Dong Shikui

Effect of urea multinutritional molasses block supplementation on liveweight change of yak calves and productive and reproductive performances of yak cows

Using three different types of yaks, 30 head of 1-yr-old calves (liveweight 60.7 +/- 6.3 kg), 30 head of 2-yr-old calves (97.7 +/- 10.2 kg) and 30 head of yak cows (160.2 +/- 15.1 kg) were randomly selected from the same yak herds. Each type of yak herd was divided into control (C) and trial (T) groups using a completely randomized design, with 10 and 20 animals in the C and T groups, respectively. The animals in the C group were grazed on natural rangeland, and the animals in the T group were supplemented with urea multinutritional molasses blocks (UMMB), together with grazing on natural rangeland from January to May of 1998. The objective was to determine the effect of UMMB on productive performance of yak calves and yak cows in the cold season. Live weight loss of 1-yr-old calves, 2-yr-old calves and yak cows was reduced by 1.2, 8.3 and 7.9 kg after UMMB supplementation (P < 0.01). The 1-yr-old calves gained the most in the first month of supplementation, but the 2-yr-old calves and yak cows gained the most both in the first and last supplementation months. Daily milk yield of yak cows increased by 0.21 kg d(-1) when the lactating animals were supplemented with UMMB (P < 0.01), although there was no effect (P < 0.01) of UMMB supplementation on hair and downy hair production. Supplementation with UMMB also improved reproductive performance of yak cows, with 8.8 and 30.9% increments in pregnancy rate and newborn weight, respectively. We conclude that the benefit of UMMB supplementation the 1-yr-old calves was not economical, with only 0.3:1 output to input ratio, but supplementation of the 2-yr-old calves and yak cows may be economical, with 1.8:1 and 1.4:1 output to input ratios, respectively.

Regionalisation of suitable herbages for grassland reconstruction in agro-pastoral transition zone of northern China

Abstract To provide a sound basis for selecting suitable herbages for grassland reconstruction in the farming‐pastoral zone of northern China, the zone was divided into regions using the lowest annual temperature, water regimes represented by a moisture index (the ratio between annual rainfall and accumulated temperature >0°C), soil types, and terrain. Suitable herbages of Gramineae (G), Legu‐minosae (L) and other families (O), representing native species (NS) and non‐native cultivars (CR) were recommended for the zone based on the following four principles: a) matching species with the site; b) giving precedence to ecological conservation; c) providing economic benefit to production; and d) taking into account the integrity of local administrative division. The main findings from this study were as follows. The farming‐pastoral zone was divided into seven regions: I. Western Songliao Plain and Daxinganling Mountain Region; II. Upper Liaohe River Sandy Region; III. Mid‐Eastern Mongolia Plateau and Northwestern Heibei Mountain Region; IV. Luliang, Taihang and Yanshan Mountains Region; V. Ordos Plateau Sandy Region; VI. Northern Shaanxi to Eastern Ganxu Loess Plateau Region; and VII. Mid Gansu to Eastern Qinghai Plateau Loess Region. Among the herbages recommended for selection, Stipa grandis and Leymus chinensis were particularly suggested for controlling wind erosion in Region I; Leymus chinensis and Elymus dahuricus for lessening soil alkalisation in Region II; Stipa glareos, Elymus dahuricus and Agropyron deserto‐rum for retarding land desertification in Region III; Elymus nutans and Bromus inermis for preventing water erosion in Region IV; Agropyron desertorum and Elymus dahuricus for reducing wind erosion and land desertification for Region V; Medicago sativa and Onobrychis viciaefolia for improving soil fertility in Region VI; Medicago varia and Melilotoides rethenica for controlling erosion and improving soil fertility in Region VII.

Influence of grazing intensity on performance of perennial grass mixtures in the alpine region of the Tibetan Plateau

Abstract Effects of grazing intensity on leaf photosynthetic rate (Pn), specific leaf area (SLA), individual tiller density, sward leaf area index (LAI), harvested herbage DM, and species composition in grass mixtures (Clinelymus nutans + Bromus inermis, Elymus nutans + Bromus inermis + Agropyron cristatum and Elymus nutans + Clinelymus nutans + Bromus inermis + Agropyron cristatum) were studied in the alpine region of the Tibetan Plateau. Four grazing intensities (GI), expressed as feed utilisation rates (UR) by Tibetan lambs were imposed as follows: (1) no grazing; (2) 30% UR as light grazing; (3) 50% UR as medium grazing; and (4) 70% UR as high grazing. Leaf Pn rate and tiller density of grasses increased (P < 0.05), while sward LAI and harvested herbage DM declined (P < 0.05) with the increments of GI, although no effect of GI on SLA was observed. With increasing GI, Elymus nutans and Clinelymus nutans increased but Bromus inermis and Agropyron cristatum decreased in swards, LAI and DM contribution. Whether being grazed or not, Elymus nutans + Clinelymus nutans + Bromus inermis + Agropyron cristatum was the most productive sward among the grass mixtures. Thus, two well‐performed grass species (Elymus nutans and Clinelymus nutans) and the most productive mixture of four species should be investigated further as the new feed resources in the alpine grazing system of the Tibetan Plateau. Light grazing intensity of 30% UR was recommended for these grass mixtures when swards, LAI, herbage DM harvested, and species compatibility were taken into account.

Effect of annual weeds on the growth of perennial grass mixtures in the alpine region of the Qinghai‐Tibetan Plateau

Abstract In the alpine region of the Tibetan Plateau, five perennial grass cultivars, Bromus inermis (B), Elymus nutans (E), Clinelymus nutans (C), Agropyron cristatum (A), and Poa crymophila (P) were combined into nine communities with different compositions and ratios, B+C, E+A, B+E+A, E+B+C, C+E+A, B+E+C+A, B+C+A+P, B+E+A+P and E+C+A+P. Each combination was sown in six 10 × 10 m plots with three hand‐weeded plots and three natural‐growing plots in a completely randomised design in 1998. Afield experiment studied the performance of these perennial grass combinations under the competitive interference of annual weeds in 3 consecutive years from 1998 to 2000. The results showed that annual weeds occupied more space and suppressed the growth of the grasses due to earlier germination and quicker growth in the establishment year, but this pattern changed in the second and third years. Leaf area indexes (LAIs) of grasses were greatly decreased by the competitive interference of weeds, and the negative effect of weeds on LAIs of grasses declined and stabilised in the second and third years. E+B+C, B+E+C+A, and B+E+A+P possessed relatively higher LAIs (P < 0.05) among all grass combinations and their LAIs were close to five when the competitive interference of weeds was removed. Grasses were competitively inferior to weeds in the establishment year, although their competitive ability (aggressivities) increased throughout the growing season. In the second and third years, grasses were competitively superior to weeds, and their competitive ability decreased from May until August and increased in September. Dry matter (DM) yields of grasses were reduced by 29.8–74.1% in the establishment year, 11.0–64.9% in the second year, and 16.0–55.8% in the third year by the competitive interference of weeds. B+E+C+A and B+E+A+P can produce around 14 t/ha of DM yields, significantly higher (P < 0.05) than the production of the other grass combinations in the second and third years after the competitive interference of weeds was removed. It was preliminarily concluded that removal of competitive interference of weeds increased the LAIs of all grass swards and improved the light interception of grasses, thus promoting the production of perennial grass pastures. The germination stage of the grasses in the establishment year was the critical period for weeding and suppression of weeds should occur at an early stage of plant growth. The grass combinations of B+E+C+A and B+E+A+P were productive and can be extensively established in the alpine regions of the Tibetan Plateau. Two or three growing seasons will be needed before determining success of establishment of grass mixtures under the alpine conditions of the Tibetan Plateau.