The transpiration of water at negative pressures in a synthetic tree.
about
Slow, fast and furious: understanding the physics of plant movementsAutomatic sequential fluid handling with multilayer microfluidic sample isolated pumpingUltrasonic emissions reveal individual cavitation bubbles in water-stressed wood.Evaporation-induced cavitation in nanofluidic channelsScaling up nanoscale water-driven energy conversion into evaporation-driven engines and generators.Fabrication of Multscale Fractal-Like Structures by Controlling Fluid Interface Instability.A Mechanically Actuating Carbon-Nanotube Fiber in Response to Water and Moisture.Plant hydraulics as a central hub integrating plant and ecosystem function: meeting report for 'Emerging Frontiers in Plant Hydraulics' (Washington, DC, May 2015).Nitroaromatic detection and infrared communication from wild-type plants using plant nanobionics.Switchable imbibition in nanoporous gold.Ion induced changes in the structure of bordered pit membranes.Optimality of the Münch mechanism for translocation of sugars in plants.The fast dynamics of cavitation bubbles within water confined in elastic solids.Structural design of a double-layered porous hydrogel for effective mass transportAn improved method for the visualization of conductive vessels in Arabidopsis thaliana inflorescence stems.Water's tensile strength measured using an optofluidic chip.Quantifying green life: grand challenges in plant biophysics and modelingPlant xylem hydraulics: What we understand, current research, and future challenges.Fabrication of Triple-parted Stomata-inspired Membrane with Stimulus-responsive Functions.Molecular mechanism for cavitation in water under tension.Vapour pressure deficit control in relation to water transport and water productivity in greenhouse tomato production during summer.Plant cells use auxin efflux to explore geometry.Investigating water transport through the xylem network in vascular plants.Bioinspired engineering of thermal materials.Effect of entropy on the nucleation of cavitation bubbles in water under tension.Directional Fluid Transport in Thin Porous Materials and its Functional Applications.Synchrotron X-ray microtomography of xylem embolism in Sequoia sempervirens saplings during cycles of drought and recovery.Extreme Aridity Pushes Trees to Their Physical Limits.Towards quantitative root hydraulic phenotyping: novel mathematical functions to calculate plant-scale hydraulic parameters from root system functional and structural traits.Diurnal changes in embolism rate in nine dry forest trees: relationships with species-specific xylem vulnerability, hydraulic strategy and wood traits.Estimation of the hydraulic conductivities of lupine roots by inverse modelling of high-resolution measurements of root water uptake.Potential for natural evaporation as a reliable renewable energy resource.Adiabatic burst evaporation from bicontinuous nanoporous membranes.All-atom molecular dynamics calculation study of entire poliovirus empty capsids in solution.Regenerable photovoltaic devices with a hydrogel-embedded microvascular network.Universal poroelastic mechanism for hydraulic signals in biomimetic and natural branches.The recent development and applications of fluidic channels by 3D printing.A series RCL circuit theory for analyzing non-steady-state water uptake of maize plants.Relax and refill: xylem rehydration prior to hydraulic measurements favours embolism repair in stems and generates artificially low PLC values.Fabrication of Artificial Leaf to Develop Fluid Pump Driven by Surface Tension and Evaporation.
P2860
Q26865223-6084620A-E5B9-4160-B2E8-76E792B98137Q30373094-AD6C74D3-318C-426D-AC1B-6A6BE993F514Q30401475-86AEB6DF-4F91-4B9A-A3AF-8F8C687C45C0Q30463891-7EAC2EE9-4172-40A9-900B-87D5CA167138Q30656477-76324CEA-0AE4-47A4-BA73-2E258285F5DAQ30828847-06F02C56-C631-400B-9A7B-B578102E6516Q31004597-CC213307-D8DE-4F5B-A7FA-34A03DCD48DCQ31066877-18C7FFC3-5127-4BA8-B3D3-5C59CF4C0981Q33451303-F6D2DB57-5B7E-4890-9BEA-3A3056B0AD50Q33915078-136F20CA-D0DF-4FCF-A359-14D063FA6715Q34285747-15F10B84-8DBD-40FC-A144-F8CFFCBCA46FQ35059340-DAAD6B22-7687-47A5-97A4-5D7EAC76ADC0Q35162863-F55E60C9-56D0-4CB4-BCAC-2CB30088399FQ35175875-7560AB94-9A27-465D-B4AC-B5861938D1FAQ35338664-3A46C86B-B705-4A21-B143-0DAC71664CABQ35587738-05DE750F-7FBB-4549-99B2-19F57900BD97Q35970643-70519471-5D72-4052-9B3A-BE88958ECAE6Q36308729-B7F8A6B9-3358-49A0-97CB-6326DF8D254FQ36591709-F833614F-A023-44ED-A009-039D4DB13B4CQ37473668-DBD5E9DB-2560-48AC-9382-BA75220DCDFBQ37684069-A1BE49FD-8FB3-4B20-84E7-C0477A32DDEBQ37733233-7F2C64BA-629D-4CE9-845F-DA0E2841D549Q38194461-6932EC74-5A60-4850-9A9B-A3316BE8A3AEQ38255697-5B6F731D-CC09-44FB-9E68-65D603BF7B84Q38629216-5FB07E5C-E28F-4C99-8CB5-925C7E29024BQ38813626-F88306D1-D3F3-4E77-83D5-BFEAB61C292FQ38945394-56A0A1EF-2FCA-48AC-A1B2-D5EF00CE041EQ39161431-2BF36F93-CF68-4835-98A0-A778C1595059Q39247998-CF90B30B-985F-4469-BFD0-B4DA3371A8E8Q39533571-4589E843-D7E5-4D6D-8D5E-F52813FD47DCQ41632185-1EAE0388-4050-4213-9EB5-C3A8B585BFE6Q41676573-2AA746F7-CEFE-401D-BA1E-838230C4E923Q41822748-C0EB4480-6CAF-4ADC-8682-75F9DBA8790BQ42182372-1DBFB3A7-F5F9-48DC-BCD7-20288E3E75E8Q42286767-9E59B455-CE3E-49D3-A6E9-927FB3343CD9Q42653593-1E8549AF-FD2A-47F3-84FB-A77C36CCE7E9Q42657902-7DBAA174-BF16-4A8B-A310-420F9CFB5E31Q42955865-5B2D45CF-F3F0-4E41-8206-E8C1095E39BEQ44034374-C5684EF3-C342-4966-958F-8CD787C7C47CQ44442335-1EF1D746-D5F0-44C0-A9A4-E3B481D15A48
P2860
The transpiration of water at negative pressures in a synthetic tree.
description
2008 nî lūn-bûn
@nan
2008 թուականի Սեպտեմբերին հրատարակուած գիտական յօդուած
@hyw
2008 թվականի սեպտեմբերին հրատարակված գիտական հոդված
@hy
2008年の論文
@ja
2008年論文
@yue
2008年論文
@zh-hant
2008年論文
@zh-hk
2008年論文
@zh-mo
2008年論文
@zh-tw
2008年论文
@wuu
name
The transpiration of water at negative pressures in a synthetic tree.
@ast
The transpiration of water at negative pressures in a synthetic tree.
@en
type
label
The transpiration of water at negative pressures in a synthetic tree.
@ast
The transpiration of water at negative pressures in a synthetic tree.
@en
prefLabel
The transpiration of water at negative pressures in a synthetic tree.
@ast
The transpiration of water at negative pressures in a synthetic tree.
@en
P356
P1433
P1476
The transpiration of water at negative pressures in a synthetic tree.
@en
P2093
Abraham D Stroock
Tobias D Wheeler
P2888
P304
P356
10.1038/NATURE07226
P407
P577
2008-09-01T00:00:00Z
P5875
P6179
1020734707