Serviços Personalizados
Journal
Artigo
Indicadores
- Citado por SciELO
- Acessos
Links relacionados
- Similares em SciELO
Compartilhar
Revista mexicana de ciencias agrícolas
versão impressa ISSN 2007-0934
Rev. Mex. Cienc. Agríc vol.11 no.spe24 Texcoco Abr./Mai. 2020 Epub 07-Maio-2021
https://doi.org/10.29312/remexca.v0i24.2353
Articles
Yield of white clover associated with ovillo grass at different grazing frequencies
1Asesor Técnico en Reproducción Animal, Abs Global 406, Gardner Ave. 10, Twin falls ID 83301, EE. UU (joelventur@gmail.com).
2Recursos Genéticos y Productividad-Ganadería- Colegio de Postgraduados. Carretera México-Texcoco km 35.5, Montecillo, Estado de México, México. (edgarhdzmoreno@gmail.com).
3Centro de Desarrollo Tecnológico Tatakin. Carretera Tzucacab Noh-Bec km 4.5, Tzucacab, Yucatán, México. (saomar87@gmail.com).
4Universidad Autónoma Chapingo. San Luis Acatlán-Tlapa km 5.5, San Luis Acatlán, Guerrero. CP. 41603. (claudiawilson@colpos.mx).
5Facultad de Medicina Veterinaria y Zootecnia Núm. 2-Universidad Autónoma de Guerrero. Cuajinicuilapa, Guerrero, México. CP. 41940. (mmaldonado@uagro.mx; rogarcia-05@hotmail.com).
The objective of the study was to evaluate the behavior of white clover associated with ovillo grass at four grazing frequencies. The treatments were fixed frequencies of 28 d in spring-summer and 35 d in autumn-winter and when the grassland intercepted 95 and 100% of intercepted radiation. Treatments were assigned to experimental units according to a randomized block design in divided plots with three replications. The variables evaluated were dry matter yield (DMY), botanical and morphological composition (BMC, %), growth rate (GR), intercepted radiation (IR, %) and height. The frequency of grazing during the winter modified the accumulation of dry matter (3885 kg DM ha-1; p< 0.05). The GR was higher in the grazing frequency at 28 d in spring (70 kg DM ha-1 d-1; p< 0.05). The highest height was reached at 28 d in the summer (26 cm; p< 0.05). Grazing frequency did not affect Grassland yield, except in winter when the best yield was obtained by grazing at 95% IR. The IR and the height of the plant are indicative of the dry matter yield and optimal harvest time.
Keywords: grass; grazing frequency; legume
El objetivo del estudio fue evaluar el comportamiento del trébol blanco (Trifolium repens L.) asociado con pasto ovillo (Dactylis glomerata L.) a cuatro frecuencias de pastoreo. Los tratamientos fueron las frecuencias fijas de 28 d en primavera-verano y 35 d en otoño-invierno y cuando la pradera intercepto 95 y 100% de radiación interceptada. Los tratamientos se asignaron a unidades experimentales de acuerdo con un diseño de bloques al azar en parcelas divididas con tres repeticiones. Las variables evaluadas fueron: rendimiento de materia seca (RMS), composición botánica y morfológica (CBM, %), tasa de crecimiento (TC), radiación interceptada (RI, %) y altura. La frecuencia de pastoreo durante el invierno modifico la acumulación de materia seca (3 885 kg MS ha-1; p< 0.05). La TC fue mayor en la frecuencia de pastoreo a 28 d en primavera (70 kg MS ha-1 d-1; p< 0.05). La mayor altura se alcanzó a 28 d en el verano (26 cm; p< 0.05). La frecuencia de pastoreo no afecto el rendimiento de la pradera, excepto en invierno cuando el mejor rendimiento se obtuvo al pastorear al 95% de RI. La RI y la altura de la planta son indicativos del rendimiento de materia seca y momento óptimo de cosecha.
Palabras clave: frecuencia de pastoreo; gramínea; leguminosa
Introduction
In the temperate zone of Mexico there are animal production systems that base their feeding on pure and associated grasslands (Rojas et al., 2016a). The most used grasses in this area are: ovillo grass or orchard (Dactylis glomerata L.), annual ryegrass or ballico (Lolium multiflorum L.), tall fescue (Festuca arundinacea Schreber), ballico or perennial ryegrass (Lolium perenne L.) which are found as monoculture or associated with legumes such as white clover (Trifolium repens L.), lucerne (Medicago sativa L.) and red clover (Trifolium pratense L.)
These species are sown in approximately 171 520 hectares, which represents 13% of the total surface of this area (Amendola et al., 2005). Some studies conducted in Mexico and other latitudes in the temperate zone world (Black et al., 2009) have reported that grass and legume associations increase biomass yield (Sanderson et al., 2013; Rojas et al., 2016a, forage quality is improved (Lee, 2018) and soil fertility due to the properties and physiology of legumes to fix nitrogen (N) symbiotically (Randazzo et al., 2013; Rojas et al., 2017).
It is necessary to consider a proportion of no more than 40% of white clover when establishing the crop (Rojas et al., 2016b), since competition for water, light and other nutrients can affect the performance of grasses in the grassland. Studies to evaluate the defoliation and use of forages is a complex subject, since the adequate use of a pure or mixed plot.
It requires knowing the growth dynamics of the species present (Velasco et al., 2001), since seasonal and annual biomass production is highly variable due to morphological adaptations and physiological changes experienced by grasses and legumes at a given time (Durand et al., 1999), for example, long periods of drought, low or high light intensities.
Extreme temperatures and availability of nutrients, likewise, the ecosystems of the pastures are changing, since there are them, annual, biennial and perennial, another important characteristic in grasses, are the type of photosynthetic pathway used, since the area pastures cold are usually called C3 and warm areas C4; however, in the face of climate change, its behavior may be variable (Stromberg, 2011; Abhishek et al., 2018).
Several directed studies (Moreno et al., 2015; Rojas et al., 2016a; Maldonado et al., 2017) in the Mexican central highlands, when evaluating different grass and legume associations, have shown that the highest dry matter yields have been achieved in the spring-summer season, however, the results are not always consistent.
Since the seasonal and annual performance of forage plants is a function of climatic and soil conditions. The objective of the present study was to evaluate the effect of defoliation frequency on forage accumulation, yield components and botanical composition of white clover associated with ovillo grass.
Materials and methods
The study was conducted in a white clover grassland associated with ovillo grass from March 2012 to April 2013 in the experimental field of the College of Postgraduates, in Montecillo, Texcoco, State of Mexico, at 19º 29’ north latitude and 98º 53’ west longitude at a height of 2 240 masl. The climate of the place is temperate sub-humid, with an average annual precipitation of 636.5 mm, and a rainy season in summer (from June to October) and an average annual temperature of 15.2 °C (García, 2004). The soil was analyzed in the Vegetable Nutrition Laboratory, SC in 2011 and was identified as sandy loam soil, with pH 8.4 and 3.5% organic matter.
Grassland management and treatment
To know the effect of the grazing frequency on the accumulation of seasonal and annual dry matter, botanical and morphological composition, growth rate of the crop (GR), intercepted radiation (IR) and height of the grassland, three treatments were proposed that consisted grazing every 28 days, 95 and 100% intercepted radiation (IR) during spring and summer, and every 35 days, 95 and 100% intercepted radiation during autumn and winter.
The sowing was carried out broadcasting in February 2009 with a density of pure and viable seed at a density of 6 kg ha-1 of white clover, while for ovillo grass it was 20 kg ha-1, with this proportion a mixture of 40-60 white clover and ovillo grass, respectively. Nine 9 x 7 m plots were used, where the treatments were distributed under a randomized complete block design with three replications.
Before starting the investigation and in the middle of each season in 2012, uniform grazing was carried out, as defoliators, sheep of the Suffolk x Dorset breed were used, until leaving a remaining leaf area of 5 cm above ground level and for a better management was established electric fence in the experimental plots. During the dry season, the grasslands were gravity watered at field capacity every two weeks and were not fertilized.
Climate data
The monthly averages for outdoor temperature (maximum and minimum) and monthly precipitation during the study period were obtained from the Agrometeorological Station of the Postgraduate College, located 100 m from the experimental site (Figure 1). The monthly maximum temperature ranged from 22.1 to 30.2 °C, meanwhile, the minimum temperature was -2.6 to 11 °C.
The highest temperature occurred in spring, with the highest recorded in April being 30.2 °C, the lowest temperature was recorded in winter with -2.6 in December. Accumulated precipitation from March 2012 to April 2013 was 613 mm, of which 75.8% occurred in the months of June, July, August, September and October 2012, accumulating precipitation of 465 mm.
Dry matter yield
After the uniform grazing, three 0.25 m2 squares were cut at a height of 5 cm starting from the soil in each plot and repetition depending on the grazing frequency. The forage harvested in each quadrant was washed and dried in labeled paper bags in a forced air stove at 55 °C for 72 h to estimate the amount of dry matter per hectare.
Botanical and morphological composition
To know the botanical composition of the forage, it was taken from the sample for dry matter yield and separated into white clover and ovillo grass. The morphological components of white clover (leaf, petiole, stolon and flower) and ovillo grass (leaf, stem and spike) were separated. Each component was dried in a labeled paper bag and remained in a forced air oven at 55 °C for 72 h to determine its dry weight.
Growth rate
The growth rate was calculated with the performance data obtained in each cut, in each of the repetitions, with the following formula: GR = R/T.
Where: GR= seasonal average growth rate (kg DM ha-1 d-1); R= seasonal forage yield (kg DM ha-1); T= days elapsed in each cut.
Intercepted radiation
The intercepted radiation was carried out before each grazing using the wooden ruler method described by Rojas et al. (2016b). To do this, five readings were taken in each experimental unit at random, consisting of sliding a wooden ruler 1 m long under the canopy with a south-north orientation. Subsequently, the shaded centimeters were counted, which represented the percentage of radiation intercepted by the plant canopy.
Grassland height
The height of the plant was measured before grazing and 20 samples were taken at random throughout the experimental unit with a graduated ruler 50 cm long and 1 mm precision above the canopy and slid until it touched the first morphological component of the association and the data was recorded (Adams et al., 1977).
Statistical analysis
Treatments were assigned to experimental units according to a randomized block design in divided plots with three replications, where the large plot was the association and the treatments the grazing frequencies. The data obtained by cutoff was organized by station and analyzed with PROC GLM from SAS (SAS Institute, 2009); the averages were compared with the Tukey test (α= 0.05).
Results and discussion
Dry matter yield
Table 1 shows the yield data for white clover associated with ovillo grass. In general, it is observed that the accumulation of dry matter was not modified (p> 0.05) in spring, summer and autumn at different grazing frequencies, however, in winter the highest accumulation of dry matter (p> 0.05), was presented at 95% IR (3 885 kg DM ha-1), which exceeded 1 925 kg DM ha-1 (equivalent to 98%) at the grazing frequency of 100% IR (1 960 kg DM ha-1) and 1 635 kg DM ha-1 (equivalent to 73%) at the frequency of 35 days (2 250 kg DM ha-1).
Season | Grazing frequency | |||||
28-35 (d) | RI (%) | 95% de IR | Interval (d) | 100% de IR | Interval (d) | |
Spring | 5 740 a | 92 | 4 385 a | 27 | 5 667 a | 30 |
Summer | 5 797 a | 93 | 4 658 a | 26 | 5 341 a | 30 |
Autumn | 2 674 b | 92 | 2 915 b | 32 | 3 297 b | 39 |
Winter | 2 250 b | 84 | 3 885 a | 38 | 1 960 c | 56 |
Anual average | 4 115 | 3 960 | 4 066 | |||
SEM | 326 | 198 | 242 | |||
Significance | ** | ** | ** | |||
Annual yield | 16 461 | 15 843 | 16 265 |
Lowercase letter averages between columns represent significant difference (Tukey, 0.05). *= p< 0.05; **= p< 0.01; d= days.
On the other hand, the annual yield was not modified in the different grazing frequencies (p> 0.05). Other researchers (Castro et al., 2012) obtained a yield of 17 275 kg DM ha-1 in mixed grasslands with white clover, ovillo grass and perennial ryegrass, which are similar to what was found in the present investigation, which were 17 296 and 17 100 kg DM ha-1 at the frequency of 28-35 d and 100% IR, respectively. On the other hand, Rojas et al. (2016b) reported annual productions of 17 589 when evaluating different associations of clew, ryegrass and white clover grass, where the highest seasonal values were found in spring-summer, which were 7 292 and 5 072 kg DM ha-1, respectively.
In the present experiment, in a very similar way, the highest seasonal yield averages were presented in spring-summer, which were statistically very similar (p> 0.05) but different from autumn-winter (p< 0.05).
The contribution of white clover and ovillo grass to dry matter yield in kg DM ha-1 per year and seasonally is found in Table 2. In general, white clover contributed approximately 65% of total annual dry matter, although there was no difference significant statistic (p> 0.05) per treatment.
Season | Grazing frequency | SEM | Sig. | Average | ||
28-35 days | 95% de IR | 100% de IR | ||||
White clover (kg DM ha-1 ) | ||||||
Spring | 3 034 a | 2 905 a | 3 816 a | 324 | NS | 3 252 a |
Summer | 2 175 b | 1 745 b | 1 925 b | 180 | NS | 1 948 b |
Autumn | 1 266 c | 1 550 b | 1 527 b | 196 | NS | 1 086 c |
Winter | 1 504 bc | 1 464 b | 1 184 b | 198 | NS | 1 384 c |
Anual average | 1 994 | 1 916 | 2 113 | 162 | NS | |
SEM | 170 | 100 | 176 | 106 | ||
Significance | ** | ** | ** | ** | ||
Annual yield | 7 979 | 7 665 | 8 452 | 805 | NS | |
Ovillo grass (kg DM ha-1 ) | ||||||
Spring | 1 603 a | 757 b | 1 157 b | 218 | NS | 1 172 b |
Summer | 1 770 a | 1 695 a | 2 288 a | 291 | NS | 1 918 a |
Autumn | 644 b | 939 ab | 1 032 bc | 118 | NS | 654 c |
Winter | 287 b | 426 b | 401 c | 57 | NS | 371 d |
Anual average | 1 076 | 954 | 1 219 | 117 | NS | |
SEM | 102 | 162 | 132 | 54 | ||
Significance | ** | ** | ** | ** | ||
Annual yield | 4 304 | 3 816 | 4 879 | 586 | NS |
Means with different capital letters between rows represent significant difference and averages with lower case letters between columns represent significant difference (Tukey, 0.05). Sig.= significance; *= p< 0.05; **= p< 0.01. Int= Interval between grazing, in days. ns= not significant.
During spring the production of white clover was higher (3 252 kg DM ha-1; p<0.05), which exceeded in 199, 135 and 67% the forage produced in autumn (1 086 kg DM ha-1) winter (1 384 kg DM ha-1) and summer (1 984 kg DM ha-1), respectively. On the other hand, ovillo grass produced more forage in the summer (1 918 kg DM ha-1; p< 0.05), which exceeded in 417, 193 and 64% the forage produced in winter (371 kg DM ha-1), autumn (654 kg DM ha-1) and spring (1 172 kg DM ha-1), respectively.
During the spring-summer the climatic conditions were more favorable for the good performance of the grasslands (Figure 1), in addition the elevated temperatures favored a greater light interception, allowing the canopy to reach a higher leaf area index faster than in autumn-winter (Rojas et al., 2016a).
On the other hand, the horizontal arrangement of white clover leaflets helps to reestablish its leaf area more quickly than the ovillo grass (Maldonado et al., 2017), consequently, the little contribution of the ovillo grass to the annual yield could be due to the fact that when this species is subjected to a severe grazing intensity and is left with a minimum of remaining leaves, and carbohydrate reserves at the root, the regrowth is slow, therefore, it is recommended to leave three leaves per stem, to reactivate the photosynthesis process and ensure a greater regrowth in the shortest possible time (Turner et al., 2006).
Botanical and morphological composition
Figure 2 shows seasonal changes in the botanical and morphological composition of grasslands under three grazing frequencies. Regardless of the grazing frequency, white clover contributed more than 50% during spring, 60% during autumn-winter and only 40% in summer. During this time, ovillo grass provided the highest percentage (40%) during the year (p< 0.01).
But also, the highest percentage of other grasses and weeds was presented, a component that had the highest contribution in spring, followed by summer, winter and the lowest, in autumn (p< 0.05). Similar results were found in a study, where white clover was the main component (26 to 66%) in the associations evaluated as a consequence of its greater ability to compete with erectly growing species and tolerate defoliation (Flores et al., 2015).
On the other hand, Castro et al. (2012) in five associations of white clover, ovillo grass and perennial ballico reported white clover with the highest contribution of the total yield of 50%, perennial ballico with 28% and ovillo grass with 12%; the remaining 10% was made up of dead material, other grasses and weeds.
White clover tends to dominate in the associated grasslands over time due to its stoloniferous growth habit, obtaining greater advantage compared to the ovillo grass and ballico grasses that are tufted and erect (Rojas et al., 2017). As can be seen in this investigation, it is not the exception, since the initial mixture of the grassland was 40-60 of white clover and ovillo, three years after planting.
Crop growth rate
The growth rate of white clover associated with ovillo grass when varying the grazing frequency is observed in Table 3. The highest seasonal growth rate occurred in the frequency of 28 days during spring (70 kg DM ha-1 d-1; p< 0.05), which exceeded the frequency of 95% IR (52 kg DM ha-1 d-1) in 18 kg DM ha-1 d-1 (equivalent to 35%).
Season | Grazing frequency | SEM | Significance | Average | ||
28-35 day | 95% de IR | 100% de IR | ||||
Spring | 70 aA | 52 aB | 66 aAB | 5 | * | 63 a |
Summer | 67 a | 56 a | 56 ab | 4 | ns | 60 a |
Autumn | 31 b | 31 b | 40 bc | 5 | ns | 34 b |
Winter | 27 b | 41 ab | 25 c | 4 | ns | 31 b |
Annual average | 49 | 44 | 46 | 2 | ns | |
SEM | 6 | 4 | 4 | 3 | ||
Significance | ** | * | ** | ** |
Means with different capital letters between rows represent significant difference and averages with lower case letters between columns represent significant difference (Tukey, 0.05). Sig.= significance; *= p< 0.05; **= p< 0.01. Int= interval between grazing, in days. ns= not significant.
During the sampling period, no statistical difference (p> 0.05) was observed in the other seasons of the year in the different grazing frequencies and annual average; however, although the trend was similar, on average there was a higher growth rate in spring (63 kg DM ha-1 d-1; p< 0.05), which was 103% higher in the winter (31 kg DM ha-1 d-1), 85% in the fall (34 kg DM ha-1 d-1) and only exceed 5% in the summer (60 kg DM ha-1 d-1).
These results coincide with those observed by Velasco et al. (2001) who in pure grasslands of ovillo recorded the highest GR in the third week of spring, which was 78 kg DM ha-1 d-1, while for summer it was in the fourth week with 50 kg DM ha-1 d-1. Similarly, the results obtained coincide with other work led by Velasco et al. (2002) when evaluating the growth curve of the perennial ryegrass, they reported the highest growth rates in spring, followed by summer with values of 98 and 53 kg DM ha-1 d-1, respectively.
Seasonal changes in growth rate (kg DM ha-1 d-1) is closely linked to the amount of radiation intercepted, largely determined by the leaf area index (IAF), photosynthetically active intercepted radiation (PAR; 400-700 nm) and due to the interaction with numerous environmental factors (Ewert, 2004; Abhishek et al., 2018) and physiological characteristics (Durand, 1999).
As observed in Figure 1, the environmental conditions were not favorable for the autumn-winter seasons, since it was in those sampling times that the lowest temperatures occurred and there was a higher incidence of frost, affecting the performance of the grassland (Rojas et al., 2016a).
Grassland height
Grassland height is an indirect method that provides estimates of the forage mass present in the grassland and is a useful tool that helps to make management decisions of pasture and legume associations efficiently and allows optimizing the costs of production (Adams et al., 1977).
The height in white clover grasslands associated with ovillo grass when varying the grazing frequencies is observed in Table 4. The highest height of the grassland was presented in the grazing frequency of 28 days in summer with 26 cm, exceeding 5 cm at the grazing frequency of 95% IR with 21 cm, in the same way, winter showed higher height in the frequency of 100% IR with 17 cm and lower grazing frequency of 35 days with 11 cm (p= 0.05).
Season | Grazing frequency | SEM | Significance | Average | ||
28-35 days | 95% de IR | 100% de IR | ||||
Spring | 18 ab | 17 a | 19 b | 1.3 | ns | 18 b |
Summer | 26 aA | 21 aB | 25 aA | 0.7 | * | 24 a |
Autumn | 14 b | 13 b | 16 b | 1 | ns | 14 c |
Winter | 11 bB | 12 bB | 17 bA | 0.5 | ** | 13 c |
Anual average | 17 B | 15 C | 19 A | 0.5 | ** | |
SEM | 1.8 | 0.8 | 0.8 | 1 | ||
Significance | * | ** | ** | ** |
Means with different capital letters between rows represent significant difference and averages with lower case letters between columns represent significant difference (Tukey, 0.05). *= p< 0.05; **= p< 0.01. Int= Interval between grazing, in days. ns= not significant.
The results obtained coincide with Flores et al. (2015), who reported the highest average heights in summer (38 cm) followed by spring (18 cm), autumn (14 cm) and winter (13 cm), respectively. Grassland height is positively related to dry matter yield (Castro et al., 2012) and intercepted radiation.
As observed in the present experiment, where the highest height found in the summer and spring coincided with the highest seasonal dry matter yield, as has been demonstrated in other works directed by Flores et al. (2015) and Rojas et al. (2016b) in associations of white clover, ovillo grass and perennial ryegrass.
Conclusions
The annual dry matter yield, growth rate, height of white clover forage associated with ovillo grass was higher in spring-summer and grazing yield set at 28 days after grazing. Regardless of the grazing frequencies, the contribution of white clover was higher compared to ovillo grass in autumn and winter. It is recommended to graze the association of white clover and ovillo grass when the grassland reached 95% of intercepted radiation, regardless of the season of the year.
Literatura citada
Abhishek, M. T.; Pohanková, E. Ma.; Fischer, M.; Orság, M.; Trnka, M.; Klem, K. and Marek, M. V. 2018. The evaluation of radiation use efficiency and leaf area index development for the estimation of biomass accumulation in short rotation poplar and annual field crops. Forests. 9(1):1-16. [ Links ]
Adams, J. E. and Arkin, G. F. 1977. A light interception method for measuring row crop ground cover. Soil Sci. Soc. Am. J. 41(4):789-792. [ Links ]
Amendola, R.; Castillo, E. y Martínez, P. A. 2005. Pasturas y cultivos forrajeros. Organización para la Alimentación y la Agricultura (FAO). http://www.fao.org. [ Links ]
Black, A. D.; Laidlaw, A. S.; Moot, D. J. and O’Kiely, P. 2009. Comparative growth and management of white and red clovers. Irish J. Agric. Food Res. 48(2):149-166. [ Links ]
Castro, R. R.; Hernández-Garay, A.; Vaquera, H. H.; Hernández, P. G. J.; Quero, C. A. R.; Enríquez, Q. J. F. y Martínez, H. P. A. 2012. Comportamiento productivo de asociaciones de gramíneas con leguminosas en pastoreo. Rev. Fitot. Mex. 35(1):87-95. [ Links ]
Durand, J. L.; Schäufele, R. and Gastal, F. 1999. Grass leaf elongation rate as a function of developmental stage and temperature: Morphological analysis and modeling. Ann. Bot. 83(5):577-588. [ Links ]
Ewert, F. 2004. Modelling plant responses to elevated CO2: how important is leaf area index?. Annals Bot. 93(6):619-627. [ Links ]
Flores, S. E.; Hernández, G. A.; Guerrero, R. J. D.; Quero, C. R. A. y Martínez, H. P. A. 2015. Productividad de asociaciones de pasto ovillo (D. glomerata L.), ballico perenne (Lolium perenne L.) y trébol blanco (Trifolium repens L.). Rev. Mex. Cienc. Pec. 6(3):337-347. [ Links ]
García, E. 2004. Modificaciones al sistema de clasificación climática de Köppen. 4 (Ed.). Universidad Nacional Autónoma de México (UNAM). México, DF. 217 p. [ Links ]
Lee, M. A. 2018. A global comparison of the nutritive values of forage plants grown in contrasting environments. J. Plant Res. 131:641-654. [ Links ]
Maldonado, P. M. A.; Rojas, G. A. R.; Torres, S. N.; Herrera, P. J.; Joaquín, C. S.; Ventura, R. J.; Hernández, G. A. and Hernández, G. F. J. 2017 Productivity of orchard grass (Dactylis glomerata L.) alone and associated with perennial ryegrass (Lolium perenne L.) and white clover (Trifolium repens L.). Rev. Brasileira Zootecnia. 46(12):890-895. [ Links ]
Moreno, C. M. A.; Hernández-Garay, A.; Vaquera, H. H.; Trejo, L. C.; Escalante, E. J. A.; Zaragoza, R. J. L. y Joaquín, T. B. M. 2015. Productividad de siete asociaciones y dos praderas puras de gramíneas y leguminosas en condiciones de pastoreo. Rev. Fitotec. Mex. 38(1):101-108. [ Links ]
Randazzo, C. P.; Rosso, B. S. y Pagano, E. M. 2013. Identificación de cultivares de trébol blanco (Trifolium repens L.) mediante SSR. J. Basic & Appl. Gen. 24(1):19-26. [ Links ]
Rojas, G. A. R.; Hernández, G. A.; Ayala, W.; Mendoza, P. S. I.; Joaquín, C. S.; Vaquera, H. H. y Santiago, O. M. A. 2016a. Comportamiento productivo de praderas con distintas combinaciones de ovillo (Dactylis glomerata L.), ballico perene (Lolium perenne L.) y trébol blanco (Trifolium repens L.). Rev. Facultad Cienc. Agrar. 48(2):57-68. [ Links ]
Rojas, G. A. R.; Hernández, G. A.; Quero, C. A. R.; Guerrero, R. J. D.; Ayala, W.; Zaragoza, R. J. L. y Trejo, L. C. 2016b. Persistencia de Dactylis glomerata L. solo y asociado con Lolium perenne L. y Trifolium repens L. Rev. Mex. Cienc. Agríc. 7(4):885-895. [ Links ]
Rojas, G. A. R.; Hernández, G. A.; Rivas, J. M. A.; Mendoza, P. S. I.; Maldonado, P. M. A. y Joaquín, C. S. 2017. Dinámica poblacional de tallos de pasto ovillo (Dactylis glomerata L.) y ballico perenne (Lolium perenne L.) asociados con trébol blanco (Trifolium repens L.). Rev. Fac. Cienc. Agrar. 49(2):35-49. [ Links ]
Sanderson, M.; Brink, G.; Stout, R. and L. Ruth. 2013. Grass-legume proportions in forage seed mixtures and effects on herbage yield and weed abundance. Agron. J. 105(5):1289-1297. [ Links ]
SAS. 2009. SAS/STAT® 9.2. Use’s guide release.Cary, NC: SAS InstituteIcn. USA. 360 p. [ Links ]
Turner, L. R.; Donaghy, D. J.; Lane, P. A. and Rawnsley. R. P. 2006. Effect of defoliation interval on water-soluble carbohydrate and nitrogen energy reserves, regrowth of leaves and roots, and tiller number of cocksfoot (Dactylis glomerata L.) plants. Aust. J. Agric. Res. 57(2):243-249. [ Links ]
Velasco, Z. M. E.; Hernández, G. A.; González, H. V. A.; Pérez, P. J.; Vaquera, H. H. y Galvis, S. A. 2001. Curva de crecimiento y acumulación estacional del pasto ovillo (Dactylis glomerata L.). Téc. Pecu. Méx. 39(001):1-14. [ Links ]
Velasco, Z. M. E; Hernández-Garay, A.; González, H. V. A.; Pérez, P. J. y Vaquera, H. H. 2002. Curvas estacionales de crecimiento del ballico perenne. Rev. Fitotec. Mex. 25(1):97-106. [ Links ]
Received: January 01, 2020; Accepted: March 01, 2020