ライフサイエンスコーパス: temperate zone

1 e elevationally restricted than those in the temperate zone.

2 of Pooideae out of the tropics and into the temperate zone.

3 common in tropical avifaunas but rare in the temperate zone.

4 compared with a similar area cleared in the temperate zone.

5 species diversity in the tropics than in the temperate zone.

6 nd improved yields for tropical maize in the temperate zone.

7 brate recruitment in the tropics but not the temperate zone.

8 ts in critical ecological regions beyond the temperate zone.

9 lose to that seen in modern humans living in temperate zones.

10 us in wetlands from the subtropical than the temperate zones.

11 ant role as maize spread from the tropics to temperate zones.

12 nd acute effects on stillbirth risk, even in temperate zones.

13 and in accordance with previous studies from temperate zones.

14 ion of taxa within the northern and southern temperate zones.

15 peratures can influence insects' survival in temperate zones.

16 lutionary selection in populations living in temperate zones.

17 f temperature change on species that inhabit temperate zones.

18 underlying soil is lacking, particularly in temperate zones.

19 into the annual rings formed in trees of the temperate zones.

20 in the tropics rather than heightened in the temperate zones.

21 nth drought was only observed in tropical or temperate zones.

22 dent plants and for plants found in Asia and temperate zones.

23 In the temperate zone, AC has strong potential for climate chan

24 most important disease vector mosquitoes in temperate zones across the northern hemisphere, responsi

25 cays with geographic distance fastest in the temperate zone, again consistent with environmental filt

26 ival and recruitment) using 31 datasets from temperate zone amphibian populations (North America and

27 at predation is (1) strongest in or near the temperate zone and (2) negatively correlated with oceani

28 n models based on EF(a) or EF(b) for global, temperate zone and subtropical zone datasets, a power fu

29 s and direct observation of predators in the temperate zone and tropics.

30 e is the most common vector-borne disease in temperate zones and a growing public health threat in th

31 ian dandelion (Taraxacum koksaghyz) grows in temperate zones and produces large amounts of poly(cis-1

32 f observations), with N limitation mainly in temperate zones and pronounced P limitation in tropical

33 (3 FDPs in tropics, 5 in subtropics and 5 in temperate zone) and compared the rates of species discri

34 ytochrome b was particularly variable in the temperate zone, and cytochrome oxidase I was notably mor

35 (Avena sativa), predominate in the northern temperate zone, and it is hypothesized that their radiat

36 Many temperate zone animals exhibit seasonal rhythms in physi

37 Temperate zone animals exhibit seasonal variation in mul

38 Temperate zone animals time the onset of reproductive ev

39 Animals living in temperate zones anticipate seasonal environmental change

40 n plant communities from the tropical to the temperate zone are lacking.

41 f reforestation on warming and/or cooling in temperate zones are less certain.

42 nal assemblages in the northern and southern temperate zones are less phylogenetically diverse than e

43 hat life history patterns of many species of temperate-zone bats, coupled with sufficiently long incu

44 ropical clades, with the colonization of the temperate zone being associated with key adaptations to

45 Tropical and temperate zones both show impacts of glacial cycles, the

46 In the temperate zones, both photoperiod and temperature fluctu

47 iology differs substantially in tropical and temperate zones, but estimates of seasonal influenza mor

48 s can reduce the uncertainty of tropical and temperate zone carbon flux estimates.

49 idence that beak shape evolves faster in the temperate zone, consistent with the empty niches hypothe

50 rn distributions; and colonization routes in temperate zones during postglacial climatic amelioration

51 s of billions of nonhardy insects to exploit temperate zones during summer represent a sink from whic

52 ore subject to invasion; the latest Cenozoic temperate zones evidently received more invaders than th

53 more of the following processes: out of the temperate zone, evolving in situ, or through montane pre

54 er genus (surrogates of clades) peaks in the temperate zone for both families contrasting with data f

55 r N demands, limits the productivity of many temperate zone forests and in part determines ecosystem

56 r Mississippi Basin, one of the most diverse temperate-zone freshwater faunas on Earth, and 3D geomet

57 or the utilization of this tropical grass in temperate zone grain and bioenergy production.

58 richness is much higher in tropical than in temperate zone habitats.

59 The reason why many immigrant children in temperate zones have vitamin D deficiency is unclear.

60 vation has expanded greatly from tropical to temperate zones; however, its sensitivity to chilling of

61 pecies in nine forests from tropical to cold-temperate zones in China.

62 bad, India, and Sri Lanka) and two from more temperate zones in the north (Nepal and Burma).

63 In the north temperate zone, increased nest failure along edges of fo

64 dity in tropical regions; however, unlike in temperate zones, influenza in the tropics is not strongl

65 biology curricula view research mostly via a temperate-zone lens.

66 increases significantly more closely than in temperate-zone montane species.

67 f macroinvertebrate assemblage structures in temperate zones of North and South America, with those a

68 rvational evidence that reforestation in the temperate zone offers opportunities for local climate mi

69 ll tropical hypervolume, indicating that the temperate zone permits a wider range of trait combinatio

70 of UFPs from diesel vehicle exhaust by nine temperate-zone plant species, in wind tunnel experiments

71 are largely based on studies of short-lived, temperate-zone plants.

72 Throughout the temperate zones, plants face combined drought and heat s

73 rus are globally distributed in tropical and temperate zones, providing the opportunity for CHIKV to

74 quivalent in magnitude to those in the north temperate-zone regions, and are in fact far greater than

75 assic case of maladaptation by an inflexible temperate zone society extending into the arctic and col

76 or fitness trade-offs across environments in temperate zone species.

77 Temperate-zone species have responded to warming tempera

78 operiod is an environmental cue used by many temperate-zone species to regulate their reproductive ti

79 warming temperatures even more strongly than temperate-zone species, but this prediction has yet to b

80 responses of tropical species with those of temperate-zone species, finding that average upslope shi

81 Greater ecological opportunity in the temperate zones, stemming from less saturated communitie

82 of tropical clades and their entry into the temperate zone suggest that OTT events are rare on a per

83 hically restricted species to persist in the temperate zone, suggesting that past differences in geog

84 certain regions, especially islands and the temperate zone, suggesting that species-rich mainland an

85 fungal diversity is significantly higher in temperate zones than in the tropics, with distance from

86 d catchments which are narrow in humidity or temperate zone, the hydrological responses to structural

87 On the basis of studies conducted in the temperate zone, the intake of vitamin D3 needed to maint

88 In temperate zones, the primary environmental cue driving s

89 Located in aggrading stands in the temperate zone, they have provided a strong foundation f

90 milar across latitudes or more potent in the temperate zone, thus calling into question multiple hypo

91 value in the conservation and restoration of temperate zone tidal wetlands through climate change mit

92 ean spanning 30 degrees of latitude from the temperate zone to the tropics.

93 Fagaceae dominates forests from the northern temperate zone to tropical Asia and Malesia, where it re

94 ll-sampled faunas that dominated tropical-to-temperate zones to the north and south.

95 However, that analysis was limited to young, temperate zone tree plantations, and its applicability t

96 imate in shaping demography, particularly in temperate zone tree species with large latitudinal range

97 ecent speciation are generally faster in the temperate zone, whereas rates of molecular evolution are

98 The data mainly cover top soil and temperate zones, whereas only few data from tropical reg

99 in dry zones but weak or null in tropical or temperate zones, whereas that for 6-month drought was on

100 ge (RT) for a long time (>10 years), in warm temperate zones with fine-textured soils, and in soils w

101 should influence the leaf-out strategies of temperate zone woody species, with high winter chilling

102 led sorghum's utilization as a grain crop in temperate zones worldwide.