Your search keyword '"water refilling"' showing total 7 results

1. Water refilling along vessels at initial stage of willow cuttage revealed by move contrast CT

Author

Mingwei Xu, Ke Li, Yanling Xue, Feixiang Wang, Zhixuan Liu, Zenghao Song, and Tiqiao Xiao

Subjects

move contrast X-ray imaging, agent free imaging, weak signal tracking in complex background, dynamic CT, in situ imaging, water refilling, Physics, QC1-999

Abstract

Cuttage is a widely used technique for plant propagation, whose success relies on the refilling for water transport recovery. However, requirements for refilling characterization studies, including large penetration depth, fast temporal resolution and high spatial resolution, cannot be reached simultaneously via conventional imaging techniques. So far, the dynamic process of water refilling along the vessels at the initial stage of cuttage, as well as its characteristics, remains unclear. Hereby, we developed a move contrast X-ray microtomography method which achieves 3D dynamic non-destructive imaging of water refilling at the initial stage of willow branch cuttage, without the aid of any contrast agent. Experimental results indicate three primary refilling modalities in vessels: 1) the osmosis type, mainly manifested by the osmosis of tissue through the vessel wall into the cavity; 2) the linear type, revealed as the tissue permeates to a certain extent where the liquid column in the vessels is completely formed; and 3) an osmosis-linear mixed type refilling as an intermediate state. Further analysis also exhibits a “temporal-spatial relay” mode of refilling between adjacent vessels. Since the vessel length is quite limited, the cavitation and the relay refilling mode of vessels can be an important way to achieve long-distance water transport.

Published

2023

2. Differentiating refilling and transpiration from night-time sap flux based on time series modelling.

Author

Zhao, Xiaowei, Zhao, Ping, and Zhu, Liwei

Abstract

Key message: Although night-time transpiration occurs most of the time, stem refilling contributed more to the amount of night-time sap flux, which indicates that there was no water loss in Schima superba at night-time. It has been historically shown to be difficult to identify the night-time transpiration (En) and stem refilling (Rn) components from night-time sap flux (NFt). We applied an autoregressive moving-average (ARMA) model with exogenous variables (ARMAX) fitting En to distinguish NFt of Schima superba for avoiding autocorrelation. In total, 23 optimum models were chosen at the node moments of the night in the dry and wet seasons. Models performed seasonal variations in involving environmental factors and build time. Vapor pressure deficit (VPDt) alone or with wind speed (WSt) drove positively NFt in most of the time in both seasons. SMt dominated NFt only at the beginning of the night-time in the dry season. En occurred 1 h later and was lower in the wet than in the dry season (ca. 1.09 kg h−1 vs 1.82 kg h−1), and Rn is the opposite (ca. 2.36 kg h−1 vs 1.9 kg h−1). This may cause by greater water storage deficit in the trunk due to stronger day-time transpiration. We found that NFt was minor compared to day-time sap flux (DFt), and the mean ratio of night-time sap flow (Qn) to daily sap flow (Qw) was only 0.02. Our results showed that there were no seasonal differences on the contribution of NFt to the 24-h Ft, and no water loss at the daily scale in Schima superba in both seasons (Rn > En). This study first quantifies En and Rn, and reveals seasonal variations in tree night-time water use and provides a basis for better understanding of En function. [ABSTRACT FROM AUTHOR]

Published

2022

3. Hydrodynamic Study on the 'Stop-and-Acceleration' Pattern of Refilling Flow at Perforation Plates by Using a Xylem-Inspired Channel

Author

Sang Joon Lee, JooYoung Park, and Jeongeun Ryu

Subjects

plant hydrodynamics, water transport in plants, embolism repair, water refilling, perforation plate, Plant culture, SB1-1110

Abstract

Porous structures, such as perforation plates and pit membranes, have attracted considerable attention due to their hydraulic regulation of water flow through vascular plant networks. However, limited information is available regarding the hydraulic functions of such structures during water-refilling and embolism repair because of difficulties in simultaneous in vivo measurements of refilling flow and pressure variations in xylem vessels. In this study, we developed a xylem-inspired microchannel with a porous mesh for systematic investigation on the hydraulic contribution of perforation plates on water-refilling. In particular, the “stop-and-acceleration” phenomenon of the water meniscus at the porous mesh structure was carefully examined in macroscopic and microscopic views. This distinctive phenomenon usually occurs in the xylem vessels of vascular plants during embolism repair. Based on the experimental results, we established a theoretical model of the flow characteristics and pressure variations around the porous structure inside the microchannel. Perforation plates could be speculated to be a pressure-modulated flow controller that facilitates embolism recovery. Furthermore, the proposed xylem-inspired channel can be used to investigate the hydraulic functions of porous structures for water management in plants.

Published

2019

4. Hydrodynamic Study on the "Stop-and-Acceleration" Pattern of Refilling Flow at Perforation Plates by Using a Xylem-Inspired Channel.

Author

Lee, Sang Joon, Park, JooYoung, and Ryu, Jeongeun

Subjects

VASCULAR plants, EMBOLISM (Botany), HYDRODYNAMICS

Abstract

Porous structures, such as perforation plates and pit membranes, have attracted considerable attention due to their hydraulic regulation of water flow through vascular plant networks. However, limited information is available regarding the hydraulic functions of such structures during water-refilling and embolism repair because of difficulties in simultaneous in vivo measurements of refilling flow and pressure variations in xylem vessels. In this study, we developed a xylem-inspired microchannel with a porous mesh for systematic investigation on the hydraulic contribution of perforation plates on water-refilling. In particular, the "stop-and-acceleration" phenomenon of the water meniscus at the porous mesh structure was carefully examined in macroscopic and microscopic views. This distinctive phenomenon usually occurs in the xylem vessels of vascular plants during embolism repair. Based on the experimental results, we established a theoretical model of the flow characteristics and pressure variations around the porous structure inside the microchannel. Perforation plates could be speculated to be a pressure-modulated flow controller that facilitates embolism recovery. Furthermore, the proposed xylem-inspired channel can be used to investigate the hydraulic functions of porous structures for water management in plants. [ABSTRACT FROM AUTHOR]

Published

2019

5. In vivo dynamic analysis of water refilling in embolized xylem vessels of intact Zea mays leaves.

Author

Jeongeun Ryu, Bae Geun Hwang, and Sang Joon Lee

Subjects

*XYLEM, *PLANT cells & tissues, *CORN, *WATER transfer, *EMBOLISM (Botany), *MONOCOTYLEDONS

Abstract

Background and Aims The refilling of embolized xylem vessels under tension is a major issue in water transport among vascular plants. However, xylem embolism and refilling remain poorly understood because of technical limitations. Direct observation of embolism repair in intact plants is essential to understand the biophysical aspects of water refilling in embolized xylem vessels. This paper reports on details of the water refilling process in leaves of the intact herbaceous monocot plant Zea mays and its refilling kinetics obtained by a direct visualization technique. Methods A synchrotron X-ray micro-imaging technique was used to monitor water refilling in embolized xylem vessels of intact maize leaves. Xylem embolism was artificially induced by using a glass capillary; real-time images of water refilling dynamics were consecutively captured at a frame rate of 50 f.p.s. Key Results Water supply in the radial direction initiates droplet formation on the wall of embolized xylem vessels. Each droplet grows into a water column; this phenomenon shows translation motion or continuous increase in water column volume. In some instances, water columns merge and form one large water column. Water refilling in the radial direction causes rapid recovery from embolism in several minutes. The average water refilling velocity is approx. 1 μm s−1. Conclusions Non-destructive visualization of embolized xylem vessels demonstrates rapid water refilling and gas bubble removal as key elements of embolism repair in a herbaceous monocot species. The refilling kinetics provides new insights into the dynamic mechanism of water refilling phenomena. [ABSTRACT FROM AUTHOR]

Published

2016

6. Hydrodynamic Study on the 'Stop-and-Acceleration' Pattern of Refilling Flow at Perforation Plates by Using a Xylem-Inspired Channel

Author

JooYoung Park, Jeongeun Ryu, and Sang Joon Lee

Subjects

0106 biological sciences, 0301 basic medicine, Materials science, Water flow, Flow (psychology), Perforation (oil well), Plant Science, lcsh:Plant culture, 01 natural sciences, 03 medical and health sciences, Acceleration, embolism repair, water transport in plants, lcsh:SB1-1110, Porosity, Original Research, Microchannel, perforation plate, Perforation plate, fungi, Xylem, food and beverages, Mechanics, water refilling, 030104 developmental biology, plant hydrodynamics, 010606 plant biology & botany

Abstract

Porous structures, such as perforation plates and pit membranes, have attracted considerable attention due to their hydraulic regulation of water flow through vascular plant networks. However, limited information is available regarding the hydraulic functions of such structures during water-refilling and embolism repair because of difficulties in simultaneous in vivo measurements of refilling flow and pressure variations in xylem vessels. In this study, we developed a xylem-inspired microchannel with a porous mesh for systematic investigation of the hydraulic contribution of perforation plates on water-refilling. In particular, the “stop-and-acceleration” phenomenon of the water meniscus at the porous mesh structure was carefully examined in macroscopic and microscopic views. This distinctive phenomenon usually occurs in the xylem vessels of vascular plants during embolism repair. Based on the experimental results, we established a theoretical model of the flow characteristics and pressure variations around the porous structure inside the microchannel. Perforation plates could be speculated to be a pressure-modulated flow controller that facilitates embolism recovery. Furthermore, the proposed xylem-inspired channel can be used to investigate the hydraulic functions of porous structures for water management in plants.

Published

2019

7. In vivo dynamic analysis of water refilling in embolized xylem vessels of intact Zea mays leaves.

Author

Ryu J, Hwang BG, and Lee SJ

Abstract

Background and Aims The refilling of embolized xylem vessels under tension is a major issue in water transport among vascular plants. However, xylem embolism and refilling remain poorly understood because of technical limitations. Direct observation of embolism repair in intact plants is essential to understand the biophysical aspects of water refilling in embolized xylem vessels. This paper reports on details of the water refilling process in leaves of the intact herbaceous monocot plant Zea mays and its refilling kinetics obtained by a direct visualization technique. Methods A synchrotron X-ray micro-imaging technique was used to monitor water refilling in embolized xylem vessels of intact maize leaves. Xylem embolism was artificially induced by using a glass capillary; real-time images of water refilling dynamics were consecutively captured at a frame rate of 50 f.p.s. Key Results Water supply in the radial direction initiates droplet formation on the wall of embolized xylem vessels. Each droplet grows into a water column; this phenomenon shows translation motion or continuous increase in water column volume. In some instances, water columns merge and form one large water column. Water refilling in the radial direction causes rapid recovery from embolism in several minutes. The average water refilling velocity is approx. 1 μm s-1. Conclusions Non-destructive visualization of embolized xylem vessels demonstrates rapid water refilling and gas bubble removal as key elements of embolism repair in a herbaceous monocot species. The refilling kinetics provides new insights into the dynamic mechanism of water refilling phenomena., (© The Author 2016. Published by Oxford University Press on behalf of the Annals of Botany Company. All rights reserved. For Permissions, please email: journals.permissions@oup.com.)

Published

2016