Capillary-Driven Flow Through Biological Porous Media: X-ray Microtomography and Computational Fluid Dynamics

IF 2.6 3区工程技术 Q3 ENGINEERING, CHEMICAL

Transport in Porous Media Pub Date : 2025-10-16 DOI:10.1007/s11242-025-02238-5

T. Staffan Lundström, J. Gunnar I. Hellström, Anna-Lena Ljung, Fredrik Forsberg, Henrik Lycksam, Mehrdad Mashkour, Mandeep Singh, Kristiina Oksman, Johannes A. J. Huber

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Abstract

This study investigates the use of X-ray microtomography (XMT) to reveal the structure of complex porous biological tissues and the fluid flow through them during wetting. It also evaluates fluid dynamical simulations based on XMT data to reproduce and analyse these flows, with a final aim of revealing fluid transport and void formation in such tissues. To fulfil the objectives, the wetting flow of a polymer liquid through an initially dry conditioned Norway spruce wood sample is visualised using XMT at the MAX IV synchrotron. The liquid flow front progression captured after 24 s and 48 s reveals uneven filling of longitudinal tracheids and flow between them via the tiny pits which connect tracheids. Most tracheids fill between 24 and 48 s, possibly due to removal of air inclusions. Large density gradients near cell walls suggest that the fluid followed and deposited along wall structures. Computational fluid dynamics simulations (CFD) of saturated flow through the tomography-based geometry indicate velocity profiles that resemble pipe flow in longitudinal tracheids and flow rate differences among them. The latter indicates that the geometry itself may cause the experimentally observed uneven flow. Streamlines show intra-tracheid flow development and clear flow direction change at the pits. Additionally, wetting simulations, using a constant contact angle, capture initial uneven filling between the tracheids on shorter time scales than could be capture by the experiments. These simulations furthermore show air entrapment during filling, consistent with experimental observations. Combining XMT with CFD enables detailed studies of flow in biological porous media. Faster X-ray scanning, incorporating dynamic contact angles and accounting for diffusion in simulations could further refine insights into fluid progression during capillary-driven flow into complex structures of porous biological tissues.

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通过生物多孔介质的毛细管驱动流动：x射线微断层扫描和计算流体动力学

本研究利用x射线微断层扫描（XMT）揭示了复杂多孔生物组织的结构和润湿过程中流体的流动。它还评估了基于XMT数据的流体动力学模拟，以重现和分析这些流动，最终目的是揭示这些组织中的流体输送和空隙形成。为了实现目标，在MAX IV同步加速器上使用XMT可视化聚合物液体通过最初干燥的挪威云杉木材样品的润湿流动。在24 s和48 s后捕获的流体流锋进程显示纵向管胞的不均匀填充和通过连接管胞的微小凹坑在管胞之间流动。大多数管胞在24到48秒之间充满，可能是由于去除空气夹杂物。细胞壁附近的大密度梯度表明流体沿着细胞壁结构移动并沉积。基于层析成像的饱和流计算流体力学模拟（CFD）表明，纵向气管内的速度分布与管道流动相似，且它们之间的流速存在差异。后者表明几何形状本身可能导致实验观察到的不均匀流动。流线显示管内流动发育，凹陷处流动方向变化明显。此外，湿润模拟使用恒定的接触角，在比实验更短的时间尺度上捕获气管之间的初始不均匀填充。这些模拟进一步显示了充填过程中的空气夹持，与实验观察结果一致。将XMT与CFD相结合，可以详细研究生物多孔介质中的流动。更快的x射线扫描，结合动态接触角和模拟中的扩散计算，可以进一步深入了解毛细管驱动的流体进入多孔生物组织复杂结构的过程。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Transport in Porous Media 工程技术-工程：化工

CiteScore

5.30

自引率

7.40%

发文量

155

审稿时长

4.2 months

期刊介绍： -Publishes original research on physical, chemical, and biological aspects of transport in porous media- Papers on porous media research may originate in various areas of physics, chemistry, biology, natural or materials science, and engineering (chemical, civil, agricultural, petroleum, environmental, electrical, and mechanical engineering)- Emphasizes theory, (numerical) modelling, laboratory work, and non-routine applications- Publishes work of a fundamental nature, of interest to a wide readership, that provides novel insight into porous media processes- Expanded in 2007 from 12 to 15 issues per year. Transport in Porous Media publishes original research on physical and chemical aspects of transport phenomena in rigid and deformable porous media. These phenomena, occurring in single and multiphase flow in porous domains, can be governed by extensive quantities such as mass of a fluid phase, mass of component of a phase, momentum, or energy. Moreover, porous medium deformations can be induced by the transport phenomena, by chemical and electro-chemical activities such as swelling, or by external loading through forces and displacements. These porous media phenomena may be studied by researchers from various areas of physics, chemistry, biology, natural or materials science, and engineering (chemical, civil, agricultural, petroleum, environmental, electrical, and mechanical engineering).