A NOTE ON THE ZERO-GRAZING OF BEEF CATTLE

Groups of 8 steers weighing 300–400 kg (660–880 Ib) were rotationally grazed on a ryegrass-dominant pasture for 115 days. The systems compared were zero grazing (Z), field grazing conducted at the same stocking rate (FC), and field grazing conducted at a stocking rate varied with the intention of giving the same liveweight gain per uiimal as zero grazing (FV). Mean daily liveweight gains were: Z, 0.98; FC, 0.78; FV, 0.90 kg/animal (2.2, 1.7 and 20 Ib/animal), and liveweight gains/unit area were in the ratio 100:78:85. Organic-matter intake, measured on four occasions, was, on average, Z, 6.54; FC, 6.18; FV, 687 kg/head daily (14.4, 13.6 and 15.1Ib). From these results it appears that a comparison of zero grazing and field grazing made at the same stocking rate is likely to underestimate the potential of field grazing for beef production from grass.     

FERTILIZER N AND THE YIELD OF CUT GRASS SWARDS IN EASTERN ENGLAND

Single spring dressings of N were compared with split applications over the first two growth periods of the year at ten sites in eastern England in the period 1964–67. None of the four spring periods was unusually dry and the single application of N in spring did not outyield a similar total N rate applied some before and some after the first cut. At nine out of ten sites split applications of N yielded considerably more in the second growth period than the single spring dressing. It is concluded that the split applications of N in the spring, already shown superior to single dressings under moist west country conditions, are correct for many seasons in the drier east of England.     

THE EFFECT OF NITROGENOUS FERTILIZER ON THE RATE OF GROWTH OF ITALIAN RYEGRASS.

Residual response to an initial application of nitrogen was measured in 3 years and was found to be quite large, e.g. a response of 8 Ib DM per extra Ib N at the first harvest, when applying 125 Ib N/ac (140 kg/ha) rather than‘75 Ib (84 kg/ha) and allowing 6 weeks' growth, was increased to 21 Ib DM when yield from residual cuts was taken into account. Response was large in relation to the amount of N estimated to have been left behind after the first harvest. Marginal recovery of N, already quite high at the first harvest, was increased to a little over 90% when yield from residual cuts was taken into account Recovery, however, was lower than this when 10 weeks' growth was allowed before the first harvest, and it seems that, in this case, some N may have been lost from the system. A supplementary experiment suggested that the residual effect of N on DM yield could be obscured to some extent by fresh applications of N.     

The application of ultraviolet microscopy to the distribution of lignin in wood description and validity of the technique

A method has been developed for the determination of lignin distribution in the wood cell wall by ultraviolet microscopy. The method incorporates some important advances on previus applications of UV microscopy to the study of lignin distribution. Ultrathin cross-sections of wood are obtained by the sample preparation and sectioning techniques of electron microscopy. The specimens are examined in monochromatic ultraviolet light using quartz reflection optics. The microscope image is photographically recorded and the negative is subsequently subjected to densitometric analysis. Each stage of the analytical procedure has been critically assessed to determine its validity and limitations. The method is ideally suited to the study of the removal of lignin from the wood cell wall during cooking and possesses other important applications in wood technology.     

Intersprout competition in the potato II. Competition for nutrients during pre-emergence growth after planting

Summary The influence of temperature, number of sprouts per tuber and concentration of supplementary inorganic nutrients on sprout growth and intersprout competition for tuber substrates during emergence was investigated in the potato varietyArran Pilot. The rate of sprout growth was found to be a positive function of initial tuber fresh weight. Dry weight data at emergence indicated that individual sprouts on multi-sprout tubers exhibited mutual interference for substrates from the tuber. The intensity of this interference increased with temperature in the range 7 25 C, but interference was reduced, and in some cases eliminated, by supplying inorganic nutrients in the rooting medium. It was concluded that a component of the inorganic nutrient solution used could replace the tuber factor the supply of which limited sprout growth. The effects of temperature and inorganic nutrient concentration on the partitioning of dry matter within the plant are deseribed and diseussed.

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Zusammenfassung Die Einflüsse von Temperatur, ursprünglichem Knollengewicht, der Anzahl Keime pro Knolle und der Konzentration zus?tzlicher anorganischer N?hrstoffe auf das Keimwachstum sowie die Konkurrenz zwischen den Keimen um das Knollensubstrat w?hrend des Auflaufens wurden an der KartoffelsorteArran Pilot untersucht. Ween Knollen in ein n?hrstofffreies Medium gepflanzt wurden (Versuch 1), glich die Auflaufrate der Keime einer positiv linearen Funktion der Temperatur über einen Bereich von 7 C bis 25 C, aber sie war nicht signifikant beeinflusst durch die Zahl der Keime pro Knolle (Tabelle 1 und 2). Die einzelnen Keime von Knollen mit vielen Keimen konkurrierten um das Substrat der Mutterknolle, und die St?rke dieser Interferenz nahm mit steigender Temperatur w?hrend des Auflaufens zu (Abb. 1 und 2). In den Versuchen 2 und 3 wurde die Auflaufzeit durch die Beigabe einer anorganischen Volln?hrl?sung zum Wurzeln?hrboden verkürzt, aber sie wurde nicht signifikant beeinflusst durch die Zahl der Keime pro Knolle (Tabelle 4). Eine Erh?hung der N?hrstoffkonzentration in der anorganischen L?sung hatte eine Erh?hung des durchschnittlichen Trockengewichtes der Keime und des durchschnittlichen Trockengewichtes der Keime pro Knolle beim Auflaufen zur Folge (Abb. 4 und 5). In Versuch 2 setzte die Gabe von anorganischen N?hrstoffen die Intensit?t der Konkurrenz zwischen den Keimen um das Substrat aus der Knolle betr?chtlich herab, was darauf hindeutet, dass ein Bestandteil der verwendeten N?hrl?sung den “Knollenfaktor”, der das Keimwachstum begrenzt, ersetzen k?nnte. Im Versuch 3 dagegen wurde die Interferenz um die Substrate aus der Knolle durch die Konzentration der verwendeten N?hrstoffe nicht beeinflusst. Diese Abweichung zwischen den zwei Versuchen dürfte mit dem unterschiedlichen Grad der Interferenz zwischen den Wurzelsystemen der einzelnen Keime für die Zufuhr der verwendeten N?hrstoffe in Zusammenhang stehen (Tabelle 5). Die Temperatur nach dem Auspflanzen übte einen betr?chtlichen Einfluss auf die Verteilung der Trockensubstanz innerhalb des Stengel-systems aus. Anzahl, L?nge und Trockengewicht der Stolonen pro Keim (Abb. 3) und das Verh?ltnis des Stolonentrockengewichtes zum gesamten Trockengewicht der Stengel (Tabelle 3) waren in umgekehrter Bezichung von der Temperatur abh?ngig, in den Versuchen 1 und 3 stand das Verh?ltnis des Stolonentrockengewichtes zum gesamten Stengelgewicht in umgekehrter Bezichung zur Anzahl Keime pro Knolle: in Versuch 3 war diese Beziehung aber nicht signifikant beeinflusst durch die Konzentration der mineralischen N?hrstoffe. Diese Ergebnisse wiesen darauf hin, dass neben der Temperatur ein spezifischer Faktor in der Mutterknolle auf das Stolonenwachstum einwirkte und dass dieser Faktor nicht durch eine den Knollen zur Verfügung stehende mineralischen N?hrstoffl?sung ersetzt werden kann. In den Versuchen 2 und 3 erweiterte sich das Stengel/Wurzel-Verh?ltnis mit der Erh?hung der Konzentration der verwendeten anorganisehen N?hrstoffe, aber es war nicht signifikant beeinflusst durch die Zahl der Keime pro Knolle.

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Résumé L’auteur a recherché, sur la variété de Pomme de terreArran Pilot, l’influence de la température, du poids initial du tubercule, du nombre de germes par tubercule et de la concentration en éléments nutritifs inorganiques supplémentaires sur la croissance du germe et la compétition entre les germes pour les réserves du tubercule pendant la levée. Quand les tubercules sont plantés dans un milieu dépourvu d’éléments nutritifs (expérience 1), la vitesse d’émergence d’un germe est une fonction linéaire positive de la température dans les limites de 7 C à 25 C mais n’est pas significativement influencéc par le nombre de germes par tubercule (tableau 1 et 2). Les germes des tubercules à plusieurs germes rivalisent individuellement pour les réserves du tubercule-mère et il se révèle que l’intensité de cette interférence s’accro?t avec l’augmentation de la température pendant l’émergence (Fig. 1 et 2). Dans les expériences 2 et 3, le temps d’émergence est réduit par l’application au milieu d’enracinement d’une solution nutritive complète inorganique, mais n’est pas significativement influencé par le nombre de germes par tubercule (Tableau 4). Une augmentation de la concentration en éléments nutritifs inorganiques entra?ne, lors de l’émergence, une augmentation du poids sec moyen d’un germe et une augmentation du poids sec moyen de tous les germes du tubercule (Fig. 4 et 5). Dans l’expérience 2 l’application d’éléments nutritifs inorganiques réduit l’intensité de la compétition entre germes pour les réserves du tubercule, ce qui signifie qu’un composant de la solution nutritive utilisée remplace le facteur du tubercule qui limite la croissance du germe. Cependant, dans l’experience 3, la compétition pour les réserves du tubercule n’est pas influencée par la concentration des éléments nutritifs appliqués. La différence dans les deux expériences peut provenir des différences dans le degré d’interaction entre les systèmes radiculaires des germes individuels pour les approvisionnements en éléments nutritifs appliqués (Tableau 5). La température après plantation exerce une influence considérable sur la répartition de la matière sèche dans le système radiculaire. Le nombre, la longucur et le poids sec de stolons par germe (Fig. 3) et le rapport du poids sec des stolons au poids total sec des germes (Tableau 3) sont des fonctions inverses de la température. Dans les expériences 1 et 3 le rapport poids sec des stolons au poids total des germes est inversément relié au nombre de germes par tubercule, mais dans l’expérience 3 ce rapport n’est pas significativement influencé par la concentration externe des éléments minéraux. Ces résultats indiquent qu’en plus des effets de la température, un facteur spécifique provenant du tubercule-mère influe sur la croissance du stolon, et que ce facteur ne peut être remplacé par un apport externe d’éléments nutritifs minéraux. Dans les expériences 2 et 3 le rapport bourgeon/ racine augmente avec l’accroissement de la concentration en éléments nutritifs inorganiques appliqués mais n’est pas significativement influencé par le nombre de germes par tubercule.

     

THE UTILIZATION OF GRASS FED INDOORS TO YOUNG BEEF CATTLE, WITH OR WITHOUT SUPPLEMENTARY BARLEY

An experiment was carried out in which grass was cut and fed indoors, with or without supplementary barley. Seven animals were allocated to each of the following treatments: (1) grass ad lib . without supplementary barley; (2) grass ad lib . with supplementary barley at the rate of 0.5 lb/100 lb bodyweight; (3) grass ad lib . with supplementary barley at the rate of 1 lb/100 lb bodyweight. Supplementary barley increased total dry-matter intake and improved daily liveweight gain and food conversion rate. The mean daily liveweight gains for the 17-week experimental period were 1.60, 1.91 and 2.20 lb and the corresponding feed dry-matter conversion ratios were 6.18, 5.67 and 5.55 for Treatments 1, 2 and 3, respectively.
The dry-matter digestibility of the diets was slightly higher when the grass was supplemented with barley than when grass alone was given. Although barley depressed the digestibility of protein, the absolute and the proportionate retention of nitrogen was increased. This was particularly marked on Treatment 3, presumably because of the higher net energy value of the diet containing the greater amount of barley. The N-retention data corresponded to the rates of liveweight gain obtained.     

A COMPARISON OF THE REACTION OF DIFFERENT GRASS SPECIES TO FERTILIZER NITROGEN AND TO GROWTH IN ASSOCIATION WITH WHITE CLOVER. II. YIELD OF NITROGEN

Seven species or varieties of grass, and a mixture of 3 of them, were sown in pure swards, treated with 4 levels of nitro-chalk (0, 17·5, 35, and 70 Ib N/ac/cut) and cut 4 or 5 times each year. Each species and the mixture were also sown with white clover, and the effect of fertilizer N on the yield of N in each grass was compared with the effect of clover on the yield of N harvested from the grass/clover swards.
The regression line for response in yield of N with increasing levels of fertilizer N showed slight, but significant, upward curvature. The grasses differed in their uptake of N from the soil, S37 cocksfoot and S48 timothy showing relatively high uptakes, and the ability of each grass to take up fertilizer N was usually related to its uptake of N from the soil. Differences in the yield of dry matter between the species, at a similar level of N, are discussed, and it was concluded that perennial ryegrasses were most efficient and Agrostis tenuis was least efficient in using the N taken up in the production of DM.
In general, there were no significant differences between the yields of N of the grass/clover mixtures; the N yields of the grass components were significantly different and tended to be inversely related to the N yields of clover.
Grasses which gave high yields of N with fertilizer were also high yielding when grown in association with clover. Pure grass swards required more than 200 Ib fertilizer N/ac/yr in order to yield the same amount of N as the grass/clover swards. The amount of N estimated to have been derived by grass from clover (indirect effect of clover) increased each year; it was highest with S37 cocksfoot and lowest with Irish perennial ryegrass, averaging 46 and 23 Ib N/ac/yr, respectively.