ライフサイエンスコーパス: crop production

1 ss talk for improvement of plant fitness and crop production.

2 ting effects on pollination and, ultimately, crop production.

3 e male sterility system applicable to hybrid crop production.

4 ting potential regional impacts of bioenergy crop production.

5 ral lands as a nutrient and water source for crop production.

6 sideration of the role of residual soil P in crop production.

7 proximately one-third of the world's primary crop production.

8 nd plant-pathogen coevolution and to improve crop production.

9 eties have contributed to large increases in crop production.

10 ht is a major abiotic stress factor limiting crop production.

11 way that gene function can affect commercial crop production.

12 ulatus), poses a serious threat to sustained crop production.

13 d ecosystem services with minimal impacts on crop production.

14 yet unexplored trait to be investigated for crop production.

15 he impacts of general warming temperature on crop production.

16 only by the amount of the area taken out of crop production.

17 productivity to meet future demands in food crop production.

18 lications for plant disease epidemiology and crop production.

19 l in the natural environment and sustainable crop production.

20 ave partially or completely damaged regional crop production.

21 rthologs suggests their potential utility in crop production.

22 ran Africa (SSA) requires enhancement of its crop production.

23 eeders to fine tune the breeding process for crop production.

24 nd marginal habitats that are unsuitable for crop production.

25 of biomass for bioenergy relies on low-input crop production.

26 e levels of inorganic fertilisers to promote crop production.

27 ide, glyphosate, is a major threat to global crop production.

28 ertilizer use efficiency and is critical for crop production.

29 ve knowledge of ecological factors affecting crop production.

30 s highlight the importance of ENSO to global crop production.

31 t to herbicide sustainability and thus world crop production.

32 identify potential risk factors during their crop production.

33 2013 and 2018 and some will likely return to crop production.

34 ens are estimated to be 12% of the potential crop production [1], despite the continued release of ne

35 70-1,200 teragrams P) is required to achieve crop production according to the various Millennium Ecos

36 quantitative traits with great importance in crop production, adaptation, and evolution.

37 nimal slurry is highly important to optimize crop production and avoid environmental pollution when s

38 ation [7-10], constitute a serious threat to crop production and biodiversity [11].

39 Total crop production and crop diversity were the strongest ph

40 This could have implications for both crop production and Earth system models, including proje

41 We investigated changes in biofuel crop production and grassland land covers surrounding ap

42 Here, we use data on crop production and insecticide use from over 100,000 fi

43 d application of agrochemicals due to higher crop production and poleward expansion of potential arab

44 r depletion (GWD) rate globally, threatening crop production and sustainability of groundwater resour

45 rmines germination timing and contributes to crop production and the adaptation of natural population

46 Despite overall tradeoffs between crop production and water quality, some locations were p

47 re synergies, but tradeoffs occurred between crop production and water quality.

48 In view of the currently increasing crop production, and also of corn as a renewable energy

49 egetative carbon stocks, evapotranspiration, crop production, and household food security.

50 availability is a significant constraint to crop production, and increasing drought tolerance of cro

51 tion, better integration of animal manure in crop production, and matching N and P supply to livestoc

52 al functions: controlling climate, enhancing crop production, and remediation of environmental contam

53 o prevention of pre-harvest sprouting during crop production, and therefore contributes to translatio

54 Improvements in nitrogen use efficiency in crop production are critical for addressing the triple c

55 and availability of large areas unusable for crop production are ideal locations for large solar inst

56 droughts, floods and extreme temperature on crop production are yet to be quantified.

57 ented in this study provides improved LCA of crop production at the catchment scale.

58 orus fertilizer required to intensify global crop production atop phosphorus-fixing soils and achieve

59 the capacity of Iran's land for sustainable crop production based on the soil properties, topography

60 ater acquisition, is a serious limitation to crop production, because up to one-half of the world's p

61 Drought stress is a major threat to crop production, but effective methods to mitigate the a

62 the focus has shifted to optimizing organic crop production by improving plant nutrition, weed contr

63 d for the purpose of verification of organic crop production by multiresidue analysis for the presenc

64 possible to address many important issues in crop production by the identification and manipulation o

65 Modern crop production calls for agrochemicals that prime plant

66 patterns presents significant challenges to crop production consistency and yield stability.

67 Statistics from densely monitored crop production, consisting primarily of corn and soybea

68 le tool and has made a significant impact on crop production, development of a biotech industry and t

69 asing attention of agronomists to suboptimal crop production environments.

70 ritical due to its complex interactions with crop production, especially in India.

71 rter of land, water, and fertilizer used for crop production, even though resources and environmental

72 ochar may enhance soil fertility, increasing crop production for the growing human population, while

73 Crop production for vegetable oil in the northern latitu

74 is regulation has important consequences for crop production, for example, in the developing wheat gr

75 nterventions geared towards buffering future crop production from climate variability.

76 ions from large-scale ecosystem modelling to crop production: homeostatic water losses justify simple

77 ates is one of the keys to increasing future crop production; however, this typically requires additi

78 al projects and policies intended to support crop production (i.e. reconstruction of low yield farmla

79 lost were responsible for 3-4% of worldwide crop production in 2000.

80 Here, we project global demand for crop production in 2050 and evaluate the environmental i

81 nd manure and to estimate P requirements for crop production in 2050.

82 cation of the two methods to a case study of crop production in a catchment in France showed that, co

83 (N) availability is a primary constraint for crop production in developing nations, while in rich nat

84 illustrate the method using a case study of crop production in East Africa, but the underlying HSMs

85 orld that renders prohibitive vegetables and crop production in general.

86 mperatures, potentially resulting in reduced crop production in many key production regions.

87 ve to understand the impacts of pathogens on crop production in order to minimize crop losses and max

88 overexploitation could significantly impact crop production in the United States because 60% of irri

89 rnational seed trade following cucurbit seed crop production in tropical or subtropical countries exp

90 s (P) availability is a major constraint for crop production in tropical regions.

91 ociated with agricultural expansion of large crop production into previously unfarmed land.

92 As livestock and crop production involves interventions such as managemen

93 Increasing crop production is essential for securing the future foo

94 norganic orthophosphate (Pi), meaning global crop production is frequently limited by P availability.

95 that, while the contribution of wild bees to crop production is significant, service delivery is rest

96 environmental life cycle assessment (LCA) of crop production is the nonlinearity between nitrogen (N)

97 al for resource-efficient and cost-effective crop production; it is widely accepted as a critically i

98 om dairy farms is a common soil amendment in crop production, its impact on the soil microbiome and r

99 At the crop production level, the example of corn grain shows t

100 on are among the causal factors for shits in crop production location and mixes, with some crops bein

101 to find solutions for the key constraints to crop production, many of which center around abiotic and

102 scenarios for supplying nitrogen to increase crop production (mineral fertilizer, herbaceous legume c

103 Crop production needs to increase to secure future food

104 xperiments more than 20 years old that study crop production, nutrient cycling, and environmental imp

105 Among the crops, production of cereals had the largest contributio

106 ity is one of the major limiting factors for crop production on acid soils that comprise significant

107 inum (Al) toxicity is a major constraint for crop production on acid soils which compose approximatel

108 Al toxicity is the primary limitation for crop production on acid soils, which make up 50% of the

109 e Al toxicity, a major abiotic constraint to crop production on acidic soils.

110 forests, soil carbon dynamics, and bioenergy crop production on degraded/abandoned agricultural land.

111 osts for US farmers and may even destabilize crop production over time.

112 ternative fumigants, modification of current crop production practices to accommodate their use, and

113 re we provide a global assessment of biofuel crop production, reconstruct global patterns of biofuel

114 is a cornerstone of floriculture and nursery crop production: strategies include sanitation, clean st

115 cially in drought-prone regions where annual crop production suffers from episodic aridity.

116 agricultural activity, such as expansion of crop production (sugarcane and maize), unintentional dis

117 ll be relied upon heavily in U.S. high-value crop production systems in a world without methyl bromid

118 Most crop production systems in the United States are charact

119 gement of soilborne pests in some high-value crop production systems is preplant fumigation with mixt

120 nventory of N and P budgets in livestock and crop production systems shows that in the beginning of t

121 Included are case studies of U.S. high-value crop production systems to demonstrate how nematode mana

122 health is crucial for developing sustainable crop production systems.

123 pin the challenges of water availability and crop production that are expected to unfold over the nex

124 center of a crisis in water availability and crop production that is expected to unfold over the next

125 etic pesticide for insect pest management in crop production, thereby, reducing threats to natural ec

126 climate change affects pollinator-dependent crop production, this will have important implications f

127 (development rate) is a major determinant of crop production time, yet the genetic control of this pr

128 ld population, vulnerability of conventional crop production to climate change, and population shifts

129 re to reduce the use of pesticides in modern crop production to decrease the environmental impact of

130 of melatonin-enriched plants for increasing crop production under a variety of unfavorable environme

131 key plant trait with wide usage in managing crop production under limited water conditions.

132 cenarios allow for a substantial increase in crop production, using an area 1.5-2.7 times the current

133 Crop production was the major source of energy, contribu

134 Linking crop production with livestock to maximal uses of by-pro

135 ew of current challenges such as sustainable crop production with reduced fertilizer input or in reso

136 wetland expansion, indicating both a risk to crop production within the Midwest Corn Belt and an oppo

137 fficient water is a major limiting factor to crop production worldwide, and the development of drough

138 is the nitrogen fertilizer most utilized in crop production worldwide.

139 ress is a major environmental constraint for crop production worldwide.

140 freezing temperatures substantially reduces crop production worldwide.

141 lant viral infections decrease seriously the crop production yield, boosting the demand to develop ne