cotton was recorded on two central rows by handpicking in November. Total seed

Table 1: Average air temperature and rainfall at Cotton Research Station, Dera Ismail Khan during 2011-2013 growing seasons

2011

2012

2013

Month

Temperature (oC)

Rainfall (mm)

Temperature (oC)

Rainfall (mm)

Temperature (oC)

Rainfall (mm)

Max

Min

Ave rage

Max

Min

Ave rage

Max

Min

Aver age

April

34

16

25

12

32

18

25

41

33

17

25

2

May

43

27

35

7

38

24

31

3

39

23

31

80

June

42

26

34

35

40

26

33

3

41

25

33

22

July

38

26

32

50

37

27

32

49

40

28

34

-

August

37

27

32

17

35

26

31

36

37

27

32

-

September

36

24

30

4

33

23

27

75

37

25

31

6

October

30

18

24

-

32

16

24

-

33

21

27

6

November

28

12

20

-

27

11

19

-

26

10

18

1

cotton yield was determined by pooling over the picks including five plants sample yield. After recording the yield, GOT was determined by taking 100 g sample of seed cotton, which was passed through ginning to separate lint and seed. Samples of lint were sent to Central Cotton Research Institute, Multan, for quality analysis of fibre. Fibre quality attributes such as micronaire/fibre fineness, fibre length (mm), fibre strength (g tex-1) and uniformity were tested. Uniformity index was determined as “a ratio between the mean length and the upper half mean length of the fibres and was expressed in percentage (%). Low uniformity index indicates high content of short fibres that lowers the quality of the textile product.

Statistical analysis

Data were subjected to analysis of variance (ANOVA), using a randomized complete block design according to Steel and Torrie (1980). Treatment means were compared using least significant difference test at 5% level of probability. The MSTATC software (written by Dr. Russel Freed, Professor and Director of Crop and Soil Sciences Department of Michigan State University) was used for this purpose.

Results and Discussion

Bolls plant-1

Significant differences were observed among varieties for bolls plant-1 (Table 2). The strain DNH-105 produced maximum bolls per plant in the study as compared to standard variety, CIM-573 (Table 3). The lowest number of bolls per plant was obtained from CIM-612 in individual years and mean over years. Variations among varieties for bolls per plant may be owing to differences in genetic potential of the genotypes under study. Other researchers communicated analogous results who reported that there were significant variations among varieties for number of bolls per plant in a comparative study of new cotton cultivars for yield performance (Anwar et al., 2002; Copur, 2006). Moser et al. (2000) also reported similar findings. Although the other cotton varieties were also high yielding but their yield performance in the study region was not up to the mark. The possible reason may be the loss of their yield potential and their less adaptability to the changing edaphic and environmental conditions besides their susceptibility to various pests and diseases (Ehsan et al., 2008).

Boll weight (g)

Boll weight has direct relation with the final seed cotton yield. Boll weight was found significant in all the three years individually as well as mean over years (Table 2). Heavier boll weight was obtained from strain DNH-105 compared to CIM-573 (standard variety), while CIM-612 gave the lowest boll weight among the tested varieties (Table 3). Other researchers also reported similar findings while evaluating genotypes for yield and yield components (Hofs et al., 2006). The differences in boll weight may be due to the differences in varietal characteristics in response to change in environmental conditions. The most favourable response of DNH-105 for producing heaviest boll weight among the varieties indicates its best suitability to the agro climatic conditions of the study site (Anonymous, 1997).

Seed cotton yield (Kg ha-1)

Yield response of different genotypes was different (Table 2). DNH-105 gave similar yield to CIM-573(std), CRIS-342, and Gomal-93 in Y1 but signif

Table 2: Mean square values of bolls plant-1, boll weight (g), seed cotton yield (kg ha-1), ginning out turn (%), fibre length (mm), fibre strength (g tex-1), micronaire (µg inch–1) and uniformity (%) for different genotypes during 2011-2013

2011

Source

D.F

Boll plant-1

Boll weight

Seed cotton yield

GOT

Fiber length

Fiber strength

Micro naire

Unifo rmity

Replication

2

0.6

0.1

15622

0.1

0.1

0.2

0.0

0.2

Varieties

5

125.0**

0.5**

162128**

4.1**

0.6ns

4.7**

0.1**

0.9*

Error

10

0.3

0.1

14866

0.5

0.3

0.3

0.0

0.2

2012

Replication

2

2.0

0.0

3016

0.0

0.2

0.3

0.0

0.1

Varieties

5

104.8**

0.3**

256391**

3.3**

0.4*

4.5**

0.1*

0.9**

Error

10

0.5

0.0

11923

0.4

0.1

0.2

0.0

0.1

2013

Replication

2

1.8

0.0

43491

0.0

0.1

0.1

0.0

0.0

Varieties

5

102.2**

0.2*

320056**

3.3**

0.4ns

4.6**

0.1**

2.7**

Error

10

1.1

0.0

9055

0.4

0.2

0.5

0.0

0.2

Mean 3years

Replication

2

1.1

0.0

14300

0.0

0.1

0.2

0.0

0.0

Varieties

5

110.0**

0.3**

218723**

3.6**

0.4ns

4.5**

0.1**

1.3**

Error

10

0.3

0.0

4266

0.4

0.1

0.3

0.0

0.0

ns= non significant; Rep (y*)= replication over year; *Significant at the 0.05 probability level; **Significant at the 0.01 probability level.

Table 3: Bolls plant-1, boll weight (g), seed cotton yield (kg ha-1) and GOT (%) of varieties during 2011-2013 growing seasons

Varieties

Years

Mean

Years

Mean

2011

2012

2013

2011

2012

2013

Bolls plant-1

Boll weight

DNH-105

37.9a±0.2

36.7a±0.7

37.0a±1.0

37.2a±0.1

3.5a±0.6

3.2a±0.3

3.4a±0.5

3.4a ±0.4

CIM-573(std)

36.5b±0.1

34.4b±0.8

35.4a±2.0

35.4b±0.9

3.4ab±0.1

3.1a± 0.2

3.3ab±0.1

3.3a ±0.1

CRIS-342

29.9c±1.1

29.4c±0.8

29.1b±0.7

29.5c±0.7

2.7cd±0.1

2.6b±0.1

2.8c ±0.1

2.7bc ±0.0

Gomal-93

29.8c±0.2

29.7c±0.1

29.7b±0.1

29.7c±0.1

3.0bc±0.1

2.8ab±0.3

3.0bc±0.1

2.9b ±0.2

NIAB-112

23.7d±0.8

23.7d±0.8

23.7c±0.8

23.7d±0.8

2.6cd±0.1

2.5b±0.2

2.8c± 0.1

2.6bc ±0.1

CIM-612

22.0e±0.7

21.4e±1.5

22.8c±1.1

22.1e±0.6

2.5d±0.1

2.5b±0.1

2.7c±0.1

2.6c ±0.0

LSD0.05

1.0

1.3

1.9

0.9

0.4

0.4

0.4

0.3

Seed cotton yield

GOT

DNH-105

2315a±168

2626a±51

2874a±106

2605a±107

39.9a± 0.2

39.8a±0.1

40.0a±0.1

39.9a ±0.1

CIM-573(std)

2245a±106

2356b±106

2660b±95

2420b±62

39.4a±0.5

39.5a±0.4

39.8a±0.1

39.6a ±0.3

CRIS-342

2130a±143

1948cd±61

2074d±90

2051c±68

37.7b±0.8

38.1bc±1.1

38.1b±1.1

38.0b ±0.9

Gomal-93

2204a±134

2397b±167

2571b±106

2391b±98

39.1a±0.5

39.3ab±0.5

39.4a±0.4

39.3a ±0.5

NIAB-112

1830b±57

2081c±79

2341c±206

2084c±39

37.8b±1.0

38.1bc±0.7

38.1b±0.7

38.0b ±0.8

CIM-612

1752b±93

1875d±105

2071d±85

1899d±67

36.9b±0.5

37.1c±0.5

37.5b±0.3

37.2b ±0.3

LSD0.05

221.8

198.7

173.1

118.8

1.3

1.2

1.1

1.1

Note: Means followed by common letters or no letters do not differ significantly at P≤ 0.05.

icantly out yielded in Y2, Y3, and mean over years (Table 3). The higher seed cotton yield in case of DNH-105 may be attributed to higher yield components such as bolls plant-1 and boll weight. The better performance of DNH-105 may be due to its more suitability to the environmental conditions of the study site such as photoperiod, and temperature condition in addition to its peculiar genetic potential for

Table 4: Fibre length (mm), fibre strength (g tex-1),micronaire (µg inch–1) and uniformity ratio (%) of varieties during 2011-2013 growing seasons

Varieties

Years

Mean

Years

Mean

2011

2012

2013

2011

2012

2013

Fiber length

Fiber strength

DNH-105

29.3±0.2

29.0a±0.1

29.2±0.1

29.2±0.1

28.6a±0.2

28.3a±0.4

28.5a±0.1

28.5a±0.1

CIM-573(std)

29.3±0.4

29.1a±0.2

29.0±0.2

29.1±0.2

27.6ab±0.3

27.8ab±0.4

27.8ab±0.4

27.7ab±0.3

CRIS-342

28.4±0.6

28.2b±0.4

28.4±0.6

28.4±0.5

26.3c±0.5

25.9d±0.4

26.3c±0.5

26.2d±0.3

Gomal-93

29.1±0.6

28.8ab±0.1

29.1±0.6

29.0±0.4

27.4b±0.6

27.1bc±0.5

27.2abc±0.9

27.2bc±0.6

NIAB-112

29.2±0.5

29.0a±0.1

28.8±0.2

29.0±0.2

26.8bc±1.0

26.5cd±0.5

26.8bc±1.0

26.7cd±0.8

CIM-612

28.3±0.6

28.3b±0.6

28.3±0.6

28.3±0.6

25.0d±0.6

25.0e±0.6

25.0d±0.6

25.0e±0.6

LSD0.05

NS

0.5

NS

NS

1.1

0.9

1.3

1.0

Micronaire

Uniformity ratio

DNH-105

4.3c±0.1

4.4b±0.1

4.2c±0.1

4.3d±0.1

80.0a±0.1

79.8a±0.2

80.7a±0.2

80.2a±0.1

CIM-573(std)

4.4c±0.1

4.5b±0.2

4.4b±0.1

4.4cd±0.1

79.0ab±0.2

79.1b±0.2

79.4ab±0.2

79.2b±0.1

CRIS-342

4.5bc±0.1

4.6b±0.1

4.5b±0.1

4.5bc±0.1

77.9bc±0.2

77.8c±0.1

77.1d±0.1

77.6cd±0.2

Gomal-93

4.4c±0.1

4.5b±0.1

4.5b±0.1

4.4cd±0.1

79.2ab±1.1

78.1c±0.5

78.7bc±0.5

78.7b±0.2

NIAB-112

4.7ab±0.3

4.6b±0.2

4.6ab±0.2

4.6ab±0.2

78.8abc±0.6

77.8c±0.0

77.8cd±0.0

78.1c±0.2

CIM-612

4.8a±0.1

4.8a±0.1

4.8a±0.2

4.8a±0.1

77.5c±0.1

77.5c±0.1

76.5d±0.1

77.1d±0.1

LSD0.05

0.2

0.2

0.2

0.2

1.5

0.7

1.4

0.5

Note: Means followed by common letters or no letters do not differ significantly at P≤ 0.05.

higher yield as reported by other researchers (Copur, 2006; Hofs et al., 2006).

Ginning out turn (%)

Ginning out turn (GOT) was different significantly for various genotypes in Y1, Y2, Y3 and mean over years (Table 2). The strain DNH-105, CIM-573(std) and Gomal-93 gave higher GOT than CRIS-342, NIAB-112 and CIM-612 (Table 3). The variation in GOT among different genotypes can be due to environmental or genetic factors/ hetrosis as reported by other researchers (Wang et al., 2004; Arshad et al., 2003). The results revealed that strain DNH-105 produced optimum GOT under agro-climatic conditions of D. I. Khan indicating its suitability to the study region.

Fibre length (mm)

There were significant variations among genotypes regarding fibre length (mm) in Y2, however, no variations occurred in Y1, Y3, and mean over years (Table 2). Data in Y2 revealed that DNH-105, CIM-573, and NIAB-112 gave higher fibre length compared to the rest of the genotypes (Table 4). Year to year variation may be ascribed to changes in environmental conditions for instance precipitation and temperature. However, variation in fibre length within a year among the varieties might be due to varietal character. Earlier studies showed that fibre length varied widely with genotype and environmental conditions as reported by Ashokkumar and Ravikesavan (2011).

Fibre strength (g tex-1)

Data regarding fibre strength is significantly different for different varieties (Table 2). The strongest fibres were obtained from DNH-105 being closely followed by CIM-573 (std) (Table 4). Other varieties showed weaker fibres compared to DNH-105 and CIM-573 (std). Research indicated that fibre strength in the range of 22-24 g tex-1 as medium class, 25 - 27 g tex-1 as strong class and 28 - 35 g tex-1 as very strong class (Basbağ and Temiz, 2004). According to the criteria reported by Basbağ and Temiz (2004), fibre strength of DNH-105 comes in very strong class.

Micronaire value (µg inch–1)

Micronaire value indicates fibre fineness which is an important parameter from industrial point of view. It is evident from analysis of variance that there were significant differences among various varieties regarding micronaire value (Table 2). Mean values revealed that micronire value was higher for CIM-612 followed by NIAB-112 in individual years and mean over years representing lower fiber fineness (Table 4). Lower micronaire values were recorded for DNH-105, CIM-573 (std) and Gomal-93 in all years of study. However, overall mean revealed higher fineness of fiber in DNH-105. Copur (2006) communicated similar findings by reporting significant variations among cultivars with respect to fibre fineness.

Uniformity (%)

Significant differences were observed for uniformity (%) among various genotypes (Table 2). Mean values revealed that the highest uniformity (80.17%) was observed in DNH-105 while CIM-612 had the lowest uniformity of 77.13% (Table 4). Fibre uniformity ratio (%) was consistently higher for DNH-105 compared to all other genotypes in all the study years. Our results are analogous to that of Lale et al. (2013) who reported significant differences among genotypes regarding fiber uniformity.

Conclusions

The DNH-105 strain comparatively performed better than the genotypes CIM-573, CRIS-342, Gomal-93, NIAB-112 and CIM-612 regarding yield and fibre quality under agro-climatic conditions of Dera Ismail Khan-Pakistan. Therefore, it is recommended for general cultivation in the region.

References

  • Ahmed, A.U.H., R. Ali, S.I. Zamir and N. Mehmood. 2009. Growth, yield and quality performance of cotton cultivar BH-160 (Gossypium hirsutum L.). J. Anim. Plant Sci. 19(4): 189-192.
  • Anonymous. 1997. Preservation and utilization of germplasm in cotton. Southern Coop. Series, Bulletin No. 386.
  • Anwar, A.M., M.I. Gill, D. Muhammad and M.N. Afzal. 2002. Evaluation of cotton varieties at different doses of nitrogen fertilizer. The Pak. Cottons. 46(1-4): 35-41
  • Arshad, M., M. Afzal, M.I. Khan and R. Mahmood. 2003. Performances of newly developed cotton strains for economic and fibre traits in national coordinated varietal trials. Pak. J. Sci. & Ind. Res. 46(5): 373-375.
  • Ashokkumar, K. and R. Ravikesavan. 2011. Morphological diversity and per se performance in upland cotton (Gossypium hirsutum L.). J. Agric. Sci. 3(2): 107-113. http://dx.doi.org/10.5539/jas.v3n2p107
  • Basbag, S and M.G. Temiz. 2004. Determinations of some agronomical and technological properties on cotton having different colors fiber. J. Agron. 3(4): 301-304. http://dx.doi.org/10.3923/ja.2004.301.304
  • Bremner, J.M. and C.S. Mulvaney. 1982. Nitrogen-total. In: Page A L, Miller R H, Keeney D R, eds., Methods of Soil Analysis. Part II. Chemical and Microbiological Properties. 2nd ed. American Society of Agronomy, Madison, WI, USA. pp. 595-682
  • Copur, O. 2006. Determination of yield and yield components of some cotton cultivars in semi-arid conditions. Pak. J. Biol. Sci. 9(14): 2572-2578. http://dx.doi.org/10.3923/pjbs.2006.2572.2578
  • Ehsan, F., A. Ali, M.A. Nadeem, M. Tahir and A. Majeed. 2008. Comparative Yield Performance of New Cultivars of Cotton (Gossypium hirsutum L.). Pak. J. life Soc. Sci. 6(1): 1-3.
  • Hanif, C.M., S.W. Hassan, S.S. Mehdi, K. Iqbal and F. Hayat. 2005. Performance of candidate cotton genotypes in respect of yield and yield components. Indus Cottons 2(2):151-154.
  • Hofs, J.L., B. Hau and D. Marais. 2006. Boll distribution patterns in Bt and non-Bt cotton cultivars: I. Study on commercial irrigated farming systems in South Africa. Field Crop Res. 98(2 & 3): 203-209.
  • Huque, H. 1994. “Insect pests of fibre crops”, In: A.A. Hashmi (Ed.), Insect Pest Management, Cereal and Cash Crops. Vol. 1, Pakistan Agricultural Research Council, Islamabad, pp. 193-260.
  • Lale, E.F.E., F. killi and A.S. Mustafayev. 2013. An evaluation of some mutant cotton (Gossypium hirsutum L.) varieties from Azerbaijan in Southeast Anatolian region of Turkey. African J. Biotech. 12(33): 5117-5130.
  • Moser, H.S., M. Closkey, J.C. Silvertooth, P. Dugger. 2000. Performance of transgenic cotton varieties in Arizona, Proceedings of Beltwide Cotton Conferences, San Antontio, USA, 1: 497-499.
  • Muhammad, J. B. 2001. Stability and adaptability analysis of some quantitative triats in upland cotton varieties. Pak. J. Sci. & Ind. Res. 44(2): 105-108.
  • Nelson, D. W. and L. E. Sommers. 1982. Total carbon, organic carbon, and organic matter. In: Page A L, Miller R H, Keeney D R, eds., Methods of Soil Analysis, Part 2. Agronomy No. 9. Madison, Wisconsin, USA. pp. 539-579.
  • PCCC. 2013. Pakistan Central Cotton Committee, Ministry of Commerce & Textile Industry, Government of Pakistan.
  • Razaq, M., M. Aslam, S.A. Shad, M.N. Aslam and N.A. Saeed. 2004. Evaluation of some new promising cotton strains against bollworm complex. J. Res. Sci. 15(3): 313-318.
  • Roach, S.H. and T.W. Culp. 1984. An evaluation of three early maturing cotton cultivars for production potential and insect damage in reduced-and conventional-tillage systems. J. Agric. Entomol. 1(3): 249-255.
  • Satpute, U.S., D.N. Sarnaik and P.D. Bhalerao, 1988. Assessment of avoidable field losses in cotton yield due to sucking pests and bollworms. Indian J. Plant Protect. 16(1): 37-39.
  • Soil Survey Staff. 2009. Keys to soil of NWFP, FATA and Northern areas. Lahore: National Institute of Research in Soils and Geomatics, p. 76.
  • Soltanpour P.N. 1985. Use of ammonium bicarbonate-DTPA soil test to evaluate elemental availability and toxicity. Communication in Soil Science and Plant Analysis. 16: 322-338. http://dx.doi.org/10.1080/00103628509367607
  • Steel, R.G.D. and J.H. Torrie. 1980. Principles and Procedures of Statistics. McGraw Hill Book Co., New York, USA.
  • Wang, C., A. Isoda and P. Wang. 2004. Growth and yield performance of some cotton cultivars in Xinjiang, China, an arid area with short growing period. J. Agron. Crop Sci. 190 (3): 177-183. http://dx.doi.org/10.1111/j.1439-037X.2004.00090.x

To share on other social networks, click on any share button. What are these?

Sarhad Journal of Agriculture

December

Pakistan J. Zool., Vol. 56, Iss. 6, pp. 2501-3000

Featuring

Click here for more

Subscribe Today

Receive free updates on new articles, opportunities and benefits


Subscribe Unsubscribe