Browsing by Author "Zhou, Yi"

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Chickpea variety evaluation and intercropping for disease management and yield
(Montana State University - Bozeman, College of Agriculture, 2022) Zhou, Yi; Chairperson, Graduate Committee: Chengci Chen; This is a manuscript style paper that includes co-authored chapters.
Chickpea (Cicer arietinum L.) is an important food grain legume, but production is constrained by the soilborne pathogen complex, Ascochyta rabiei, and the development of fungicide resistance. Cultivar resistance is one of the most efficient strategies in disease management. However, chickpea cultivars with resistance to soilborne pathogens or complete resistance to A. rabiei have not been developed. Intercropping chickpea-flax has the potential for Ascochyta blight management. To minimize the impact of soilborne disease and Ascochyta blight on chickpea production, refining of integrated pest management practices is essential. To evaluate the effect of cultivar selection in combination with seed treatment on soilborne disease control, twenty-five cultivars/lines were planted with or without fluxapyroxad, pyraclostrobin, and metalaxyl under field conditions. The area under disease progress curve (AUDPC), seed yield, and protein content were assessed. Fusarium solani was isolated and identified in the late season, and the disease severity of root rot was evaluated. The results showed that seed treatment effectively suppressed damping-off and improved chickpea yield but only slightly reduced late-season root rot. The AUDPC of NDC160166 and NDC 160236 was not significantly reduced by seed treatment, which could be a future resource of resistance. To assess the effects of configurations and resistant cultivar on yield and Ascochyta blight management in intercropping chickpea-flax, two chickpea cultivars (CDC Leader and Royal) were planted with flax under six configurations (monocrop chickpea, 70% chickpea-30% flax in mixture, 50% chickpea-50% flax in mixture, 50% chickpea-50% flax in alternate rows, 30% chickpea-70 flax in mixture, monocrop flax). Yield and nutrient content of component crops and Ascochyta blight infection were evaluated. Chickpea yield decreased as flax proportion increased in the mixture. Chickpea yielded higher in the alternate row design than in the mixture at the same seeding rate due to less interspecies competition in the alternate rows. Intercrop increased 2%-23% land productivity. Chickpea-flax intercrop effectively reduced Ascochyta blight under higher disease pressure. The configuration of 50% chickpea and 50% flax in the mixture was more effective in suppressing Ascochyta blight than in the alternate row configuration. Integrated resistant cultivar and intercropping configuration was most effective in disease suppression.
Durum wheat yield and protein influenced by nitrogen management and cropping rotation
(Informa UK Limited, 2022-04) Chen, Chengci; Zhou, Shuang; Afshar, Reza Keshavarz; Franck, William; Zhou, Yi
Nitrogen (N) is the major input for cereal grain production. N management in durum wheat (Triticum turgidum subsp. durum) is critical for optimizing grain yield, protein concentration, and utilization efficiency of nitrogen fertilizer. A two-year study was conducted in the semi-arid region of the US Northern Great Plains (NGP) to investigate nitrogen input levels and application methods under fallow-durum and pea-durum systems. A durum wheat (cv. Joppa) was planted in the field following fallow or field pea with N input levels of 65 and 135 kg ha−1 and four application methods for each N input level. Results showed that water was the major limiting factor determining grain yield and protein concentration. Grain yield was greater but with similar protein concentration following fallow (1958 kg ha−1, 16.7%) than following field pea (1754 kg ha−1, 16.4%). Increasing N input from 65 kg ha−1 to 135 kg ha−1decreased grain yield from 1933 to 1779 kg ha−1 but improved protein concentration from 16.3 to 16.8%, which resulted in a negative nitrogen use efficiency (NUE). Application method of N did not significantly affect yield and protein, but there was a trend of yield increase via split application of N at the lower rate in a wetter year. The drought in 2017 resulted in lower test weight and harvest index (HI). The HI was lower in the135 kg ha−1 N rate than in the 65 kg ha−1 N rate, especially in the dryer year. Excessive N inputs in a water-limited environment may result in ‘haying-off’.
Evaluation of environment and cultivar impact on lentil protein, starch, mineral nutrients, and yield
(Wiley, 2021-12) Chen, Chengci; Etemadi, Fatemeh; Franck, William; Franck, Sooyoung; Abdelhamid, Magdi T.; Ahmadi, Jafar; Mohammed, Yesuf Assen; Lamb, Peggy F.; Miller, John H.; Carr, Patrick M.; McPhee, Kevin; Zhou, Yi; Torabian, Shahram; Qin, Ruijun
Lentil (Lens culinaris Medik.) is an important source of protein, starch, and mineral nutrients in many parts of the world. However, the impact of environment and cultivar on the enrichment of these nutrients is not well understood. Four lentil cultivars (‘Avondale’, ‘CDC Richlea’, ‘CDC Maxim’, and ‘CDC Imvincible’) varying in color, seed size, and maturity were evaluated at five Montana locations with diverse climatic and soil conditions over 3 yr. Significant cultivar, location, and year effects were found for yield, protein, starch, and minerals. Grain protein concentration was the highest at Moccasin (262 g kg−1) and lowest at Richland (246 g kg−1), whereas starch concentration was the highest at Richland (455 g kg−1) and lowest at Moccasin(441gkg−1). Among cultivars, Avondale was the top yielding cultivar (1965 kg ha−1)and adaptable to most of the environments; CDC Imvincible was the top protein producer (265 g kg−1); and CDC Richlea is the leading starch producer (456 g kg−1). Grain protein concentration was negatively correlated with starch. Lentil grains varied in nutrient concentrations across locations, with the north central Montana region producing 10- to 20-times greater selenium concentration than other locations. CDC Maxim had the highest iron (62.1 mg kg−1) and zinc (31.5 mg kg−1) concentrations.Seed protein concentration was positively correlated with phosphorus, sulfur, cop-per, and boron. Seed starch is positively correlated with magnesium and manganese.Results suggest that plant breeding and production site selection could enrich lentil nutrient concentrations to help combat malnutrition in the world.
Intercropping chickpea–flax for yield and disease management
(Wiley, 2023-03) Zhou, Yi; Chen, Chengci; Franck, William L.; Khan, Qasim; Franck, Sooyoung; Crutcher, Frankie K.; McVay, Kent; McPhee, Kevin
Ascochyta blight (caused by Ascochyta rabiei) is a primary concern of chickpea production worldwide. Intercropping chickpea with a non-host crop has the potential to suppress this disease and improve resource use efficiency for enhanced crop yield. This study aimed to evaluate the effects of seeding rate and row configuration of chickpea (Cicer arietinum L.)–flax (Linum usitatissimum L) intercropping on (1) yield and seed quality, (2) disease incidence and severity of Ascochyta blight of chickpea, and (3) land productivity of this intercropping system. Field trials were conducted at the Eastern Agricultural Research Center, Sidney, MT, and the Southern Agricultural Research Center, Huntley, MT, in 2020 and 2021. Chickpea was planted with flax in four intercropping configurations (70% chickpea–30% flax in mixed rows, 50% chickpea–50% flax in alternate rows, 50% chickpea–50% flax in mixed rows, and 30% chickpea–70% flax in mixed rows). Chickpea yield decreased with increased flax proportion in the mixed rows intercrop. Flax displayed higher competitiveness than chickpea, resulting in decreased yield and protein concentration in chickpea but increased yield and protein content in flax. Land equivalent ratio of intercropping was greater than one, showing improved land productivity (2%–23% greater than monocropping). Intercropping reduced Ascochyta blight disease incidence and severity; the 50% chickpea–50% flax and 30% chickpea–70% flax intercropping configurations could reduce the disease severity to 50% (in Huntley) and 67% (in Sidney) of that in the monocropping. These results indicated that seed ratio and planting configurations of chickpea–flax intercropping may be manipulated to increase land use efficiency and reduce Ascochyta blight in chickpea. Canadian Development Center ‘CDC Leader’ yielded greater than Royal in the higher disease pressure environment in Huntley indicated that selection of disease resistant cultivars is important for managing Ascochyta blight in chickpea.
Intercropping chickpea-flax for yield and disease management
(Wiley, 2022-12) Zhou, Yi; Chen, Chengci; Franck, William L.; Khan, Qasim; Franck, Sooyoung; Crutcher, Frankie K.; McVay, Kent; McPhee, Kevin
Ascochyta blight (caused by Ascochyta rabiei) is a primary concern of chickpea production worldwide. Intercropping chickpea with a non-host crop has the potential to suppress this disease and improve resource use efficiency for enhanced crop yield. This study aimed to evaluate the effects of seeding rate and row configuration of chickpea (Cicer arietinum, L.)-flax (Linum usitatissimum, L) intercropping on 1) yield and seed quality, 2) disease incidence and severity of Ascochyta blight of chickpea, and 3) land productivity of this intercropping system. Field trials were conducted at the Eastern Agricultural Research Center (EARC), Sidney, MT, and the Southern Agricultural Research Center (SARC), Huntley, MT, in 2020 and 2021. Chickpea was planted with flax in 4 intercropping configurations (70% chickpea – 30% flax in mixed rows, 50% chickpea – 50% flax in alternate rows, 50% chickpea – 50% flax in mixed rows, and 30% chickpea – 70% flax in mixed rows). Chickpea yield decreased with increased flax proportion in the mixed rows intercrop. Flax displayed higher competitiveness than chickpea, resulting in decreased yield and protein concentration in chickpea but increased yield and protein content in flax. Land equivalent ratio (LER) of intercropping was greater than 1, showing improved land productivity (2% -23% greater than monocropping). Intercropping reduced Ascochyta blight disease incidence and severity; the 50% chickpea – 50% flax and 30% chickpea – 70% flax intercropping configurations could reduce the disease severity to 50% (in Hunley) and 67% (in Sidney) of that in the monocropping. These results indicated that seed ratio and planting configurations of chickpea-flax intercropping may be manipulated to increase land use efficiency and reduce Ascochyta blight in chickpea. CDC Leader yielded greater than Royal in the higher disease pressure environment in Huntley indicated that selection of disease resistant cultivar is important for managing Ascochyta blight on chickpea.