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1 anisms are a crucial part of the terrestrial biosphere.
2 ochemical activity in a dynamic sub-seafloor biosphere.
3 emistry, biogeochemical cycles, and the deep biosphere.
4 bon lost from the atmosphere and terrestrial biosphere.
5 se of cellular receptors among phages in the biosphere.
6 radioactive waste and incorporation into the biosphere.
7 ility to influence critical functions of the biosphere.
8 the Earth's weather, climate, chemistry, and biosphere.
9 ssociated with an extensive, deep subsurface biosphere.
10 ncrease having profound consequences for the biosphere.
11 unusual ecosystem isolated from the surface biosphere.
12 sure of persistent lead contamination in the biosphere.
13 e text] due to the ocean and the terrestrial biosphere.
14 al and widespread changes in the terrestrial biosphere.
15 impact the functioning of ecosystems and the biosphere.
16 represents the biophysical limit of Earth's biosphere.
17 on the evolution of cooperation in the early biosphere.
18 onredundant sequences present throughout the biosphere.
19 uptake and release of CO2 by the oceans and biosphere.
20 f-amplification and self-organization of the biosphere.
21 ofound influences on carbon (C) cycle in the biosphere.
22 fe and sustainability of the deep subsurface biosphere.
23 es the flow of matter and energy through the biosphere.
24 phere, shallow lithosphere, hydrosphere, and biosphere.
25 ng free-living N fixation in the terrestrial biosphere.
26 a large portion of nitrogen fixation in the biosphere.
27 to free-living N fixation in the terrestrial biosphere.
28 nd related capsidless mobile elements in the biosphere.
29 lar handedness, or homochirality, across the biosphere.
30 cesses that govern our interactions with the biosphere.
31 mately supporting methanogenesis in the deep biosphere.
32 e specialized for survival in the subsurface biosphere.
33 nsfer mechanisms from the hydrosphere to the biosphere.
34 evolutionarily viable in today's terrestrial biosphere.
35 face chemistry and the low oxygen primordial biosphere.
36 evolution of the hydrosphere, atmosphere and biosphere.
37 jor provider of energy-rich compounds in the biosphere.
38 radioactive contamination to the surrounding biosphere.
39 of the highest stores of soil carbon in the biosphere.
40 nd below-ground processes in the terrestrial biosphere.
41 ability to cause adverse consequence to the biosphere.
42 tral to our understanding of the terrestrial biosphere.
43 bly supplying significant energy to the deep biosphere.
44 ycle process that fuels the deep subseafloor biosphere.
45 ny microbial cells as the marine sedimentary biosphere.
46 lant N and P in a progressively CO2-enriched biosphere.
47 phages, the largest group of viruses in the Biosphere.
48 oic and the Cambrian emergence of the modern biosphere.
49 cycling within the largest ecosystem of the biosphere.
50 played a key role in the development of the biosphere.
51 be considered when modeling the terrestrial biosphere.
52 e of events leading to global changes in the biosphere.
53 severely limiting the size of the primordial biosphere.
54 underexplored reservoir of diversity in the biosphere.
55 ments at scales from local ecosystems to the biosphere.
56 icant effect on the biogeography of the rare biosphere.
57 bolic strategies employed by the subseafloor biosphere.
58 er view of the biosynthetic potential of the biosphere.
59 varying contribution of CO(2) from the urban biosphere.
60 volcanoes, marine biosphere, and terrestrial biosphere.
61 bility to monitor and measure changes in the biosphere.
62 erstone of atmospheric CO(2) fixation by the biosphere.
63 al component of biogeochemical cycles in the biosphere.
64 on of estrogens into androgens occurs in the biosphere.
65 ionary transitions in the history of Earth's biosphere.
66 ial to transform energy flow through Earth's biosphere.
67 nts necessary for the maintenance of Earth's biosphere.
68 stimate the scale of the human impact on the biosphere.
69 orld and produces most of the biomass in the biosphere.
70 tion of rare species referred to as the rare biosphere.
71 that oxidative stress actually plays in the biosphere.
72 rgest organic matter pool in the terrestrial biosphere.
73 ound on the total information content in the biosphere: 5.3 x 1031 (+/-3.6 x 1031) megabases (Mb) of
74 as been the dramatic reshaping of the global biosphere, a transformation whose early origins are incr
76 t limitation is pervasive in the terrestrial biosphere, although the relationship between global carb
77 n is a global problem threatening the entire biosphere and affecting the life of many millions of peo
78 on the cycling flux between the terrestrial biosphere and atmosphere and infers a residence time of
79 regulating CO2 exchange between the Earth's biosphere and atmosphere, and in determining how carbon
85 aftermaths suggests strong ties between the biosphere and geosphere, and a previously undescribed ma
86 e carbon storage capacity of the terrestrial biosphere and hence the land-based mitigation potential.
90 al history, the relative contribution of the biosphere and its chemical fingerprints on Earth's devel
92 en sequestration of POC from the terrestrial biosphere and oxidation of rock-derived (petrogenic) org
93 ls in the coevolution of the lithosphere and biosphere and provides a step toward understanding the f
94 extent of a poorly quantified rare microbial biosphere and refute recent predictions that there exist
97 model to quantify CH4 fluxes from the marine biosphere and to examine the capacity of biogenic CH4 to
98 bial communities play essential roles in the biosphere and understanding the mechanisms underlying th
99 atmosphere pool, provides energy to the deep biosphere, and on geological timescales drives the oxyge
101 he global N cycle as much of the terrestrial biosphere appears to be experiencing reduced N availabil
102 ographical patterns, and members of the rare biosphere are generated, and suggest allopatric speciati
105 anged between the atmosphere and terrestrial biosphere, are necessary to better understand the role o
106 bial life strategies in the present-day deep biosphere as well as early life on Earth and beyond.
107 r developmental program populated the marine biosphere at least a billion years before the Cambrian E
108 ent, however reconciling the response of the biosphere (at local and nonlocal scales) to potential CA
111 oves organic carbon (OC) from the short-term biosphere-atmosphere carbon (C) cycle, and therefore pre
112 t of the warmer spring and summer drought on biosphere-atmosphere carbon and water exchange in 2012.
113 eographic and temporal variability in Amazon biosphere-atmosphere carbon exchange and that is minimal
114 ed to further improve modeled projections of biosphere-atmosphere CO2 exchange in a changing climate.
115 , we elucidate key processes controlling the biosphere-atmosphere exchange of H2 and raise new questi
118 important considerations for modeling future biosphere-atmosphere interactions and for understanding
121 proach to ecosystem ecology, using microbial biospheres, based on a combination of theory and the rep
123 on is respired back to carbon dioxide in the biosphere, but a small fraction escapes remineralization
124 thesis supplies organic carbon to the modern biosphere, but it is uncertain when this metabolism orig
125 are among the most effective C sinks of the biosphere, but methane (CH(4)) emissions can offset thei
126 Bacteriophages play critical roles in the biosphere, but their vast genomic diversity has obscured
127 , the gatekeeper of carbon fixation into the biosphere, by its molecular chaperone Rubisco activase (
130 und by at least ca. 20%, supporting a marine biosphere-climate link through sea ice melt and low alti
133 quantitative evidence for the role of major biosphere components in the evolution of upper continent
134 s, and viewed to significantly contribute to biosphere cycling of methane, a potent greenhouse gas.
135 have been interpreted as evidence for a deep biosphere dating back in time through the earliest perio
137 storage of organic carbon in the terrestrial biosphere directly affects atmospheric concentrations of
138 s the polygeonamides produced from deep-rock biosphere DNA, contain the highest numbers of D-amino ac
140 % difference implemented in most present-day biosphere emissions models (i.e., homogeneous emissions)
141 s that the surface/atmospheric abundances of biosphere-essential materials will likely be variable.
142 s the global transition to a more productive biosphere, evidenced by increased availability of food a
143 in air-surface processes (whether atmosphere-biosphere exchange or aerosols), as well as the extent o
144 ere we quantify the response of tropical net biosphere exchange, gross primary production, biomass bu
146 onal and global models to assess the climate-biosphere feedbacks and improve predictions of the futur
147 ng terrestrial albedo, potentially impacting biosphere feedbacks on past and future climate, and call
149 mospheric inverse systems, we estimated land biosphere fluxes (natural, land-use change and fires) ba
151 ment represents an exceptional record of the biosphere following the crucial changes that occurred in
153 ns for understanding the extremes of Earth's biosphere; for understanding the potency of disease-caus
154 ing and ozone production, and influences the biosphere from ecosystem-level processes through to the
155 equences for our understanding of changes in biosphere function since the Late Pleistocene and of the
159 rigin and may be evidence that a terrestrial biosphere had emerged by 4.1 Ga, or approximately 300 My
160 This suggests that a modern-style marine biosphere had rapidly emerged during the latest Ediacara
163 taxonomically and functionally diverse rare biosphere has the potential to increase functional redun
164 ny ways to conceptualize the recovery of the biosphere; here, we focus on the global recovery of spec
167 ere present typically as members of the rare biosphere in metagenomic data from uncontaminated field
168 etter understand the role of the terrestrial biosphere in mitigating anthropogenic CO(2) emissions.
170 findings first indicate that the living rare biosphere in the aquifer system has the metabolic potent
171 providing energy to the overlying subsurface biosphere in the forearc regions of convergent margins.
174 Earth's microbial biomass exists in the deep biosphere, in the deep ocean, and within the Earth's cru
176 nic energy fuels the human domination of the biosphere, including conversion of natural habitats to a
178 s could have supported a substantial aerobic biosphere, including nitrification and methanotrophy, an
179 verse forests of the temperate region of the biosphere, including those of hardwood, conifer and mixe
181 improved model representation of atmosphere-biosphere interactions in a changing global climate.
188 Recent studies have revealed that the rare biosphere is not merely an inactive dormant population b
189 easonal pattern of uptake by the terrestrial biosphere is recorded in fluorescence and the drawdown o
190 ological route for nitrogen gas entering the biosphere is reduction to ammonia by the nitrogenase enz
191 a major pathway by which fixed carbon in the biosphere is returned to the atmosphere, yet there are l
193 eased from the geosphere fuel chemosynthetic biospheres is fundamental to understanding the distribut
194 ant hydraulics into the Community Atmosphere Biosphere Land Exchange (CABLE) land surface model.
195 hat are of fundamental importance across the biosphere, leading to a thorough understanding of biodiv
198 g to implications for the sustenance of deep biosphere microbial communities and their potential role
200 nd land-use scenario, and on the terrestrial biosphere model used, highlighting the importance of imp
201 ge observations, combined with a terrestrial biosphere model with explicit modeling of forest regrowt
203 exchange and that is minimally influenced by biosphere model-based first guesses of seasonal and annu
205 luded in coupled carbon-nitrogen terrestrial biosphere models (CN-TBMs) and are consistent with CN-TB
206 vironmental forcings using three terrestrial biosphere models (ED2, IBIS, and JULES) forced by three
208 However, given that most global terrestrial biosphere models (TBMs) do not include the C cost of nut
209 resentation of photosynthesis in terrestrial biosphere models (TBMs) is essential for robust projecti
211 hesis models are at the heart of terrestrial biosphere models (TBMs) simulating the daily, monthly, a
212 otosynthesis estimates from nine terrestrial biosphere models (TBMs), to quantify and assess photosyn
213 ts with the output of a suite of terrestrial biosphere models (TBMs), we suggest that within the curr
214 cated as important for advancing terrestrial biosphere models (TBMs), yet to date, such models have o
217 either current physiological nor terrestrial biosphere models adequately describe its short-term temp
219 al remote-sensing techniques and terrestrial biosphere models fail to reproduce the seasonality of GP
220 emble of demographically-enabled terrestrial biosphere models following an independent reconstruction
221 ionships, the next generation of terrestrial biosphere models may need to consider how limitations in
222 testing critical assumptions in terrestrial biosphere models that are being used to project future i
223 ) to increase representation of processes in biosphere models that could contribute to fill the budge
224 here we tested the ability of 10 terrestrial biosphere models to reproduce the observed sensitivity o
225 Simulations of photosynthesis by terrestrial biosphere models typically need a specification of the m
226 has underlain the development of terrestrial biosphere models used in climate prediction and of remot
227 into next-generation trait-based terrestrial biosphere models would improve predictions of global pho
228 timates have relied heavily on process-based biosphere models, despite lack of model agreement with p
230 hydraulics within terrestrial ecosystem and biosphere models, which will enhance our ability to make
242 in the health and disease of the terrestrial biosphere, much less is known about the function and pot
243 determined and simplified systems, microbial biospheres offer the opportunity to test and develop str
244 owever, our understanding of the terrestrial biosphere on a global scale is subject to considerable u
245 indicates that potential impacts of the deep biosphere on CO2 fate and transport should be taken into
247 ort the plausible antiquity of a terrestrial biosphere populated by cyanobacteria well before the GOE
248 ogenic environmental element that enters the biosphere primarily from geochemical sources, but also t
249 ion rates, this information content suggests biosphere processing speeds exceeding yottaNOPS values (
252 elative to the 2011 La Nina, the pantropical biosphere released 2.5 +/- 0.34 gigatons more carbon int
255 ecosystems have had on the evolution of the biosphere requires an understanding of modern lithificat
257 ey were located within the Monarch Butterfly Biosphere Reserve, but were not influenced by disease ra
264 these data, we estimate a mean Chinese land biosphere sink of -1.11 +/- 0.38 petagrams of carbon per
266 versification of Pinnularia borealis, a rare biosphere soil diatom species complex, using a global sa
267 served features of change towards 'corporate biosphere stewardship', with significant potential for u
268 considered one of the most complex microbial biospheres studied to date, hosting thousands of bacteri
271 ice, snow cover, permafrost, and terrestrial biosphere that arise after a certain global temperature
272 rviving in the nutrient-poor, lithified deep biosphere that include the recycling of organic matter.
273 ic carbon cycling and energy transfer in the biosphere that is mediated by a wide range of streambed
274 energy can be harnessed by a chemosynthetic biosphere that permeates hydrothermal regions on Earth.
276 ttention has been given to the study of deep biospheres, their role in geochemical cycles, and their
278 nderstanding the response of the terrestrial biosphere to climatic change and other anthropogenic for
279 diversity advances our understanding of the biosphere to conserve more biodiversity in the face of l
280 spheric haze was a transient response of the biosphere to increased nutrient availability, with metha
283 otected ecosystems may have allowed the deep biosphere to thrive, despite violent phases during Earth
284 and population declines threaten to push the biosphere toward a tipping point with irreversible effec
285 evidence now supports the presence of a deep biosphere ubiquitously distributed on Earth in both terr
286 Given the ubiquity of complex systems in the biosphere, understanding the evolution of complexity is
287 global models of the marine and terrestrial biospheres used for climate change projections, typicall
288 es are likely to play a major role in future biosphere-vegetation feedbacks such as sun-screening und
291 , nearly all of the reactive nitrogen in the biosphere was generated and recycled by microorganisms.
292 thermal vents represent a deep, hot, aphotic biosphere where chemosynthetic primary producers, fuelle
293 of plant-soil-nutrient feedbacks in the land biosphere, which, in turn, are essential for our ability
295 nique class of pigments found throughout the biosphere with a wide variety of functions, structures,
296 e, and on the other the modern 'Phanerozoic' biosphere with its extraordinary diversity of large mult
297 a(15)N data indicate a Mo-based diazotrophic biosphere with no compelling evidence for a significant
298 areness that our planet is a self-supporting biosphere with sunlight as its major source of energy fo
300 originating from the terrestrial and marine biosphere, with a profound effect on atmospheric chemist