Evaluating the Response of Rainfed-Chickpea to Population Density in Iran, Using Simulation
The response of growth and yield of rainfed-chickpea
to population density should be evaluated based on long-term
experiments to include the climate variability. This is achievable just
by simulation. In this simulation study, this evaluation was done by
running the CYRUS model for long-term daily weather data of five
locations in Iran. The tested population densities were 7 to 59 (with
interval of 2) stands per square meter. Various functions, including
quadratic, segmented, beta, broken linear, and dent-like functions,
were tested. Considering root mean square of deviations and linear
regression statistics [intercept (a), slope (b), and correlation
coefficient (r)] for predicted versus observed variables, the quadratic
and broken linear functions appeared to be appropriate for describing
the changes in biomass and grain yield, and in harvest index,
respectively. Results indicated that in all locations, grain yield tends
to show increasing trend with crowding the population, but
subsequently decreases. This was also true for biomass in five
locations. The harvest index appeared to have plateau state across
low population densities, but decreasing trend with more increasing
density. The turning point (optimum population density) for grain
yield was 30.68 stands per square meter in Isfahan, 30.54 in Shiraz,
31.47 in Kermanshah, 34.85 in Tabriz, and 32.00 in Mashhad. The
optimum population density for biomass ranged from 24.6 (in
Tabriz) to 35.3 stands per square meter (Mashhad). For harvest index
it varied between 35.87 and 40.12 stands per square meter.
[1] Amir, J., Sinclair, T.R. 1991. A model of water limitation on spring
wheat growth and yield. Field Crops Res. 29, 59-69.
[2] Barzegar, A.B., Soltani, A. 2007. Effect of future climate change on
yield of rainfed-chickpea in northwest of Iran (Text in Persian, abstract
in English). Proceedings of 2nd national symposium of organic farming,
16-17 Oct, University of Agricultural sciences and Natural Resources,
Gorgan, Iran.
[3] Clapp, C.E., Allmaras, R.R., Layese, M.F., Linden, D.R., Dowdy, R.H.
2000. Soil organic carbon and 13-C abundance as related to tillage, crop
residue, and nitrogen fertilizer under continuous corn management in
Minnesota. Soil Tillage Res. 55, 127-142.
[4] Dore, M.H.I., Lamarche, J.F. 2005. Dating climate change: evidence
from time series data on precipitation. Brock University mimeo.
[5] Gholipoor, M., Soltani, A. 2005. Effect of past climate change on runoff
in Gorgan. (Text in Persian). Proceedings of 5th Iranian Hydrolic
Conference, Nov. 8-10, Shahid Bahonar University of Kerman, Kerman,
Iran.
[6] Gholipoor, M., Soltani, A. 2006. Comparing relative effects of
temperature and photoperiod on development rate of chickpea, using
simulation. (Abstract in persian). Proceedings of 9th Iranian Crop
Science Congress, Aug. 27-29, Aboureyhan Campus- University of
Tehran, Tehran, Iran.
[7] Gholipoor, M., Soltani, A., Sharafi, S. 2006. Determining optimum
sowing date for dormant seeding of chickpea in Kermanshah using
simulation. (Abstract in persian). Proceedings of 9th Iranian Crop
Science Congress, Aug. 27-29, Aboureyhan Campus- University of
Tehran, Iran.
[8] Gholipoor, M. 2007. Potential effects of individual versus simultaneous
climate change factors on growth and water use in chickpea.
International J. Plant Production 1, 189-204.
[9] Gholipoor, M. 2008. Comparative evaluating the climate-related runoff
production in slopped farms of Iran, using simulation. Asian J. Agric.
Res. 2, 45-55.
[10] Haylock M, Nicholls M. 2000. Trends in extreme rainfall indices for an
updated high quality data set for Australia, 1910- 1998. Int. J. Climatol.
20, 1533-1541.
[11] Hulme M. 1996. Recent climatic change in the world-s drylands.
Geophys Res. Lett. 23, 61-64.
[12] Knisel, W.G. 1980. CREAMS: A filed-scal model for chemicals, runoff
and erosion from agricultural management systems. Conservation
Research Report 26, USDA, US. Gov. Print. Office, Washington, DC.
[13] Kumar, K., Goh, K.M. 2000. Crop residues and management practices:
Effects on soil quality, soil nitrogen dynamics, crop yield and nitrogen
recovery. Adv. Agron. 68, 197-319.
[14] Manton, M.J., Della-Marta, P.M., Haylock, M.R., Hennessy, K.J.,
Nicholls, N., Chambers, L.E., et al. 2001. Trends in extreme daily
rainfall and temperature in Southeast Asia and the South Pacific: 1961-
1998. Int. J. Climatol. 21, 269-284.
[15] Martens, D.A. 2000. Plant residue biochemistry regulates soil carbon
cycling and carbon sequestration. Soil Biol. Biochem. 32, 361-369.
[16] Mwale, D., Gan, T.Y., Shen, S.S.P. 2004. A new analysis on variability
and predictability of seasonal rainfall of central southern Africa. Int. J.
Climatol. RMS 24, 1509-1530.
[17] Power, J.F., Koerner, P.T., Doran, J.W., Wilhelm, W.W. 1998. Residual
effects of crop residues on grain production and selected soil properties.
Soil Sci. Soc. Am. J. 62, 1393-1397.
[18] Rahimi-Karizaki, A., Soltani, A. 2007. Determining optimum phenology
of chickpea for now and future. Proceedings of 2nd national symposium
of organic farming, 16-17 Oct, University of Agricultural sciences and
Natural Resources, Gorgan, Iran.
[19] Salinger, M.J., Allan, R.J., Bindoff, N., Hannah, J., Lavery, B., Lin, Z.,
et al. 1996. Observed variability and change in climate and sea level in
Australia, New Zealand and the South Pacific. In: Bouma WJ, Pearman
GI, Manning MR, editors. Greenhouse: Coping with Climate Change.
Melbourne, Australia Commonwealth Scientific and Industrial Research
Organisation (CSIRO). p. 100-126.
[20] Scho¨nwiese, C.D., Rapp, J. 1997. Climate trend atlas of Europe based
on observations, 1891-1990. Dordrecht, Netherlands Kluwer Academic
Publishers. p. 228.
[21] Sinclair, T.R., 1994. Limits to crop yield. In: Boote, K.J., Bennet, J.M.,
Sinclair, T.R., Paulsen, G.N. (Eds.), Physiology and Determination of
Crop Yield. ASA, CSSA, and SSSA, Madison, WI, pp. 509-532.
[22] Soltani, A., Ghassemi-Golezani, K., Khooie, F.R., Moghaddam, M.
1999. A simple model for chickpea growth and yield. Field Crops Res.
62, 213-224.
[23] Soltani, A., Khooie, F.R., Ghassemi-Golezani, K., Moghaddam, M.
2000. Thresholds for chickpea leaf expansion and transpiration response
to soil water deficit. Field Crops Res. 68, 205-210.
[24] Soltani, A., Torabi, B., Zeinali, E., Sarparast, R. 2004a. Response of
chickpea to photoperiod as a qualitative long-day plant. Asian J. Plant
Sci. 3, 705-708.
[25] Soltani, A., Galeshi, S., Attarbashi, M.R., Taheri, A.H. 2004b.
Comparison of two methods for estimating parameters of harvest index
increase during seed growth. Field Crops Res. 89, 369-378.
[26] Soltani, A., Torabi, B., Zarei, H. 2005. Modeling crop yield using a
modified harvest index-based approach: Application in chickpea. Field
Crops Res. 91, 273-285.
[27] Soltani, A., Gholipoor, M. 2006. Simulating the climate change effects
on growth and water use in chickpea (Text in Persian; Abstract in
English). J. Agric. Sci. Natural Resources 2, 123-145.
[28] Soltani, A., Hammer, G.L., Torabi, B., Robertson, M.J., Zeinali, E.
2006a. Modeling chickpea growth and development: Phenological
development. Field Crops Res. 99, 1-13.
[29] Soltani, A., Robertson, M.J., Manschadi, A.M. 2006b. Modeling
chickpea growth and development: Nitrogen accumulation and use.
Field Crops Res. 99, 24-34.
[30] Soltani, A., Robertson, M.J., Mohammad-Nejad, Y., Rahemi-Karizaki,
A. 2006c. Modeling chickpea growth and development: Leaf production
and senescence. Field Crops Res. 99, 14-23.
[31] Soltani, A., Robertson, M.J., Torabi, B., Yousefi-Daz, M., Sarparast, R.
2006d. Modelling seedling emergence in chickpea as influenced by
temperature and sowing depth. Agric. For. Meteorol. 138, 156-167.
[32] Soltani, A., Torabi, B. 2007. Evaluating yield of chickpea and its
stability in dormant seeding (Text in Persian, Abstract in English).
Proceedings of 2nd national symposium of organic farming, 16-17 Oct,
University of Agricultural sciences and Natural Resources, Gorgan, Iran.
[33] Soltani, A., Gholipoor, M., Ghassemi-Golezani, K. 2007. Analysis of
temperature and CO2 effects on radiation use efficiency in chickpea
(Cicer arietinum L.). J. Plant Sci. 2, 89-95.
[34] Soltani, E., and Soltani, E. 2008. Climate change of Khorasan, north-east
of Iran, during 1950-2004. Res. J. Environ. Sci. 2, 316-322.
[35] Tanner, C.B., Sinclair, T.R. 1983. Efficient water use in crop production:
Research or re-search? In: Taylor, H.M., Jordan, W.R., Sinclair, T.R.
(Eds.), Limitations to efficient water use in crop production. ASA,
CSSA, and SSSA, Madison, WI, pp. 1-27.
[36] Zhai, P.M., Sun, A., Ren, F.M., Liu, X., Gao, B., Zhang, Q. 1999.
Changes of climate extremes in China. Clim Change 42, 203-218.
[1] Amir, J., Sinclair, T.R. 1991. A model of water limitation on spring
wheat growth and yield. Field Crops Res. 29, 59-69.
[2] Barzegar, A.B., Soltani, A. 2007. Effect of future climate change on
yield of rainfed-chickpea in northwest of Iran (Text in Persian, abstract
in English). Proceedings of 2nd national symposium of organic farming,
16-17 Oct, University of Agricultural sciences and Natural Resources,
Gorgan, Iran.
[3] Clapp, C.E., Allmaras, R.R., Layese, M.F., Linden, D.R., Dowdy, R.H.
2000. Soil organic carbon and 13-C abundance as related to tillage, crop
residue, and nitrogen fertilizer under continuous corn management in
Minnesota. Soil Tillage Res. 55, 127-142.
[4] Dore, M.H.I., Lamarche, J.F. 2005. Dating climate change: evidence
from time series data on precipitation. Brock University mimeo.
[5] Gholipoor, M., Soltani, A. 2005. Effect of past climate change on runoff
in Gorgan. (Text in Persian). Proceedings of 5th Iranian Hydrolic
Conference, Nov. 8-10, Shahid Bahonar University of Kerman, Kerman,
Iran.
[6] Gholipoor, M., Soltani, A. 2006. Comparing relative effects of
temperature and photoperiod on development rate of chickpea, using
simulation. (Abstract in persian). Proceedings of 9th Iranian Crop
Science Congress, Aug. 27-29, Aboureyhan Campus- University of
Tehran, Tehran, Iran.
[7] Gholipoor, M., Soltani, A., Sharafi, S. 2006. Determining optimum
sowing date for dormant seeding of chickpea in Kermanshah using
simulation. (Abstract in persian). Proceedings of 9th Iranian Crop
Science Congress, Aug. 27-29, Aboureyhan Campus- University of
Tehran, Iran.
[8] Gholipoor, M. 2007. Potential effects of individual versus simultaneous
climate change factors on growth and water use in chickpea.
International J. Plant Production 1, 189-204.
[9] Gholipoor, M. 2008. Comparative evaluating the climate-related runoff
production in slopped farms of Iran, using simulation. Asian J. Agric.
Res. 2, 45-55.
[10] Haylock M, Nicholls M. 2000. Trends in extreme rainfall indices for an
updated high quality data set for Australia, 1910- 1998. Int. J. Climatol.
20, 1533-1541.
[11] Hulme M. 1996. Recent climatic change in the world-s drylands.
Geophys Res. Lett. 23, 61-64.
[12] Knisel, W.G. 1980. CREAMS: A filed-scal model for chemicals, runoff
and erosion from agricultural management systems. Conservation
Research Report 26, USDA, US. Gov. Print. Office, Washington, DC.
[13] Kumar, K., Goh, K.M. 2000. Crop residues and management practices:
Effects on soil quality, soil nitrogen dynamics, crop yield and nitrogen
recovery. Adv. Agron. 68, 197-319.
[14] Manton, M.J., Della-Marta, P.M., Haylock, M.R., Hennessy, K.J.,
Nicholls, N., Chambers, L.E., et al. 2001. Trends in extreme daily
rainfall and temperature in Southeast Asia and the South Pacific: 1961-
1998. Int. J. Climatol. 21, 269-284.
[15] Martens, D.A. 2000. Plant residue biochemistry regulates soil carbon
cycling and carbon sequestration. Soil Biol. Biochem. 32, 361-369.
[16] Mwale, D., Gan, T.Y., Shen, S.S.P. 2004. A new analysis on variability
and predictability of seasonal rainfall of central southern Africa. Int. J.
Climatol. RMS 24, 1509-1530.
[17] Power, J.F., Koerner, P.T., Doran, J.W., Wilhelm, W.W. 1998. Residual
effects of crop residues on grain production and selected soil properties.
Soil Sci. Soc. Am. J. 62, 1393-1397.
[18] Rahimi-Karizaki, A., Soltani, A. 2007. Determining optimum phenology
of chickpea for now and future. Proceedings of 2nd national symposium
of organic farming, 16-17 Oct, University of Agricultural sciences and
Natural Resources, Gorgan, Iran.
[19] Salinger, M.J., Allan, R.J., Bindoff, N., Hannah, J., Lavery, B., Lin, Z.,
et al. 1996. Observed variability and change in climate and sea level in
Australia, New Zealand and the South Pacific. In: Bouma WJ, Pearman
GI, Manning MR, editors. Greenhouse: Coping with Climate Change.
Melbourne, Australia Commonwealth Scientific and Industrial Research
Organisation (CSIRO). p. 100-126.
[20] Scho¨nwiese, C.D., Rapp, J. 1997. Climate trend atlas of Europe based
on observations, 1891-1990. Dordrecht, Netherlands Kluwer Academic
Publishers. p. 228.
[21] Sinclair, T.R., 1994. Limits to crop yield. In: Boote, K.J., Bennet, J.M.,
Sinclair, T.R., Paulsen, G.N. (Eds.), Physiology and Determination of
Crop Yield. ASA, CSSA, and SSSA, Madison, WI, pp. 509-532.
[22] Soltani, A., Ghassemi-Golezani, K., Khooie, F.R., Moghaddam, M.
1999. A simple model for chickpea growth and yield. Field Crops Res.
62, 213-224.
[23] Soltani, A., Khooie, F.R., Ghassemi-Golezani, K., Moghaddam, M.
2000. Thresholds for chickpea leaf expansion and transpiration response
to soil water deficit. Field Crops Res. 68, 205-210.
[24] Soltani, A., Torabi, B., Zeinali, E., Sarparast, R. 2004a. Response of
chickpea to photoperiod as a qualitative long-day plant. Asian J. Plant
Sci. 3, 705-708.
[25] Soltani, A., Galeshi, S., Attarbashi, M.R., Taheri, A.H. 2004b.
Comparison of two methods for estimating parameters of harvest index
increase during seed growth. Field Crops Res. 89, 369-378.
[26] Soltani, A., Torabi, B., Zarei, H. 2005. Modeling crop yield using a
modified harvest index-based approach: Application in chickpea. Field
Crops Res. 91, 273-285.
[27] Soltani, A., Gholipoor, M. 2006. Simulating the climate change effects
on growth and water use in chickpea (Text in Persian; Abstract in
English). J. Agric. Sci. Natural Resources 2, 123-145.
[28] Soltani, A., Hammer, G.L., Torabi, B., Robertson, M.J., Zeinali, E.
2006a. Modeling chickpea growth and development: Phenological
development. Field Crops Res. 99, 1-13.
[29] Soltani, A., Robertson, M.J., Manschadi, A.M. 2006b. Modeling
chickpea growth and development: Nitrogen accumulation and use.
Field Crops Res. 99, 24-34.
[30] Soltani, A., Robertson, M.J., Mohammad-Nejad, Y., Rahemi-Karizaki,
A. 2006c. Modeling chickpea growth and development: Leaf production
and senescence. Field Crops Res. 99, 14-23.
[31] Soltani, A., Robertson, M.J., Torabi, B., Yousefi-Daz, M., Sarparast, R.
2006d. Modelling seedling emergence in chickpea as influenced by
temperature and sowing depth. Agric. For. Meteorol. 138, 156-167.
[32] Soltani, A., Torabi, B. 2007. Evaluating yield of chickpea and its
stability in dormant seeding (Text in Persian, Abstract in English).
Proceedings of 2nd national symposium of organic farming, 16-17 Oct,
University of Agricultural sciences and Natural Resources, Gorgan, Iran.
[33] Soltani, A., Gholipoor, M., Ghassemi-Golezani, K. 2007. Analysis of
temperature and CO2 effects on radiation use efficiency in chickpea
(Cicer arietinum L.). J. Plant Sci. 2, 89-95.
[34] Soltani, E., and Soltani, E. 2008. Climate change of Khorasan, north-east
of Iran, during 1950-2004. Res. J. Environ. Sci. 2, 316-322.
[35] Tanner, C.B., Sinclair, T.R. 1983. Efficient water use in crop production:
Research or re-search? In: Taylor, H.M., Jordan, W.R., Sinclair, T.R.
(Eds.), Limitations to efficient water use in crop production. ASA,
CSSA, and SSSA, Madison, WI, pp. 1-27.
[36] Zhai, P.M., Sun, A., Ren, F.M., Liu, X., Gao, B., Zhang, Q. 1999.
Changes of climate extremes in China. Clim Change 42, 203-218.
@article{"International Journal of Biological, Life and Agricultural Sciences:57059", author = "Manoochehr Gholipoor", title = "Evaluating the Response of Rainfed-Chickpea to Population Density in Iran, Using Simulation", abstract = "The response of growth and yield of rainfed-chickpea
to population density should be evaluated based on long-term
experiments to include the climate variability. This is achievable just
by simulation. In this simulation study, this evaluation was done by
running the CYRUS model for long-term daily weather data of five
locations in Iran. The tested population densities were 7 to 59 (with
interval of 2) stands per square meter. Various functions, including
quadratic, segmented, beta, broken linear, and dent-like functions,
were tested. Considering root mean square of deviations and linear
regression statistics [intercept (a), slope (b), and correlation
coefficient (r)] for predicted versus observed variables, the quadratic
and broken linear functions appeared to be appropriate for describing
the changes in biomass and grain yield, and in harvest index,
respectively. Results indicated that in all locations, grain yield tends
to show increasing trend with crowding the population, but
subsequently decreases. This was also true for biomass in five
locations. The harvest index appeared to have plateau state across
low population densities, but decreasing trend with more increasing
density. The turning point (optimum population density) for grain
yield was 30.68 stands per square meter in Isfahan, 30.54 in Shiraz,
31.47 in Kermanshah, 34.85 in Tabriz, and 32.00 in Mashhad. The
optimum population density for biomass ranged from 24.6 (in
Tabriz) to 35.3 stands per square meter (Mashhad). For harvest index
it varied between 35.87 and 40.12 stands per square meter.", keywords = "Rainfed-chickpea, biomass, harvest index, grain
yield, simulation.", volume = "3", number = "1", pages = "64-8", }
