Absorption of Water in Thermally Modified Pine Wood As Studied by Nuclear Magnetic Resonance

Kekkonen, Päivi; Ylisassi, Aapo; Telkki, Ville‐Veikko

doi:10.1021/jp411199r

Cited by 62 publications

(82 citation statements)

References 51 publications

(85 reference statements)

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“…It results in a relatively short relaxation time, called bound water. When the MC increases towards the FSP, as in case II, Table 2 The measurement settings of HSE and CPMG pulse sequences used during water uptake and drying of all selected wood types t e (ls) t ww (ls) (Menon et al 1987;Kekkonen et al 2014). The wood cellulose has very short T 2 around tens of microseconds, which is too short to be observed in the used NMR set-up.…”

Section: Relaxation Analysis Of Water In Woodmentioning

confidence: 99%

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Bound and free water distribution in wood during water uptake and drying as measured by 1D magnetic resonance imaging

et al. 2016

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Knowledge on moisture transport in wood is important for understanding its utilization, durability and product quality. Moisture transport processes in wood can be studied by Nuclear Magnetic Resonance (NMR) imaging. By combining NMR imaging with relaxometry, the state of water within wood can be identified, i.e. water bound to the cell wall, and free water in the cell lumen/vessel. This paper presents how the transport of water can be monitored and quantified in terms of bound and free water during water uptake and drying. Three types of wood from softwood to hardwood were selected covering a range of low to high density wood; pine sapwood and oak and teak. A calibration is performed to determine the different water states in each different wood type and to convert the NMR signal into moisture content. For all wood types, water transport appeared to be internally limited during both uptake and drying. In case of water uptake, free water was observed only after the cell walls were saturated with bound water. In case of drying, the loss of bound water starts only after vanishing of free water, irrespective of the position. Obviously, there is always a local thermodynamic equilibrium of bound and free water for both uptake and drying. Finally, we determined the effective diffusion coefficient (D eff ). Experimentally determined diffusion constants were compared with those derived by the diffusion models for conceptual understanding of transport mechanism. We found that diffusion in the cell wall fibers plays a critical role in the transport process.

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Section: Relaxation Analysis Of Water In Woodmentioning

confidence: 99%

“…These studies provide spatially resolved one dimensional moisture profiles, but no spatially resolved relaxation analysis. The role of the porosity on water transport was studied by Kekkonen et al (2014). They investigated absorption of water in thermally modified wood by applying various NMR methods.…”

Section: Introductionmentioning

confidence: 99%

Bound and free water distribution in wood during water uptake and drying as measured by 1D magnetic resonance imaging

et al. 2016

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“…Low-field nuclear magnetic resonance spectroscopy and magnetic resonance imaging Low-field (LF) nuclear magnetic resonance (NMR) spectroscopy, also known as time-domain NMR (Thygesen and Elder 2008) or NMR relaxometry (Kekkonen et al 2014), can distinguish between water-bound hydrogen located in different physical and chemical environments. Consequently, it is a good technique for determining the distribution of water within different parts of the wood structure (Araujo et al 1992).…”

Section: Spectroscopic Techniquesmentioning

confidence: 99%

“…In particular, CPMG is a commonly used sequence for determining T 2 relaxation as it reduces effects of magnet inhomogeneity by multiple refocusing of the spins in the transverse plane. Several studies have employed LFNMR for characterising water in both untreated Araujo et al 1992Araujo et al , 1994Cox et al 2010;Flibotte et al 1990;Fredriksson and Thygesen 2017;Labbé et al 2002Labbé et al , 2006Menon et al 1987;Passarini et al 2015;Telkki et al 2013;Elder 2008, 2009) and modified wood (Elder et al 2006;Hietala et al 2002;Javed et al 2015;Kekkonen et al 2014;Elder 2008, 2009). Based on a deconvolution of the decay curves, signals from water in different compartments within the wood structure have been analysed Araujo et al 1992Araujo et al , 1993Fredriksson and Thygesen 2017;Passarini et al 2015) (see Fig.…”

Section: Spectroscopic Techniquesmentioning

confidence: 99%

Experimental techniques for characterising water in wood covering the range from dry to fully water-saturated

2017

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Water plays a central role in wood research, since it affects all material properties relevant to the performance of wood materials. Therefore, experimental techniques for characterising water within wood are an essential part of nearly all scientific investigations of wood materials. This review focuses on selected experimental techniques that can give deeper insights into various aspects of water in wood in the entire moisture domain from dry to fully water-saturated. These techniques fall into three broad categories: (1) gravimetric techniques that determine how much water is absorbed, (2) fibre saturation techniques that determine the amount of water within cell walls, and (3) spectroscopic techniques that provide insights into chemical wood-water interactions as well as yield information on water distribution in the macro-void wood structure. For all techniques, the general measurement concept is explained, its history in wood science as well as advantages and limitations.

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“…Although the NMR spectrum in this context typically shows only a single and broad peak, bound water and free water can be distinguished by means of T 2 or T 1 relaxation time distributions ( Riggin et al 1979 ;Araujo et al 1992 ;Hartley et al 1994 ;Xu et al 1996 ;Labb é et al 2002 ;Fantazzini et al 2006 ;Almeida et al 2007 ;Thygesen and Elder 2008 ;Cox et al 2010 ;Hoffmeyer et al 2011 ;Elder and Houtman 2013 ;Telkki et al 2013 ;Zhang et al 2013 ;Kekkonen et al 2014 ). NMR self-diffusion measurements enable the observation of moisture transport in wood ( Wycoff et al 2000 ;Hietala et al 2002 ;Topgaard and S ö derman 2002 ;Meder et al 2003 ;Johannessen et al 2006 ;Kekkonen et al 2009 ;Telkki and Jokisaari 2009 ;Kekkonen et al 2010 ).…”

Section: Introductionmentioning

confidence: 99%

Magnetic resonance imaging study of water absorption in thermally modified pine wood

et al. 2014

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Thermal modification is an environmentally friendly process that enhances the lifetime and properties of timber. In this work, the absorption of water in pine wood ( Pinus sylvestris ) samples, which were modified by the ThermoWood process, was studied by magnetic resonance imaging (MRI) and gravimetric analysis. The modification temperatures were varied between 180 ° C and 240 ° C. The data shows that the modification at 240 ° C and at 230 ° C decreases the water absorption rate significantly and slightly, respectively, while lower temperatures do not have a noticeable effect. MR images reveal that free water absorption in latewood (LW) is faster than in earlywood (EW), but in the saturated sample, the amount of water is greater in EW. Individual resin channels can be resolved in the high-resolution images, especially in LW regions of the modified samples, and their density was estimated to be (2.7 ± 0.6) mm -2 . The T 2 relaxation time of water is longer in the modified wood than in the reference samples due to the removal of resin and extractives in the course of the modification process.

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Absorption of Water in Thermally Modified Pine Wood As Studied by Nuclear Magnetic Resonance

Cited by 62 publications

References 51 publications

Bound and free water distribution in wood during water uptake and drying as measured by 1D magnetic resonance imaging

Bound and free water distribution in wood during water uptake and drying as measured by 1D magnetic resonance imaging

Experimental techniques for characterising water in wood covering the range from dry to fully water-saturated

Magnetic resonance imaging study of water absorption in thermally modified pine wood

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