Research Article | | Peer-Reviewed

Agronomic Evaluation of Improved Chickpea (Cicer arietinum L.) Varieties and Seeding Rates on Vertisols in Abeshige, Central Ethiopia

Received: 12 April 2024     Accepted: 11 June 2024     Published: 30 August 2024
Views:       Downloads:
Abstract

Identification of appropriate varieties and seed rates for different agroecology are important agronomic practices to increase the productivity of chickpea. A field experiment was conducted during the cropping season to evaluate the performance of chickpea varieties and their seed rates on Vertisols of Abeshige district. Four chickpea varieties (Minjar of 100, 125, 150 kg ha-1), Teketay of 120, 150, 180 kg ha-1, Habru of 130, 162.5 195 kg ha-1 and Yelbe of 120, 150, 180 kg ha-1)] and three levels of seed rates were used and combined factorially in randomized complete block design with three replications. Interaction of Chickpea varieties and seed rates were significantly affected number of days to 50% emergency, days to 50% flowering and 90% maturity, plant height, seed yield, number of pods per plant, number of seed per pod, hundred seed weight, harvest index and dry biomass of chickpea. Teketay varieties showed better performance on seed yield, harvest index and number of seed per pod in response to seed rate. Teketay with 180 kg ha-1 was gave better yield and yield components of Chickpea variety. Therefore, Teketay variety with 180 kg ha-1 is recommended to sustain chickpea production in Vertisols of Abeshige areas in central mid-lands of Ethiopia.

Published in American Journal of Plant Biology (Volume 9, Issue 3)
DOI 10.11648/j.ajpb.20240903.13
Page(s) 67-74
Creative Commons

This is an Open Access article, distributed under the terms of the Creative Commons Attribution 4.0 International License (http://creativecommons.org/licenses/by/4.0/), which permits unrestricted use, distribution and reproduction in any medium or format, provided the original work is properly cited.

Copyright

Copyright © The Author(s), 2024. Published by Science Publishing Group

Keywords

Plant Density, Variety, Seed Yield, Chickpea, Correlation Coefficient

1. Introduction
Chickpea (Cicer arietinum L.) is the third most important grain, self-pollinating legume crop, and it is a basic component of the human diet in many countries. The leading chickpea producing countries in the world are India, Australia, Turkey, Myanmar, Ethiopia, Russia, Pakistan, United state of America, Iran and Mexico as FAOSTAT 2015-2020 years average report chickpea production top ten producers Chickpea is a high-value crop that is adapted to deep black soils in the cool semi-arid areas of the tropics, sub-tropics as well as the temperate areas. Ethiopia is ranked third and fifth in the world in terms of yield and production, respectively and accounts for over 90% of chickpea production in sub-Saharan Africa . Importantly, it is among the principal legumes in the highland Vertisols mainly in the maize, tef, wheat, and sorghum-based cropping systems. Chickpea can grow well in elevation range of 1500 and 2700 m. Economic yield, however, is obtained within an altitude range of 1700 –2600 m.
Both (Desi and Kabuli) seed types of chick pea are grown in Ethiopia . Despite the fact that Ethiopia’s agroclimatic conditions are suitable for both types. International markets favor the Kabuli types and offer higher prices for them, this has attracted attention in Ethiopia, and steps have been taken to increase Kabuli production and export .
However, the national yield of check pea was very low as compared to other countries. The main reasons of low yield of Chickpea is improper plant population. Too low and high plant population beyond a certain limit often adversely affects the crop yield. The optimum planting density for chickpea varies with location, the growing conditions, and growth habit of the varieties. The use of a low seeding rate has no significant effects on seed yield due to the capacity of the crop to produce a large number of branches to compensate for low plant population. However, it is essential to use high seed rate in ensuring good plant stand under adverse environmental conditions.
The recommendation for row planting of chickpea indicates a spacing of 30 cm between rows and 10 cm between plants which gives a density of about 333,334 plants ha-1 . A reduced spacing between the plants can be used for varieties that are more erect and hence plant density can be increased. However, the seed rate by broadcast application method appears to be varying depending upon the seed size of the cultivars and growth habit. High seed rates (120-140 kg ha-1) for large seeded and low seed rates (65-75 kg ha-1) for varieties with small seed size are recommended . The reduced plant population will be increasing the performance of individual plant. However, this does not indicate that maximum productivity as per a given area of land because of the inefficient utilization of plant growth factors such as moisture, air, space (land). In short, too dense plant population resulted from reduced inter and intra-row spacing and fewer plant population resulted from increased inter and intra-row spacing will adversely affect productivity per a given area of land. Higher plant population is producing taller, spindly, and more susceptible to lodging .
The national chickpea breeding program in Ethiopia has developed several improved varieties that are being promoted for large-scale adoption by farmers. The improved chickpea varieties differ in important agronomic attributes including seed size and grain yield. Nonetheless, chickpea landraces continue to be widely grown in large parts of Ethiopia . It is often believed that crop landraces display a specific adaptation that may confer yield advantages over modern varieties under abiotic stress situations such as drought . It may, therefore, be important to examine the differential performance of landrace and modern chickpea varieties when subjected to different levels of management regimes such as sowing dates and drainage methods.
Indeed, there will be a need to evaluate the performance of chickpea varieties in varying seed rate to determine the optimum plant density and promising varieties of the crop for maximum yield in the study area. In the study area, no research work has been done on the interaction effects of various agronomic practices such as plant density, identifying adaptive and yield promising of Chickpea varieties. Thus, knowing the seed rate recommendation for chickpea varieties in the studying area could improve the yield and yield components for small holder farmers. The objective was to determine the effect of seed rate and varieties, and their interaction on yield and yield components of chickpea in Abeshige district, Gurage, SNNPR Ethiopia.
2. Material and Methodology
2.1. Description of Experimental Site
The experiment was conducted in 2021 cropping season at SNNPR, Gurage zone Abeshige woreda fite Jeju kebele farmers training center which located at a latitude 8°19'16.06"N North and longitude 37°36'10.40"E East with an altitude of 1580 m.a.s.l (Figure 1).
2.2. Please Take and Put All Graphs and Tables After References
The mean temperature, precipitation, potential of evapotranspiration, water vapor pressure, wind speed, sun fraction and sun hours representing chickpea growing season of 2021 year (Table 1). Climate data were interpolated from New LocClim software of FAO, 2006. New LocClim is especially designed for the interpolation of agroclimatic data, offering the possibility of producing climate maps from user provided station data.
Table 1. Climate Analysis: Temperature, Precipitation, and Solar Data for Each Month in Ethiopia.

Months

T_Mean [°C]

Prec [mm]

PET [mm]

Vapor [hPa]

Wind [km/h]

Sun Fraction [%]

Sun hrs [h]

January

18.2

30

114.7

11.1

4.32

69

8:03

February

19.0

52

113.6

11.3

4.68

70

8:17

March

19.2

128

131.1

12.6

4.68

71

8:34

April

19.2

93

120.2

12.6

4.32

66

8:06

May

19.0

120

122.2

15.0

4.68

61

7:36

June

17.3

134

93.6

14.7

2.88

52

6:31

July

16.3

194

79.0

14.1

2.88

43

5:23

August

16.1

163

82.0

13.9

2.88

44

5:26

September

16.6

127

91.2

13.1

3.6

43

5:13

October

17.2

6

120.3

11.8

5.76

69

8:13

November

17.1

4

116.5

10

5.4

76

8:55

December

17.7

11

114.5

9.3

5.4

72

8:22

T_Mean = mean temperature, Prec = precipitation, PET = potential of evapotranspiration
Figure 1. Location map of study area.
2.3. Experimental Treatments and Procedures
The field experiment comprised four improved chickpea varieties with three levels of seed rates [Minjar of 100, 125, 150 kg ha-1), Teketay of 120, 150, 180 kg ha-1, Habru of 130, 162.5 195 kg ha-1 and Yelbe of 120, 150, 180 kg ha-1] were used. The design of the experiment was randomized complete block design in 3m × 3m factorial arrangements with three replications. Four chickpea varieties were used as Factor A and three seed rates as Factor B. In each season normal cultural practices for raising successful chickpea crop were applied. The recommended dose of fertilizer i. e. 23 Kg N and 100 Kg NPS ha-1 was applied in the form of urea at the time of seed sowing.
Table 2. Description of chickpea varieties used for the study.

S/N

Chick pea varieties

Year of released

Seed color

Type

1

Teketay (ICCV-00104)

2013

Desi

2

Habru (FILP88-42C)

2004

White

Kabuli

3

Yelbey (ICCV-14808)

2006

Yellowish

Kabuli

4

Minjar (ICCV-03107)

2010

Golden

Desi

Source; MoARD, 2018
Data collected
Soil Sampling and Analysis
Pre-planting and post-harvest soil samples (0-20 cm depth) were collected from five spots diagonally and composited. Composited soil sample was prepared following standard procedures and analyzed for soil pH, organic matter, organic carbon, available phosphorus and cation exchange capacity (CEC) . After harvest, soil samples were also collected from each plot and composited treatment wise for the identification of resource change. Particle size distribution determination was following procedure.
Table 3. Soil physiochemical properties of the experimental sites.

Time of sample collection

pH (1:25 H₂O)

Available phosphorus (mg/kg)

Organic carbon (%)

Organic matter (%)

CEC (Cmol (+) kg -1 soil)

Texture (%)

Sand (%)

Clay (%)

Silt (%)

Class

Before planting

6.242

5.436

1.456

2.508

43.960

21.917

44.000

34.083

Clay

After harvesting

6.100

7.120

1.770

3.050

39.830

19.000

46.000

35.000

Clay

2.4. Crop Parameters
All-important phenology, growth, yield and yield parameters were collected following the standard procedure for the crop.
2.4.1. Phenological Data
Number of days to 50% emergence: was recorded as the number of days taken from sowing up to 50% of seedling emergence from each plot.
Number of days to 50% flowering: was recorded when 50% of the total plants flower in the plot and computed from the date of sowing till 50% of the plants attained flowering.
Days to 90% physiological maturity: was recorded as the number of days from the day of planting to the date when 90% of the plants attained physiological maturity in each plot.
2.4.2. Growth Parameters
Plant height: was measured in centimeters from ground level to the plant tip at physiological maturity using ten plants taken randomly from each plot.
Yield and yield components
Number of pods per plant: was computed by dividing total number of pods obtained from ten plants by ten.
Number of seeds per pod: was recorded by dividing total number of seeds from ten plants by total number of pods from ten plants.
Hundred seed weight: was taken by weighing 100 seeds drawn randomly from the grain yield obtained from each experimental plot.
Dry biomass yield: The weight in grams was recorded by weighing the total above ground biomass harvested from the two central middle rows from each experimental plot after air dried and was converted to get biomass yield per hectare.
Seed yield: Seed yield obtained in grams from each experimental plot’s central two rows (2.4 m2) and was converted to get seed yield per hectare.
Harvest index: was calculated as a ratio of total seed yield to total above ground biomass yield harvested from the two middle rows.
2.5. Statistical Analysis
The collected data were subjected to the analysis of variance (ANOVA) using statistical computer software R version 3.5.2 (2018) and R studio Version 1.4.1106 . Mean separation was done using least significance difference (LSD) procedure at 5 % probability level.
3. Result and Discussion
Interaction effect of chickpea varieties with seed rate on crop phenology and growth parameters of Check pea.
The interaction effects of seed rates and varieties were significantly (P<0.05) influenced on number of days to emergency of chick pea (Table 4). The longest (12.27,12.00) number of days to emergency were obtained from 180 and 150 kg ha -1 seed rates with the Yelbe variety and the shortest (9.33 and 9.67) number of days to emergency with 100, 125 and 150 kg ha -1 seed rates of Minjar at Abeshige (Table 4). The data indicate that Yelbe variety considered as relatively late emergency while Habru and Teketay were medium days to emergency and shortest number of days to emergency recorded from minjar.
The interaction effects of seed rates and varieties were significantly (P<0.05) influenced on number of days to flowering chick pea (Table 4). The longest (63.67) number of days to flowering was obtained on 162.5 kg ha-1 seed rates with the Habru variety, and the shortest (45.33 and 9.67) number of days to flowering with 100and 150 kg ha -1 seed rates of Minjar and Teketay variety (47.00) with 120 seed rate at Abeshige (Table 4). Similarly on lentil Varieties were significantly varied in days to 50% flowering and 95% maturity, number of nodules, plant height and biological yields .
The interaction effects of seed rate and varieties were significantly (P<0.05) influenced on number of days to 90 % maturity of chick pea (Table 4). The longest (111) number of days to maturity were obtained on 180 kg ha-1 seed rates with the Yelbe variety, and the shortest (9.33 and 9.67) number of days to 90 % maturity of with 100, 125 and 150 kg ha -1 of seed rates from Minjar at Abeshge (Table 4). The data indicate that Yelbe variety considered as relatively late mature while habru and teketay were medium days to mature and early mature recorded on minjar from three four varieties at the study area.
The interaction effects of seed rate and varieties were significantly (P<0.05) influenced on plant height of chick pea (Table 4). The tallest (47cm) plant height was obtained from 130 kg ha-1 seed rates with the Habru variety, and the shortest (34.60cm) plant height with 125 kg ha -1 seed rates with Minjar at Abeshige (Table 4).
Table 4. Interaction effect of varieties and seed rate on number of days to 50% emergence, number of days to 50% flowering, number of days to 90% physiological maturity and plant height.

Varieties and Seed Rate (kg ha-1)

number of days to 50% emergence

number of days to 50% flowering

number of days to 90% physiological maturity

Plant height (cm)

Yelbe:S_150 kg ha-1

12.00a

56.00ab

109.00ab

41.90abcd

Habru: S_130 kg ha-1

11.33ab

59.67ab

105.67abcd

47.00a

Teketay:S_150 kg ha-1

11.33ab

49.33ab

101.00bcd

43.07abcd

Habru:S_162.5kg ha-1

10.67ab

63.67a

107.33abc

45.33ab

Teketay:S_120 kg ha-1

10.67ab

47.00b

105.33abcd

39.87abcde

Habru:S_195 kg ha -1

10.33ab

53.00ab

105.67abcd

46.33ab

Teketay:S_180 kg ha-1

10.33ab

57.33ab

103.33abcd

39.80abcde

Yelbe:S_180 kg ha-1

12.27a

54.33ab

111.00a

43.53abc

Minjar:S_125 kg ha-1

9.67b

50.67ab

97.33d

34.60e

Yelbe:S_120 kg ha-1

11.50ab

50.75ab

104.75abcd

39.35bcde

Minjar:S_100 kg ha-1

9.33b

45.67b

98.67cd

36.13de

Minjar:S_150 kg ha-1

9.33b

45.33b

100.00cd

36.73cde

LSD (5%)

1.112

7.993

4.456

3.619

CV (%)

11.032

15.549

4.384

9.015

3.1. Interaction Effect of Seed Ratesand Varieties on Seed Yield and Yield Traits of Chickpea Varieties
Seed yield is one of the most important and phenomenal yield components which describe the overall potential of the genotypes and response to plant density and varieties. The seed yield of chickpea was highly significantly (P<0.01) affected by interaction effects of seed rates and varieties on chick pea (Table 5). The highest (1732kg ha-1) grain yield was obtained from 180 kg ha-1 seed rate with the Teketay variety, followed by seed yields (1596 and 1564kg ha-1), respectively from Teketay with 150 and 120 kg ha-1 seed rates, and the lowest (357 kg ha-1) seed yield with 130 kg ha-1 seed rate of Habru variety at Abeshige (Table 5).
The interaction effects of seed rate and varieties were highly significantly (P<0.01) influenced on dry biomass of chick pea (Table 5). The highest (2984 kg ha-1) dry biomass was obtained from 180 kg ha-1 seed rates with the Teketay variety, followed by (2984.074, 2668.889 kg ha-1), respectively dry biomass of Teketay with 120 and 150 kg ha-1 seed rates, and the lowest (1126 kg ha-1) dry biomass with 120 kg ha-1 seed rates with Yelbe variety at Abeshige.
The interaction effects of seed rate and varieties were significantly (P<0.05) influenced on harvest index chick pea (Table 5). The highest (67.5%) harvest index was obtained from 180 kg ha-1 seed rates with the Teketay variety, and the lowest (26.6 and 27.9%) harvest index with 130 and 162.5 kg ha-1 seed rate from Yelbe variety. Similarly reported that harvest index of chickpea variety influenced by seed rate and variety.
The interaction effects of seed rate and varieties were significantly (P<0.05) influenced on hundred seed weight of chick pea (Table 5). The varieties with the highest hundred seed weight (Yelbe with 150 kg ha-1, Habru 162.5 kg ha-1, and Yelbe 120 kg ha-1 seed rates).
The interaction effects of seed rate and varieties were significantly (P<0.05) influenced on number of pods per plant chick pea (Table 5). The highest (87.13) number of pods per plant was obtained from 180 kg ha-1 seed rates with the Yelbe variety, and Habru with 195 kg ha-1 seed rates was (75.57) and the lowest (39.93) number of pods per plant with the three of seed rate of Teketay at Abeshige.
The interaction effects of seed rates and varieties were significantly (P0.05) influenced on number of seed per pod of chick pea (Table 5). The highest (1.234) number of seeds per pod was obtained from 150 kg ha-1 seed rate with the Teketay variety, and Minjar with 195 kg ha-1 seed rate of (1.243) and the lowest (0.91, 0.904 and 0.928) number of seed per pod with the three seed rate of Habru at Abeshige this report were supported by .
Table 5. Interaction effect of plant density and varieties on seed yield and yield traits of chickpea at Abeshige in 2021.

Variety and seed rate

Seed yield (Kg ha-1)

Dry biomass (Kg ha-1)

Harvest index (%)

Hundred seed weight (g)

Number of pods per plant

Number seeds per plant

Teketay: S-180

1731.852a

2984.074a

0.675a

25.33d

39.93b

1.242a

Teketay: S-150

1595.556ab

2668.889ab

0.626ab

26.33cd

46.33b

1.234a

Teketay: S-120

1564.074ab

2984.074a

0.521abcd

25.67d

45.00b

1.043ab

Minjar: S-125

1184.444bc

2142.593bc

0.548abc

18.67e

46.20b

1.164ab

Minjar: S-150

1122.963bcd

2050.37bcde

0.550abc

17.67e

51.73ab

1.178ab

Minjar: S-100

1045.185cde

1800.37cdef

0.573abc

18.00e

66.60ab

1.243a

Yelbe: S-180

711.111cdef

1619.63cdef

0.432cde

30.67ab

87.13a

1.127ab

Habru: S-195

664.444def

2109.26bcd

0.296e

28.33bc

75.57a

0.904b

Yelbe: S-150

603.333ef

1338.89def

0.451bcde

32.00 a

62.00ab

1.197ab

Habru: S-162.5

402.222f

1502.22cdef

0.266e

32.33a

63.73ab

0.91b

Yelbe: S-120

400.000f

1126.11f

0.345de

31.25a

60.85ab

1.123ab

Habru: S-130

357.037f

1285.56ef

0.279e

30.00ab

83.57a

0.928b

LSD (5%)

251.538

403.252

0.097

1.298

13.745

0.147

CV (%)

27.288

21.378

21.625

5.044

23.398

13.823

Means within the same column followed by the same letter non-significantly influenced at 5% probability level.
3.2. The Correlation Between Yield and Yield Attributes of Chickpea
The relationship among yield and yield components of chickpea varieties were presented in Figure 2. Correlation analysis indicated that seed yield was significantly and positively associated with dry biomass and harvest index (0.87) and (0.85) respectively. Days to maturity were significantly and negatively correlated with grain yield (-0.37). The association between number of pods per plant and seed yield were highly significant and negatively correlated. These may imply that chickpea varieties those bear densely pod per plant may not contain two or more seeds per pod whereas some varieties with a smaller number of pods per plant contains two or more seeds per pod that directly and positively related with seed yield. In addition to these hundred seed weight also had negatively correlated with seed yield, kabuli type of chickpea varieties had large seed size low productivity as compared to desi type of chickpea while desi type of chickpea varieties had small seed size and some of them were high yielder.
Figure 2. Pearson correlation () of yield and yield related parameters of chickpea varieties grown in the field at Abeshge in 2021 cropping season.
DTE=Days to Emergence; DTF=Days to 50% Flowering; DTM=Days to 90% Maturity; PH = plant height; NSP = number of seed per pod, NPPP = number of pods per plant, AGBM = above ground biomass, GY = grain yield, HI = harvest index, HSW = hundred seed weight.
4. Conclusions
The chickpea varieties evaluated showed significant variation in some of the yield and yield parameters. There was significance and positive correlation with most growth parameters, yield and yield components. Planting density influenced some parameters of chickpea varieties, The interactions of teketay variety with 180 seed rate was produced higher (1731.852 kg ha -1) seed yield of chick pea. Significantly improved mean harvest index and higher (0.675%) and number of seed per pods (1.242) of chickpea were obtained from teketay with 180 kg ha -1 Thus, chickpea teketay variety with 180 kg ha-1 can tentatively be recommended as best for double cropping maize production in the study area as compared to the other three varieties. Conclusive recommendation could be obtained if the study is repeated at more locations and seasons. Further study over years, locations and different chickpea varieties with different planting densities to suggest valid recommendation for the area.
Abbreviations

MoARD

Ministry of Agriculture and Rural Development

Author Contributions
Takele Zike is the sole author. The author read and approved the final manuscript.
Conflicts of Interest
The author declares no conflict of interest.
References
[1] Abera, Y., Kebede, M., 2013. Assessment on the status of some micronutrients in Vertisols of the central highlands of Ethiopia. Int. Res. J. Agric. Sci. Soil Sci. 3, 169–173.
[2] Admas, S., Haileselassie, T., Tesfaye, K., Shiferaw, E., & Flynn, K. C. (2021, July 14). Evaluation of Ethiopian chickpea (Cicer arietinum L.) genotypes for frost tolerance. ADMAS | Acta Agriculturae Slovenica.
[3] Chala, B., Abera, T., & Nandeshwar, B. (2020, November 23). Influence of Inter and Intra Row Spacing on Yield and Yield Components of Chickpea (Cicer arietinum L.) in Jimma Horro District, Western Ethiopia. International Journal of Plant and Soil Science.
[4] Kassie, M., Shiferaw, B., Asfaw, S., Abate, T., Muricho, G., Ferede, S., Eshete, M., Assfa, K., 2009. Current situation and future outlooks of the chickpea sub-sector in Ethiopia. Icrisat/ Eiar. Nairobi: Debre Zeit.
[5] L. Korbu, T. D. and A. F. (eds)., 2016. Harnessing Chickpea Value Chain for Nutrition Security and Commercialization of Smallholder Agriculture in Africa, in: Lijalem, K., Tebkew, D., Fikre, A. (Eds.), Harnessing Chickpea Value Chain for Nutrition Security and Commercialization of Smallholder Agriculture in Africa. Debre Zeit, pp. 119–134.
[6] Loria, K., Kumari, M., Sood, Y., Vikas, Lalita, Rani, S., & Himangini. (n.d.). 2022. Effect of Seed Rate and Seed Spacings on Yield Attributes of Chickpea
[7] Wood, J. A., Knights, E. J., Chocty, M., 2011. Morphology of chickpea seeds (Cicer arietinum l.): Comparison of desi and kabuli types. Int. J. Plant Sci. 172, 632–643.
[8] FAOSTAT. Food and Agricultural Organization Statistical Database, Rome, Italy; 2020.
[9] RStudio: Integrated development for R. RStudio, Inc., Boston, RStudio team (2018), MA URL
[10] DZARC. Annual Report on Highland Food and Forage Legumes Research Program, DZARC: Ethiopian Agricultural Research Organization; 2004.
[11] Chapman HD (1965) Cation exchange capacity by ammonium saturation. In: Black CA (ed.) Methods of Soil Analysis. Agronomy part II No 9, American Society of Agronomy, Madison, Wisconsin, USA, pp: 891-901.
[12] Martin J, Rechard H, Waldren P, Stamp DL. Principles of field crop production 4th Ed. Pearson Education, Inc. New Jersey; 2006.
[13] Van Reeuwijk, L. P. (2002). Procedures for Soil Analysis (6th Edition). ISRIC - World Soil Information. Retrieved from ISRIC.
[14] Zike T, Abera T, Hamza I (2017) Response of Improved Lentil (Lens Culinaris Medik) Varieties to Phosphorus Nutrition on Vertisols of West Showa, Central Highlands of Ethiopia. Adv Crop Sci Tech 5: 315.
Cite This Article
  • APA Style

    Zike, T. (2024). Agronomic Evaluation of Improved Chickpea (Cicer arietinum L.) Varieties and Seeding Rates on Vertisols in Abeshige, Central Ethiopia. American Journal of Plant Biology, 9(3), 67-74. https://doi.org/10.11648/j.ajpb.20240903.13

    Copy | Download

    ACS Style

    Zike, T. Agronomic Evaluation of Improved Chickpea (Cicer arietinum L.) Varieties and Seeding Rates on Vertisols in Abeshige, Central Ethiopia. Am. J. Plant Biol. 2024, 9(3), 67-74. doi: 10.11648/j.ajpb.20240903.13

    Copy | Download

    AMA Style

    Zike T. Agronomic Evaluation of Improved Chickpea (Cicer arietinum L.) Varieties and Seeding Rates on Vertisols in Abeshige, Central Ethiopia. Am J Plant Biol. 2024;9(3):67-74. doi: 10.11648/j.ajpb.20240903.13

    Copy | Download

  • @article{10.11648/j.ajpb.20240903.13,
      author = {Takele Zike},
      title = {Agronomic Evaluation of Improved Chickpea (Cicer arietinum L.) Varieties and Seeding Rates on Vertisols in Abeshige, Central Ethiopia
    },
      journal = {American Journal of Plant Biology},
      volume = {9},
      number = {3},
      pages = {67-74},
      doi = {10.11648/j.ajpb.20240903.13},
      url = {https://doi.org/10.11648/j.ajpb.20240903.13},
      eprint = {https://article.sciencepublishinggroup.com/pdf/10.11648.j.ajpb.20240903.13},
      abstract = {Identification of appropriate varieties and seed rates for different agroecology are important agronomic practices to increase the productivity of chickpea. A field experiment was conducted during the cropping season to evaluate the performance of chickpea varieties and their seed rates on Vertisols of Abeshige district. Four chickpea varieties (Minjar of 100, 125, 150 kg ha-1), Teketay of 120, 150, 180 kg ha-1, Habru of 130, 162.5 195 kg ha-1 and Yelbe of 120, 150, 180 kg ha-1)] and three levels of seed rates were used and combined factorially in randomized complete block design with three replications. Interaction of Chickpea varieties and seed rates were significantly affected number of days to 50% emergency, days to 50% flowering and 90% maturity, plant height, seed yield, number of pods per plant, number of seed per pod, hundred seed weight, harvest index and dry biomass of chickpea. Teketay varieties showed better performance on seed yield, harvest index and number of seed per pod in response to seed rate. Teketay with 180 kg ha-1 was gave better yield and yield components of Chickpea variety. Therefore, Teketay variety with 180 kg ha-1 is recommended to sustain chickpea production in Vertisols of Abeshige areas in central mid-lands of Ethiopia.
    },
     year = {2024}
    }
    

    Copy | Download

  • TY  - JOUR
    T1  - Agronomic Evaluation of Improved Chickpea (Cicer arietinum L.) Varieties and Seeding Rates on Vertisols in Abeshige, Central Ethiopia
    
    AU  - Takele Zike
    Y1  - 2024/08/30
    PY  - 2024
    N1  - https://doi.org/10.11648/j.ajpb.20240903.13
    DO  - 10.11648/j.ajpb.20240903.13
    T2  - American Journal of Plant Biology
    JF  - American Journal of Plant Biology
    JO  - American Journal of Plant Biology
    SP  - 67
    EP  - 74
    PB  - Science Publishing Group
    SN  - 2578-8337
    UR  - https://doi.org/10.11648/j.ajpb.20240903.13
    AB  - Identification of appropriate varieties and seed rates for different agroecology are important agronomic practices to increase the productivity of chickpea. A field experiment was conducted during the cropping season to evaluate the performance of chickpea varieties and their seed rates on Vertisols of Abeshige district. Four chickpea varieties (Minjar of 100, 125, 150 kg ha-1), Teketay of 120, 150, 180 kg ha-1, Habru of 130, 162.5 195 kg ha-1 and Yelbe of 120, 150, 180 kg ha-1)] and three levels of seed rates were used and combined factorially in randomized complete block design with three replications. Interaction of Chickpea varieties and seed rates were significantly affected number of days to 50% emergency, days to 50% flowering and 90% maturity, plant height, seed yield, number of pods per plant, number of seed per pod, hundred seed weight, harvest index and dry biomass of chickpea. Teketay varieties showed better performance on seed yield, harvest index and number of seed per pod in response to seed rate. Teketay with 180 kg ha-1 was gave better yield and yield components of Chickpea variety. Therefore, Teketay variety with 180 kg ha-1 is recommended to sustain chickpea production in Vertisols of Abeshige areas in central mid-lands of Ethiopia.
    
    VL  - 9
    IS  - 3
    ER  - 

    Copy | Download

Author Information
  • Abstract
  • Keywords
  • Document Sections

    1. 1. Introduction
    2. 2. Material and Methodology
    3. 3. Result and Discussion
    4. 4. Conclusions
    Show Full Outline
  • Abbreviations
  • Author Contributions
  • Conflicts of Interest
  • References
  • Cite This Article
  • Author Information