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Calorespirometric evidence for adaptation of blackbrush and shadscale to growth season temperatures in cold deserts /Summers, Heidi A., January 2005 (has links) (PDF)
Thesis (M.S.)--Brigham Young University. Dept. of Plant and Animal Sciences, 2005. / Includes bibliographical references (p. 14-18).
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A genetic study of Gigas atriplex canescensMelby, James Michael 01 August 1972 (has links)
A population of Atriplex canescens (Pursh) Nutt. (fourwing saltbush), endemic to the Little Sahara Sand Dunes near Jericho, Utah, appears to be genetically distinct from all other forms of this species. It differs from other populations by many characters, including growth rate, seed size, and height (Figures 1, 2, 3 and 4). This is a report of a study which was made to investigate the differences between the sand dune and normal populations, and an attempt to determine the evolutionary processes involved in the formation of the sand dune population.
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Salt Tolerance of Forage Kochia, Gardner's Saltbush, and Halogeton: Studies in Hydroponic CultureSagers, Joseph 01 May 2016 (has links)
Halogeton (Halogeton glomeratus) is a halophytic, invasive species that displaces Gardner’s saltbush (Atriplex gardneri) on saline rangelands. Forage kochia (Bassia prostrata) is a potential species to rehabilitate these ecosystems. This study compared the salinity tolerance of these species and tall wheatgrass (Thinopyrum ponticum) and alfalfa (Medicago sativa). Plants were evaluated for 28 days in hydroponics where they were maintained at 0, 150, 200, 300, 400, 600, and 800 mM NaCl. Shoot growth and ion accumulation were determined. Alfalfa and tall wheatgrass were severely affected by salt with both species’ shoot mass just 32% of control at 150 mM NaCl. Alfalfa did not survive above 300 mM NaCl, while, tall wheatgrass did not survive at salt levels above 400 mM NaCl. In contrast, forage kochia survived to 600 mM, but produced little shoot mass at that level. Halogeton exhibited ‘halophytic’ shoot growth, reaching maximum mass at 141 mM, and not less mass than the control until salinity reached 400 mM. Gardner’s saltbush did not show a dramatic decrease in dry mass produced until it reached salt levels of 600 and 800 mM NaCl. Forage kochia yielded high amounts of dry mass in the absence of salt, but also managed to survive up to 600 mM NaCl. Salt tolerance ranking (GR50 = 50% reduction in shoot mass) was Gardner’s saltbush=halogeton>forage kochia> alfalfa>tall wheatgrass. Both halogeton and Gardner’s saltbush actively accumulated sodium in shoots, indicating that Na+ was the principle ion in osmotic adjustment. In contrast, forage kochia exhibited a linear increase (e.g. passive uptake) in Na+ accumulation as salinity increased. This study confirmed that halogeton is a halophytic species and thus well adapted to salt-desert shrubland ecosystems. Gardner’s saltbush, also a halophyte, was equally salt tolerant, suggesting other factors are responsible for halogeton displacement of Gardner’s saltbush. Forage kochia is a halophytic species that can survive salinity equal to seawater, but is not as salt tolerant as Gardner’s saltbush and halogeton.
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High dietary salt during pregnancy in ewes alters the responses of offspring to an oral salt challenge.Digby, Serina January 2007 (has links)
Most research to date has focused on non-pregnant sheep grazing saltbush to fill the summer/autumn feed gap in temperate regions of southern Australia. However, the summer/autumn period coincides with late pregnancy for autumn- or winter-lambing ewes, and feeding saltbush may reduce the amount and cost of supplementary feed that is required to meet the energy demands of late pregnancy. The challenge of dealing with a high-salt diet may be exacerbated during pregnancy since pregnancy is a salt-retaining physiological state, yet a high-salt intake requires an increase in mechanisms to excrete salt. The effect of high dietary salt on the developing foetus(es) has been studied in rodent models, but less so in sheep. Hence the aims of this thesis were to determine whether pregnant ewes can manage a high dietary salt content resembling that found in saltbush, and whether there are consequences to the offspring’s physiological responses to ingested salt. Merino ewes were synchronized for ovulation and artificially inseminated. To mimic the concentration of salt in animals grazing saltbush-based pastures in summer and autumn, a diet of 13% NaCl was fed from insemination through to parturition. It was found that pregnant ewes can be fed a 13% NaCl diet and manage the physiological conflict of high salt and pregnancy by decreasing their aldosterone concentrations and increasing their water consumption. There was no effect of high dietary salt on pregnancy rates, lamb birth weights, lamb survival or milk composition (fat and protein percentages). A series of experiments were conducted to test if the high-salt intake of ewes during pregnancy was associated with a change in the dietary preference for salt and/or changes in physiological responses to ingested salt in the offspring (‘S lambs’ vs. control, ‘C lambs’). C lambs and S lambs were exposed to short- and long-term preference testing to determine if there were differences in their voluntary selection for salt in their diet. There were no significant differences in dietary salt preference between C and S lambs. The lambs were subjected to salt 'challenges' (oral dose of 40 g NaCl in 25% w/v solution) from 3-10 months of age and their water intake, urinary output, sodium excretion and hormone concentrations were measured over the ensuing 23 hours, and compared against counterparts dosed with an equal volume of water without salt. Following the initial salt challenge further experiments were conducted with slight alterations; water intake was manipulated immediately following the salt challenge; two consecutive salt challenges, 8 hours apart, were administered; and C and S lambs were offered salty water (1.5% NaCl) over a period of two days. The results of these salt challenge experiments showed that C and S lambs excreted a salt load at a similar rate, but they differed in the magnitude of changes in water intake and hormone concentrations required to achieve sodium homeostasis. S lambs were able excrete sodium at the same rate as C lambs but without decreasing aldosterone concentrations to the same extent and whilst consuming 400 mL less water in the first two hours post challenge. The aldosterone results suggested a lowered responsiveness to aldosterone and the lower water consumption suggested an altered thirst threshold. The experiment in which water consumption was manipulated suggested that when the supply or access to fresh water is limited, the capacity to remove a salt load is likely to be less impaired in S lambs than C lambs; S lambs were able to excrete the salt load faster than the C lambs when the availability of drinking water was limited. From the experiment in which lambs were treated with two consecutive salt challenges, the rate of sodium excretion increased after the second dose, but there remained no difference in the rate of excretion between C and S lambs; all animals were able to excrete 95% of the administered dose of sodium within 23 hours. The final experiment in which animals were given salty water (1.5% NaCl) for a period of two days showed consistent results with the previous experiments for water consumption and aldosterone concentrations between C and S lambs. There was no difference in sodium excretion between C and S lambs. A novel finding was a markedly lower voluntary feed intake in S lambs than C lambs. Although mechanisms for this are unknown, it may have profound effects on the productivity of the animals. The experiments reported in this thesis provide new information of relevance to pregnant ewes grazing halophytic forages. It is apparent that they can withstand a high NaCl content typical, of a saltbush-based pasture. Further work is warranted to conclude whether high salt during pregnancy is (i) beneficial to the offspring in regards to a higher capacity to deal with excess salt under farming conditions and (ii) consistently associated with a lower voluntary feed intake of the offspring. / http://proxy.library.adelaide.edu.au/login?url= http://library.adelaide.edu.au/cgi-bin/Pwebrecon.cgi?BBID=1290752 / Thesis (Ph.D.) -- University of Adelaide, School of Agriculture, Food and Wine, 2007.
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Fetal programming of sheep for production on saltbushChadwick, Megan January 2009 (has links)
[Truncated abstract] Saltbush is one of the few types of forage that will grow on salt affected land but, sheep struggle to maintain weight when grazing saltbush mainly because of its high salt content. Therefore, a strategy to improve salt tolerance of sheep would be beneficial to the profitable use of revegetated saline land. This could be done by manipulating the dietary salt load of pregnant or lactating ewes which could 'program', or permanently alter the physiology of their offspring to allow them to cope better with a high-salt diet as adults. When rat dams consume a high amount of salt during pregnancy, the salt balance mechanisms of their offspring are 'programmed' due to suppression of the offspring's renin-angiotensin system in early development. If this occurs in offspring from ewes grazing saltbush, beneficial adaptations may be programmed in these offspring which could allow them to better cope with the high-salt content of saltbush. I tested the general hypothesis that offspring born to ewes that consumed a high-salt or saltbush diet from mid-pregnancy to early lactation would have an increased capacity to cope with salt that would allow them gain weight when grazing saltbush in later life. To test this hypothesis, I pair-fed ewes either a high-salt diet (14% NaCl) or control diet (2% NaCl) in an animal house from day 60 of gestation until day 21 of lactation. During the same period, I also conducted a field experiment where ewes grazed on saltbush (supplemented with barley) or on pasture (supplemented with lupins). ... This led to the high-salt offspring retaining more salt than control animals. In contrast, the renin activity of saltbush was consistently lower than pasture offspring which allowed them to excrete salt more rapidly. In experiment three, the saltbush offspring gained tissue weight after grazing saltbush for 8 weeks, whereas the offspring in the other three treatments lost weight. High-salt and saltbush offspring also had higher greasy fleece weights at 22 months of age than their respective control groups. Feeding saltbush to ewes from mid-pregnancy to early lactation induces physiological adaptations in their offspring that allow them to cope better with salt and gain weight when grazing saltbush as adults, supporting my hypothesis. However, contrary to expectations, the high-salt offspring did not gain weight when grazing saltbush because their physiological adaptations, such as salt retention, did not allow them to cope better with a salt load. The reason that saltbush offspring showed different adaptations to highsalt offspring is likely to be because saltbush contains not only NaCl but also high amounts of other minerals such as potassium, and other plant compounds, which may influence the adaptive responses of the offspring. This research has direct implications for farmers because it shows they could utilize otherwise unproductive saltland by grazing pregnant ewes on saltbush to 'program' their offspring to gain weight when they graze saltbush later in life.
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Carcass and eating quality of sheep grazing saltbush based saline pasture systemsk.pearce@murdoch.edu.au, Kelly L Pearce January 2006 (has links)
Forage halophytes such as saltbush (Atriplex spp) are being widely used to revegetate Australian
saline land and can also provide a medium quality fodder source. There is widespread anecdotal
evidence that sheep grazing on saltbush are leaner, tastier and juicer. This thesis investigated the
potential to produce a high quality carcass with improved eating quality from grazing sheep on
saltbush on saline land.
The first experimental chapter in this thesis details an animal house experiment investigating the
carcass, eating and wool quality and physiological responses of sheep ingesting a 60:40 dried
saltbush (Atriplex nummularia):barley grain (S+B), ration verses a 33:25:42 lupin grain:barley
grain:oaten hay ration (Control, C) for 10 weeks prior to commercial slaughter (Chapter 4).
Subsequently, two field experiments were conducted to examine the effects of grazing saltbush
on saline land compared to dry senesced pasture on carcass and eating quality of lambs
(Goomalling 2003) and hoggets (Wickepin 2004) (both chapter 6) for 14 weeks. Both chapters
demonstrated that the ingestion of saltbush resulted in significantly less fat and in the 2 field
experiments the ingestion of saltbush resulted in more lean on the carcass compared to sheep
grazing a stubble/pasture (control) ration. These are positive findings for processors as costs of
fat denudation are high so the lower the fat content and for farmers because less fat is deposited
on the carcass per unit of liveweight gain. The decreased deposition of fat was attributed to the
higher protein:energy ratio available for production, secondary compounds in saltbush and lower
circulating insulin and higher growth hormone of the S+B fed sheep compared to the control fed
sheep. Further work is needed to determine if these beneficial improvements in carcass
composition can be achieved without compromising animal production. The long term grazing of
saltbush did not result in commercially desirable hot carcass weights unless the sheep were supplemented with a high energy source such as barley. The low growth rates are attributed to a
decreased availability of energy substrates, low feed intake and increased energy output of sheep
fed high salt diets. The low energy intake of the S+B fed sheep also resulted in an a significantly
lower percentage of unsaturated fat and unchanged levels of saturated fat in the fat depots
compared to the C treatment.
Consumer taste tests conducted on meat from experiments in both chapter 4 and 6 indicated no
difference between the treatments for any of the eating quality traits assessed. This can be
considered a positive result as sheep can be finished on saltbush without any detriment to eating
quality. High vitamin E levels in the meat may have also prevented the development of rancid
flavours and aroma. It can be speculated that saltbush does not impart beneficial flavour and
aroma volatiles as previously thought; instead the high vitamin E levels inhibit off-flavour and
aroma development compared to meat from sheep grazed on dry pasture.
The long term ingestion of saltbush also resulted in significantly lower urine specific gravity
(USG), muscle dry matter and higher urine weights suggesting that the saltbush fed sheep had a
better hydration status compared to control fed sheep. However, this finding did not correspond
with higher hot carcass weight or dressing percentages. The increases in muscle fluid content of
the saltbush fed sheep were attributed to changes in body composition. The saltbush fed sheep
had a higher lean and lower fat content which corresponded with a greater body fluid content as
found in the animal house study.
Under conditions where the body composition of sheep remains the same, the use of short term
strategic feeding of components of saltbush was investigated (mimicked in the form of salt and
betaine) to reduce dehydration and subsequent reductions in carcass weight and dressing percentages (Chapter 7). Salt and or betaine were fed for 1 week either prior to a 48 h period of
water deprivation or prior to 48 h commercial slaughter process where water was available in
lairage from 24-48 h. Under both scenarios the diets did not result in improved dressing
percentages, hot carcass weights, muscle dry matter or muscle weights. The ingestion of high salt
diet prior to slaughter, did increase fluid retention in the extracellular spaces prior to slaughter
however by 48 h both groups were at a similar physiological and therefore similar hydration
status. Therefore similar levels of fluid were present in the muscles and no difference in carcass
weight or dressing percentage could be expected. An important observation from the second
experiment was that the high salt group drunk more water than the low salt fed sheep but the low
salt group consumed fluid in lairage also. The low salt fed sheep may have been encouraged to
drink water after observing the frequent drinking patterns of the high salt group.
This thesis has also shown that saltbush contains high levels of vitamin E (á-tocopherol) (193
mg/kg dry matter). As a result the concentration of á-tocopherol in plasma, liver and muscle of
the saltbush fed sheep was elevated compared to those grazing dry pasture. The high muscle
concentrations of vitamin E in the saltbush-grazed sheep resulted in improved meat colour
stability. The high vitamin E levels did not influence the drip and cooking loss of the meat
despite a decrease in the muscle dry matter of the meat. The browning of meat and increased drip
loss results in large losses to the meat industry due to value deterioration at the supermarket.
There is also great potential for the high vitamin E content in saltbush to be used for the
prevention of nutritional myopathy instead of using expensive and labour intensive synthetic
supplements.
In conclusion, this thesis has provided an insight into the carcass and eating quality of sheep
grazed on saltbush based saline pasture systems. The most significant findings were that
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Recuperação de solo salino-sódico por fitorremediação com Atriplex nummularia ou aplicação de gesso. / Reclamation of saline-sodic soil by phytoremediation with Atriplex nummularia or application gypsum.SANTOS, Monaliza Alves dos 02 March 2012 (has links)
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Previous issue date: 2012-03-02 / Arid and semi-arid environments may present salty soils, which hamper plant growth, being removed from productive process constituting degradation cores. Under these conditions, glycophyte plants can’t growth because high levels of salts hinder their metabolism, however, for halophytes this is favorable environment and these plants may represent a key to soil reclamation, extracting salts in the vegetable material produced by phytoremediation technique. The study was conducted in a saline sodic INCEPTISOL from the Cachoeira II Irrigation Perimeter, Serra Talhada (PE), with the objective of evaluating changes in soil physical and chemical properties when under cultivation with the halophyte Atriplex nummularia Lindl, compared with chemical correction with gypsum, and plant growth and production monitoring under two spacing in the pruning management every six months. Samples were taken every six months, with four soil samples (0, 6, 12 and 18 months) and three cuts in the plant 50 cm from the ground surface (6, 12 and 18 months) measuring the material produced at each pruning.The experimental design was randomized blocks, four treatments were evaluated: control (no soil management), chemical correction with gypsum (no crop) and two Atriplex nummularia cultivation, one at 1 x 1 m spacing and other at 2 x 2 m spacing, with four replications. The results of soil chemical and physical analysis revealed the contribution of gypsum application and especially the cultivation of atriplex plants in reducing the problems of salinity-sodicity and improving soil physical properties. The biometric analysis and plant tissue showed the Atriplex nummularia potential for phytoremediation, with emphasis on the 1 x 1 m spacing which presented as the best recommendation of cultivation with frequent pruning due to higher plant material yield and extraction of salt per planted area. / Ambientes sob clima árido e semiárido podem apresentar solos com elevados teores de sais, que dificultam o desenvolvimento de plantas, sendo retirados do processo produtivo e se constituindo núcleos de degradação. Nestas condições, plantas glicófitas não conseguem vegetar pelos elevados teores de sais, que dificultam seu metabolismo, entretanto, para as plantas halófitas este é um ambiente propício, podendo representar um agente recuperador do solo, com a extração de sais na matéria vegetal produzida, pela técnica da fitorremediação. O trabalho foi desenvolvido em um CAMBISSOLO salino sódico do Perímetro Irrigado Cachoeira II, Serra Talhada (PE), com o objetivo de avaliar as alterações nas propriedades físicas e químicas do solo quando submetido ao cultivo com a halófita Atriplex nummularia Lindl, em comparação com a correção química com gesso; e o monitoramento do crescimento e produção da planta sob dois espaçamentos em manejo de poda a cada seis meses. Realizaram-se amostragens semestrais, com quatro coletas de solo (0, 6, 12 e 18 meses) e três cortes na planta a 50 cm da superfície do solo (6, 12 e 18 meses), mensurando-se o material produzido a cada poda. O delineamento experimental utilizado foi blocos ao acaso, onde foram avaliados quatro tratamentos: o controle (sem nenhum manejo do solo), o de correção química com gesso (sem cultivo) e dois com cultivo de Atriplex nummularia Lindl, (espaçamentos 1 x 1 m e 2 x 2 m), com quatro repetições. Os resultados das análises químicas e físicas do solo revelaram a contribuição da aplicação de gesso e especialmente do cultivo de plantas de atriplex na redução dos problemas de salinidade-sodicidade e na melhoria nas propriedades físicas do solo. As análises biométricas e do tecido vegetal das plantas, evidenciaram o potencial fitorremediador da Atriplex nummularia Lindl, com destaque para as plantas no espaçamento 1 x 1 m, que se apresentou como a melhor recomendação de cultivo com podas frequentes, em função do maior rendimento na produção da matéria vegetal e da extração de sais por área plantada.
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Potential of Forage Kochia and Other Plant Materials in Reclamation of Gardner Saltbush Ecosystems Invaded by HalogetonSmith, Rob C. 01 May 2015 (has links)
Gardner saltbush ecosystems are increasingly being invaded by halogeton, a competitive annual weed that increases soil surface salinity and reduces plant biodiversity. This study was established on the Flaming Gorge National Recreation Area, in the Ashley National Forest near Manila, UT to evaluate the ability of forage kochia, Russian wildrye, tall wheatgrass, Indian ricegrass and Gardner saltbush, in monocultures and binary mixtures with Gardner saltbush, to establish and compete in ecosystems dominated by halogeton. A dormant seeding, with and without prior disking, was conducted to determine the ability of plant materials to establish. A spaced-plant evaluation was used to determine the competitive ability of fully established plants by measuring halogeton densities at four 10 cm intervals (10-20, 20-30, 30-40, and 40-50 cm) distal from transplants. Gardner saltbush, tall wheatgrass, and Indian ricegrass did not establish or persist beyond the first year in either study. Conversely, Russian wildrye and forage kochia established and persisted, with Russian wildrye establishment higher (P ≤ 0.05) in the disked treatment (4.5 and 1.7 plants m-2, respectively) and no-till favoring (P ≤ 0.05) forage kochia establishment (2.0 and 0.8 plants m-2, respectively). Spaced-plants of these species reduced halogeton by 52% relative to the control. Furthermore, by the second year of evaluation, the competitive ability of Russian wildrye and forage kochia had extended to 50 cm distal from transplant. Transplant survival and halogeton frequency were highly correlated (r = -0.67, P = 0.0001), indicating the important of persistence. These results suggest that Russian wildrye and forage kochia can establish, persist, and compete with halogeton, thereby providing an opportunity for reclamation of halogeton-invaded areas. Conversely, direct restoration to Gardner saltbush and Indian ricegrass does not appear likely
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Fall Regrowth of Crested Wheatgrass and Fourwing SaltbushMohammad, Noor 01 May 1981 (has links)
During 1980-81, studies with crested wheatgrass (Agropyron desertorum) and fourwing saltbush (Atriplex canescens) were conducted in controlled environment growth chambers as well as under field conditions to achieve the following objectives:
1. To determine the effect of nitrogen fertilizer on the water use efficiency.
2. To determine the effects of various temperature, water stress and nitrogen treatments on the productivity, nitrogen content and carbohydrate reserves.
3. To determine the effects of N fertilization on fall and spring regrowth.
Crested wheatgrass and fourwing saltbush plants were maintained in three growth chambers for 60 days under three temperature regimes (11/7, 19/7 and 27/7 C), two soil moisture stress regimes (-0.3 bars and -15 bars) and three N fertilizer levels (0, 50 and 100 kg of N/ha).
During the study, tranpiration and plant biomass data were recorded.
During the first week of September, 1980, crested wheatgrass and fourwing saltbush pastures at Nephi, Utah, were subjected to three nitrogen fertilizer levels (0, 50 and 100 kg N/ha). After 60 days the fall regrowth was clipped. In the first week of June 1981 spring regrowth of both species was measured. In the fall of 1981, a second experiment was laid out at Nephi where crested wheatgrass and fourwing saltbush plants were subjected to three soil moisture regimes (dry, medium and wet) and three nitrogen fertilizer levels. At the end of a 60 day study period, dry matter yield, root distribution, water content and soil samples at different incremental soil depths were collected.
Under controlled environment conditions, the water use efficiency of both species was six percent more with the application of a moderate amount of nitrogen (50 kg/ha). A high temperature regime (27/7 C) and a high water stress regime (-15 bars) increased the water use efficiency of plants by eight and six percent respectively.
Results of the growth chamber experiment revealed that nitrogen fertilization had a significant effect on plant biomass, nitrogen percent and total nonstructual carbohydrate reserves of crested wheatgrass and fourwing saltbush. The data further suggested that nitrogen fertilization can substitute for the adverse effects of low temperature and low soil moisture on plant growth.
Nitrogen fertilization during fall increased plant biomass, nitrogen percent and total nonstructural carbohydrate reserves in crested wheatgrass and fourwing saltbush. Fall fertilization did not reduce spring regrowth.
It is inferred that under limited soil moisture and low temperature during the fall growing season, a moderate amount of nitrogen fertilizer (50 kg N/ha) may increase the forage availability and water use efficiency of crested wheatgrass and fourwing saltbush to the level of plants maintained at moderate temperature and adequate soil moisture. Nitrogen fertilization (50 kg N/ha) of crested wheatgrass and fourwing saltbush during fall does not reduce plant nitrogen percent or carbohydrate reserves which may limit spring regrowth.
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Leaf-litter and microsite on seedling recruitment in an alley-planted E. sargentii and Atriplex spp. saline agricultural systemFarrell, Claire January 2008 (has links)
[Truncated abstract] In order to assess the sustainability of mixed plantings on saline land, this thesis examined the importance of leaf-litter trapping and microsites on recruitment in a salt affected alley-belted (tree/shrub) agricultural system in Western Australia. Located in the low rainfall region (MAR <330 mm) of the wheatbelt, the 60 ha site consists of concentric rows of Eucalyptus sargentii trees with mounded (6 - 11 cm high) 10 -15 m inter-rows of Atriplex spp. Sustainability of this system and fulfilment of productive and ameliorative functions is dependant on successful recruitment (perennials). Although the present study site was conducted on farmland in a Mediterranean-type climate, low annual rainfall and spatial arrangement of perennial shrubs and trees, allow useful comparisons to be made with naturally occurring banded semi-arid systems and vice-versa. Of key interest were leaf-litter redistribution and trapping by tree and shrub rows and whether litter-cover/microsites facilitated/interfered with seedling recruitment (establishment, growth and survival). Litter from the tree row, redistributed by prevailing winds and rain, accumulated adjacent to saltbush seeding mounds, creating a mosaic of bare and littered areas across the site (total litter 10 t/ha over 22 months). Accumulated litter was hypothesized to differentially influence seasonal soil abiotic parameters (depending on litter-cover density) including; salinity, water availability, infiltration rates, water repellency and temperature. These abiotic conditions were also hypothesized to vary between tree and shrub microsites. Biotically, recruitment at this site was also hypothesized to be determined by interactions (positive and negative) between perennial components and understorey annuals/perennial seedlings. Accumulation of litter and resultant heterogeneity was influenced by shrub morphology, microtopography, wind direction and distance from litter source, with increased litter on the leeward sides of hemispherical Atriplex undulata shrubs and shrubs closest to tree rows. ... The importance of tree/shrub microsites varied seasonally, with no influence in winter due to moderate temperatures and increased water availability. In warmer months saltbush mid-row microsites were most favourable for seedling recruitment due to moderate litter-cover; reducing salinity, temperatures and increasing infiltration; and reduced root-competition/shading by the tree row. Tree microsites also directly inhibited seedling recruitment through increased salinities and water repellency. However, trees also indirectly facilitated recruitment in adjacent areas through provision of leaf-litter. As litter-trapping and recruitment patterns at this site mirror those found in semi-arid natural and artificial systems, the results of this study provide useful insights into creating appropriate mimics of low rainfall natural banded woodland and chenopod shrublands. Saltbush seeding mounds, shrub morphology and litter were key components for litter trapping and recruitment heterogeneity at this site. In this tree/shrub alley planting, where litter quantities directly influence vegetation cover densities, future saline plantings need to consider appropriate tree/shrub row spacings and orientation for efficient resource (seeds, litter and water) capture.
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