Utilization potential of naturally regenerated Mongolian Betula platyphylla wood based on growth characteristics and wood properties
Erdene-Ochir T., Ishiguri F., Nezu I., Tumenjargal B., Baasan B., Chultem G., Ohshima J., Yokota S. (2020). Utilization potential of naturally regenerated Mongolian Betula platyphylla wood based on growth characteristics and wood properties. Silva Fennica vol. 54 no. 3 article id 10284. https://doi.org/10.14214/sf.10284
Highlights
Abstract
To preliminary evaluate the potential wood utilization of Betula platyphylla Sukaczev trees naturally regenerated in Mongolia, growth characteristics (stem diameter and tree height), wood properties (annual ring width, basic density, and compressive strength parallel to grain at the green condition) of core samples, and stress-wave velocity in stems were investigated for Betula platyphylla trees grown naturally in three different sites in Selenge, Mongolia. Betula platyphylla trees, naturally grown in Nikko, Japan, were also examined to compare wood properties between the two regions. The mean values of stem diameter, tree height, stress-wave velocity of stems, annual ring width, basic density, and compressive strength parallel to grain at green condition in Mongolian B. platyphylla were 17.6 cm, 14.1 m, 3.50 km s–1, 1.27 mm, 0.51 g cm–3, and 20.4 MPa, respectively. Basic density and compressive strength were decreased first from the pith, and then gradually increased toward the bark. The wood properties of B. platyphylla trees grown naturally in Mongolia were similar to those in B. platyphylla trees grown in Japan. Growth characteristics, especially stem diameter, were positively correlated with the stress-wave velocity of stems and basic density. Early evaluation of basic density in B. platyphylla trees is possible by using wood located 2 cm from the pith. Basic density at the position from the 1st to the 15th annual ring from the pith showed significant between-site differences in Mongolian B. platyphylla. Based on the results, it is concluded that the wood of B. platyphylla trees grown in Mongolia may be used for industrial products as well as those from similar species in other countries.
Keywords
basic density;
stress-wave velocity;
compressive strength;
early evaluation
Received 11 December 2019 Accepted 17 June 2020 Published 22 June 2020
Views 44602
Available at https://doi.org/10.14214/sf.10284 | Download PDF
Betula platyphylla Sukaczev (later Betula platyphylla in this study) is a pioneer and fast-growing tree species in temperate to subarctic zones (Zhang 1997; Johnson and More 2004; Mao et al. 2010). Betula platyphylla is distributed in Northeast Asia, such as western and northern China, Japan, Korea, Mongolia, and Russia (eFloras 2008). In northern Europe, the other Betula species, Betula pendula Roth and Betula pubescens Ehrh., have been used as main hardwood species in forest regeneration and plantation (Hynynen et al. 2010). In addition, Betula alleghaniensis Britton, Betula papyrifera Marshall, and Betula lenta L. have been used as plantation species to produce wood for industrial utilization in the United States of America (Verkasalo 1990).
The wood properties of Betula species have been investigated by several researchers (for example, Hakkila 1966; Bhat 1980; Verkasalo 1990; Heräjärvi 2004a,b; Repola 2006; Luostarinen et al. 2009; Viherä-Aarnio and Velling 2017; Lachowicz et al. 2019). The wood has been used widely for charcoal, fuel, pulps, printing papers, and paperboard as well as raw materials for sawn timber, veneer, and plywood (Luostarinen and Verkasalo 2000; Heräjärvi 2002; Bekhta et al. 2009; Dubois et al. 2020). In European countries, such as in Finland, the wood of Betula species has been utilized for a multitude of industrial and bioenergy products (e.g., Kärhä 2011).
Stress-wave techniques are a well-known, nondestructive testing methods used to evaluate wood quality, especially density, stability and mechanical properties (Smulski 1991; Wang et al. 2001, 2004; Ishiguri et al. 2008; Yin et al. 2011). Wood density is known to strongly affect the physical and mechanical properties of wood (Kollman and Côté 1984). Therefore, the stress-wave velocity of stems and basic density are important indicators when evaluating wood properties. Shmulsky and Jones (2011) mentioned that understanding the radial variations of wood properties is important for utilizing the wood resources.
In Mongolia, B. platyphylla occupies approximately 10% of the total forest area, comprising about 6% of total forest stock volume, as stated by the Ministry of Environment and Tourism (2016). In contrast to the abundance of forest resources in this species, its wood is only utilized by households for firewood or small wooden artifacts. In other words, the wood utilization level of B. platyphylla in Mongolia is lower compared to that of similar species growing in other countries. Detailed information about the wood is required for B. platyphylla grown in Mongolia to promote the wood utilization of this species. However, only a few studies are available regarding this issue (Sambuu and Dolgorhuu 2009). Regarding to the utilization of wood resources of this species, basic information about wood is also needed for tree breeding programs for wood quality in the future establishment of plantations in Mongolia.
The objective of this study is to preliminarily evaluate the potential wood utilization on the basis of growth characteristics (stem diameter and tree height) and selected wood properties (annual ring width, basic density, and compressive strength parallel to the grain) of core samples, and stress-wave velocity in stems of B. platyphylla trees grown naturally in Mongolia. Relationships between growth characteristics, wood properties, and stress-wave velocity are investigated. To determine the possible utilization methods, the results are compared with those of the same species growing in Japan and other countries. Finally, possibility of tree breeding for wood quality is discussed.
The experimental sites were located in Selenge, Mongolia (48°34´–41´N, 106°38´–52´E, ca. 1100 m above the sea level). This province has the highest growing stock volume of Betula forests in Mongolia. Three different sites (Site I, II, and III) of naturally regenerated forests were selected for this study. Site I is a pure forest of B. platyphylla, whereas Site II and III are mixed forests with Pinus sylvestris L. and Larix sibirica Ledeb., respectively. Exact tree age was unknown because trees were growing in naturally regenerated forests. To compare wood properties, trees of naturally regenerated B. platyphylla (without any silvicultural treatments) were also selected in the Experimental Forest, Utsunomiya University, Nikko, Japan (36°47´N, 139°29´E, ca. 1550 m above sea level). Tree age was also unknown in Japanese B. platyphylla. Fig. 1 shows the basic climatic conditions of experimental sites.
Fig. 2 shows the experimental procedures in the present study. Growth characteristics (stem diameter and tree height) and the stress-wave velocity of stem were measured for a total of 110 trees from the three sites in Mongolia and 10 trees in Japan. Stem diameter was measured at 1.3 m above the ground, using a tape measure. Tree height was measured using an ultrasonic height meter (Vertex IV, Haglöf). The stress-wave velocity of stems was measured between positions at 0.5 m and 1.5 m above ground, using a commercial handheld stress-wave timer (Fakopp Microsecond Timer, Fakopp Enterprise), as described in by Ishiguri et al. (2008) and Tumenjargal et al. (2018).
Core samples 5 mm in diameter were obtained by a core borer (Haglöf) at 1.3 m above ground for 30 Mongolian B. platyphylla trees (10 trees per site and three cores per tree) to measure the wood properties (Fig. 2). Ten sample trees were selected based on the mean values of stem diameter at 1.3 m above the ground in each site. For 10 Japanese B. platyphylla trees, 2 cm-thick disks were obtained at around 1.3 m above the ground and radial boards with 2 cm thickness (including bark-to-bark) were obtained from the disks.
Transverse sections of pith-to-bark core samples and bark-to-bark radial strips were trimmed with a disposable knife to measure annual ring width. Next, bark-to-bark radial strips and pith-to-bark core strips were prepared. The image data (2400 dpi) of the transverse section of both the radial and core strips from pith to bark in one direction were captured using a scanner (GT-9300UF, Epson). Both the annual ring number and width were measured using the software ImageJ (National Institutes of Health, USA). The mean values were calculated every 5 years to evaluate the radial variation of annual rings.
Separate core samples with 5 mm diameters were obtained from 30 Mongolian B. platyphylla trees, using the same method for measuring basic density. For Japanese B. platyphylla trees, 2 cm-thick disks were obtained at approximately 1.3 m above the ground after felling the trees. The wedge-shaped specimens (30° in center angle) were then prepared. The basic density was measured at one-centimetre intervals from the pith to the bark, and calculated by dividing oven-dried weight (105 °C) by green volume measured by the water displacement method (Kollmann and Côté 1984).
Separate core samples with 5 mm diameters were obtained from both Mongolian and Japanese B. platyphylla trees by using the method described above to assess compressive strength parallel to grain at green condition. It was measured at 5-mm intervals from the pith to the bark, using strength-test equipment for core samples (Fractometer II, IML), according to our previous reports (Matsumoto et al. 2008; Ishiguri et al. 2012). Matsumoto et al. (2008) reported that values of compressive strength at green condition in the core samples measured by Fractometer II had almost the same values than compressive strength parallel to the grain at green condition in small-clear specimens in Japan Industrial Standard. This suggests that the values of compressive strength measured by Fractometer II can be compared with reference values obtained by small-clear specimens at green condition.
The mean values of basic density and compressive strength were calculated at one-centimetre intervals from the pith to the bark to analyze their radial variations. In addition, values of basic density and compressive strength determined with respect to radial distance from the pith were converted to those with respect to tree age (annual ring number from pith) applying the method described by Makino et al. (2012). By using these results, the mean values of basic density and compressive strength were also calculated at five-year intervals from the pith to the bark.
Differences between mean values of Mongolian and Japanese sites were detected by the t-tests. Analysis of variance (ANOVA) was applied to evaluate the differences in measured characteristics, such as basic density among Mongolian sites. The relationship between the measured tree and wood properties was determined using Pearson’s correlation. In addition, correlation coefficients of basic density were determined between the inner (within 2 or 3 cm from the pith) and the outer wood (2 or 3 cm from the bark). All statistical analyses were conducted using MS Excel (Excel 2016, Microsoft).
Table 1 shows mean values of growth characteristics and stress-wave velocity of stems of B. platyphylla trees in Mongolia and Japan. Mean values of stem diameter, tree height, and stress-wave velocity of stems in three sites in Mongolia ranged from 13.4 to 22.7 cm, 11.0 to 17.6 m, and 3.29 to 3.76 km s–1, respectively. Mean values of stem diameter, tree height, and stress-wave velocity of stems were 17.6 cm, 14.1 m, and 3.50 km s–1, respectively. Although stem diameter was not significantly different between Mongolian and Japanese B. platyphylla trees, tree height and stress-wave velocity of Mongolian trees were significantly lower than those of Japanese trees.
Table 1. Growth characteristics and stress-wave velocity in wood of Betula platyphylla naturally grown in Mongolia and Japan. | |||||||||||||
Site | n | D (cm) | TH (m) | SWV (km s–1) | |||||||||
Mean | SD | Min. | Max. | Mean | SD | Min. | Max. | Mean | SD | Min. | Max. | ||
I | 50 | 13.4 | 2.8 | 9.0 | 21.0 | 11.0 | 2.0 | 7.7 | 14.8 | 3.29 | 0.20 | 2.87 | 3.65 |
II | 30 | 22.7 | 5.1 | 15.4 | 36.7 | 17.6 | 3.3 | 10.3 | 25.8 | 3.76 | 0.48 | 2.62 | 4.44 |
III | 30 | 19.4 | 3.2 | 13.8 | 26.9 | 15.9 | 2.0 | 10.5 | 18.7 | 3.61 | 0.33 | 2.76 | 4.14 |
Mean/total | 110 | 17.6 | 5.4 | 9.0 | 36.7 | 14.1 | 3.8 | 7.7 | 25.8 | 3.50 | 0.39 | 2.62 | 4.44 |
Nikko, Japan | 10 | 17.8 | 2.7 | 13.8 | 21.8 | 17.1 | 2.3 | 14.4 | 21.2 | 4.07 | 0.13 | 3.87 | 4.26 |
Significance | ns | * | ** | ||||||||||
n, number of standing trees; D, stem diameter at 1.3 m above the ground; TH, tree height; SWV, stress-wave velocity of stems; SD, standard deviation; Min., minimum; Max., maximum. Significant differences were obtained by t-test between Mongolian trees (110 trees) and Japanese trees (10 trees). **, significant difference (p < 0.01); *, significant difference (p < 0.05); ns, no significant difference. |
Number of annual rings and mean values of the annual ring width of Mongolian B. platyphylla trees ranged from 36 to 93 and 0.09 to 4.28 mm, respectively (Table 2). No significant difference was found in annual ring width between Mongolian and Japanese B. platyphylla trees. As shown in Fig. 3, the annual ring width of B. platyphylla decreased from the pith towards the bark in each Mongolian and Japanese site. The pace of decrease varied by site, and the trees of sites II and III were older than the trees of site I and in Japan.
Table 2. Number of annual rings and annual ring width in the sample of 30 Mongolian and 10 Japanese Betula platyphylla trees. | |||||||||
Site | n | Number of annual rings | Annual ring width (mm) | ||||||
Mean | Min. | Max. | Mean | SD | Min. | Max. | |||
I | 10 | 42 | 36 | 54 | 1.42 | 0.21 | 0.23 | 4.28 | |
II | 10 | 83 | 74 | 93 | 1.13 | 0.15 | 0.13 | 3.45 | |
III | 10 | 67 | 62 | 76 | 1.27 | 0.09 | 0.09 | 3.48 | |
Mean/total | - | - | - | - | 1.27 | 0.15 | 0.15 | 3.74 | |
Nikko, Japan | 10 | 54 | 49 | 60 | 1.46 | 0.21 | 0.44 | 3.92 | |
Significance | - | ns | |||||||
n, number of sample trees; SD, standard deviation; Min., minimum; Max., maximum. Significant differences were obtained by t-test between Mongolian and Japanese samples. ns, no significant difference. |
The mean values of basic density of Mongolian B. platyphylla wood in each site ranged from 0.49 to 0.55 g cm–3 (Table 3). Basic density showed significantly higher mean values compared to those of Japanese trees (Table 3). Basic density in both Mongolian and Japanese B. platyphylla wood decreased down to approximately 2 cm from the pith (or 10th to 20th annual ring from the pith), and then increased towards the bark (Fig. 4). Table 4 shows mean values of basic density at 5-year intervals starting from the pith in trees of the three Mongolian sites. Significant differences in basic density at the position of annual ring numbers from 1–5, 6–10, and 11–15 were found among three sites, whereas the mean values did not differ significantly after the 20th annual ring.
Table 3. Means and standard deviations of wood properties in the sample of 30 Mongolian and 10 Japanese Betula platyphylla trees. | ||||||||||
Site | n | BD (g cm–3) | CS (MPa) | |||||||
Mean | SD | Min. | Max. | Mean | SD | Min. | Max. | |||
I | 10 | 0.49 | 0.04 | 0.41 | 0.53 | 20.5 | 2.2 | 16.8 | 23.6 | |
II | 10 | 0.55 | 0.02 | 0.51 | 0.58 | 21.3 | 1.1 | 19.4 | 23.9 | |
III | 10 | 0.51 | 0.02 | 0.47 | 0.53 | 19.2 | 1.8 | 16.1 | 21.9 | |
Mean/total | 30 | 0.51 | 0.04 | 0.41 | 0.58 | 20.4 | 1.9 | 16.1 | 23.9 | |
Nikko, Japan | 10 | 0.49 | 0.02 | 0.45 | 0.52 | 21.3 | 1.5 | 18.8 | 23.6 | |
Significance | ** | ns | ||||||||
n, number of sample trees; BD, basic density; CS, compression strength; SD, standard deviation; Min., minimum; Max., maximum. Significant differences were obtained by t-test between Mongolian and Japanese samples. **, significant difference (p < 0.01); ns, no significant difference. |
Table 4. Mean values of basic density in certain radial positions in the sample trees of 30 Mongolian Betula platyphylla trees. | |||||||||
Radial position (annual ring number) | Site I (n = 10) | Site II (n = 10) | Site III (n = 10) | Significance among three sites | |||||
Mean | SD | Mean | SD | Mean | SD | ||||
1–5 | 0.48 | 0.07 | 0.56 | 0.05 | 0.51 | 0.04 | ** | ||
6–10 | 0.46 | 0.06 | 0.53 | 0.05 | 0.49 | 0.03 | ** | ||
11–15 | 0.47 | 0.05 | 0.52 | 0.03 | 0.49 | 0.04 | * | ||
16–20 | 0.48 | 0.05 | 0.52 | 0.03 | 0.49 | 0.03 | ns | ||
21–25 | 0.50 | 0.05 | 0.52 | 0.04 | 0.50 | 0.03 | ns | ||
26–30 | 0.51 | 0.04 | 0.52 | 0.03 | 0.50 | 0.03 | ns | ||
31–35 | 0.52 | 0.03 | 0.53 | 0.03 | 0.51 | 0.03 | ns | ||
n, number of sample trees; SD, standard deviation; F- and p-values obtained by analysis of variance (ANOVA) test among three sites. **, significant difference (p < 0.01); *, significant difference (p < 0.05); ns, no significant difference. |
The mean value of compressive strength parallel to the grain at green condition in the Mongolian B. platyphylla wood was 20.4 ± 1.9 MPa (Table 3). Compressive strength increased from the pith towards the bark, except for Site I (Fig. 5). In Site I, the radial variation was similar to that of basic density; compressive strength decreased to approximately 2 cm from the pith or to the 10th annual ring from the pith, and then gradually increased (Fig. 5). In other Mongolian sites, as well as in Japan, compressive strength systematically increased along with the radial position and the number of annual rings. The compressive strength became almost constant after the 40th annual ring from the pith in both Mongolia and Japan (Fig. 5). No differences were found in the compressive strengths between the Mongolian and Japanese B. platyphylla wood (Table 3).
A significant positive correlation was found between stem diameter and tree height for 110 Mongolian trees (r = 0.717, p < 0.01) (Fig. 6). This tendency was also true for the sampled 30 trees (Table 5, r = 0.696, p < 0.01). The results suggest that growth characteristics are closely linked to each other for this species. The stress-wave velocity of stems in the examined height intervals also correlated positively with the stem diameter (r = 0.446, p < 0.05), and tree height (r = 0.532, p < 0.01) (Table 5). Similar but much weaker tendencies were observed in all 110 trees: the correlation coefficients between stress-wave velocity and stem diameter and stress-wave velocity and tree height showed values of r = 0.187 and r = 0.435 (p < 0.05 and p < 0.01), respectively. Significant negative correlation coefficients were found between annual ring width and stress-wave velocity or basic density, but not with compressive strength (Table 5). Significant correlation coefficients were found between basic density and other examined tree and wood properties, whereas compressive strength did not correlate with growth characteristics or stress-wave velocity (Table 5). Basic density correlated positively with stem diameter (r = 0.565, p < 0.01) and tree height (r = 0.574, p < 0.01) (Table 5). Faster-growing trees had more wood volume with higher density. Strong positive correlations were found between the basic densities of inner and outer wood (Fig. 7).
Table 5. Correlation coefficients among measured characteristics in the sample of 30 Mongolian Betula platyphylla trees. | ||||||
Property | D | TH | ARW | SWV | BD | CS |
D | ** | * | * | ** | ns | |
TH | 0.696 | ** | ** | ** | ns | |
ARW | –0.450 | –0.587 | ** | * | ns | |
SWV | 0.446 | 0.532 | –0.478 | ** | ns | |
BD | 0.565 | 0.574 | –0.384 | 0.552 | ** | |
CS | 0.101 | 0.151 | –0.144 | 0.221 | 0.499 | |
D, stem diameter at 1.3 m above the ground; TH, tree height; ARW, annual ring width; SWV, stress-wave velocity of stems; BD, basic density; CS, compressive strength; **, significant correlation (p < 0.01); *, significant correlation (p < 0.05); ns, no significant. |
The stress-wave velocity of wood in different forms (trees, logs, and small-clear specimens) have been reported in hardwood species by several researchers (Armstrong and Patterson 1991; Smulski 1991; Ilic 2003; Wang et al. 2004; Yin et al. 2011). Ilic (2003) reported that the stress-wave velocity of 45 small hardwood beams along a longitudinal direction at 12% moisture content ranged from 4180 to 5700 m s–1 (4.18 to 5.70 km s–1). Yin et al. (2011) reported that the stress-wave velocity of green logs of Populus × euramericana cv. I-72/58 “San Martino” ranged from 3.05 to 3.09 km s–1. The mean value of the stress-wave velocity of Mongolian B. platyphylla trees along a longitudinal direction at green condition was almost similar to that of green logs of P. × euramericana (Yin et al. 2011). Yin et al. (2011) also mentioned that stress-wave technology is a reliable method to predict the strength properties of both logs and trees in hardwood species. The results of this study indicate potential to apply stress-wave velocity measurement to B. platyphylla, as well.
The mean value of the annual ring width (1.27 mm) at three sites (Table 2) was almost similar to those of 25-year-old B. pubescens trees (1.35 to 1.40 mm) grown in Finland (Luostarinen et al. 2009). The radial variations in annual ring width were also examined in other Betula species grown in Finland (Bhat 1980; Luostarinen et al. 2009). The annual ring width of B. pendula trees increased up to about 25 years of age (25th annual ring) from the pith, and then dramatically decreased toward the bark (Bhat 1980). The radial patterns of annual ring width in this study (Fig. 3) were almost identical to the results obtained by Bhat (1980).
Compared to the basic density of Betula species, the mean values obtained in the present study (Table 3) were relatively higher than those of 22-, 30-, and 45-year-old B. pendula trees (0.47 to 0.48 g cm–3) grown in Finland (Bhat 1980; Repola 2006; Viherä-Aarnio and Velling 2017). Lachowicz et al. (2019) reported that the mean values of the basic density of B. pendula grown in Poland were 0.51, 0.53, and 0.54 g cm–3 for 30-, 50-, and 70-year-old trees, respectively. Lachowicz et al. (2019) concluded that tree age effects wood density in this species. Verkasalo (1990) reported that the mean value of wood density ranged from 480 to 550 kg m–3 (0.48 to 0.55 g cm–3) for B. alleghaniensis and B. papyrifera trees grown in the United States of America. In the present study, the mean basic density of wood gradually increased after the 6th annual ring towards the bark in all Mongolian sites (Table 4). The mean value of the basic density of three Mongolian sites (0.51 g cm–3) was similar to those reported for B. pendula grown in European countries and B. alleghaniensis Britton and B. papyrifera Marsh grown in the United States of America (Bhat 1980; Verkasalo 1990; Repola 2006; Viherä-Aarnio and Velling 2017; Lachowicz et al. 2019). The radial pattern of basic density in B. platyphylla in the present study (Fig. 4) was regarded as type II in the classification by Panshin and de Zeeuw (1980); basic density decreased outward from the pith, and then increased to the bark. Similar radial variations were also found in other Betula species (Bhat 1980; Heräjärvi 2004b).
Compressive strength has been reported to range from 41.8 to 44.8 MPa at 15% moisture content in Betula species (B. platyphylla and Betula utilis D. Don) (Zhang 1997). In the present study, compressive strength was measured at green condition. Thus, the values were converted into those specimens at 28% of moisture content (fiber saturation point) using the method developed by Ishimaru et al. (2017). In the results, the values at the fiber saturation point ranged from 18.7 to 20.0 MPa. Thus, it was found that mean values of compressive strength in Mongolian B. platyphylla (Table 3) were similar to those of the same species grown in Japan and other Betula species grown in other countries. The radial variations of compressive strength (Fig. 5) were similar to those of subtropical and tropical fast-growing hardwood species, such as Casuarina equisetifolia L. (Chowdhury et al. 2009) and Dysoxylum mollissimum Bl. (Ishiguri et al. 2016). Based on the results, it is considered that wood density and compressive strength of Mongolian B. platyphylla is suitable for industrial utilization, although the number of sample trees and tested wood properties were limited in this study.
Previous studies have reported both for hardwood and softwood species that no correlation or a weak negative correlation exists between stem diameter and stress-wave velocity (Ishiguri et al. 2008, 2011, 2012; Tumenjargal et al. 2018). However, significant positive correlations were also found in tropical fast-growing hardwood species, such as Gmelina arborea Roxb. ex Sm. (Hidayati et al. 2017), Eucalyptus urophylla S.T. Blake, and Eucalyptus grandis W. Hill ex Maiden (Prasetyo et al. 2017). In the present study, significant positive correlations were observed between the growth characteristics and stress-wave velocity (Fig. 6 and Table 5), which is consistent with the results obtained in the above the mentioned studies. Our results suggest that the stress-wave velocity in naturally grown Mongolian B. platyphylla wood is dependent on growth characteristics; trees with faster radial and height growth appear to produce wood with higher strength properties. This finding might be related to a positive relationship between stem diameter and basic density (Table 5): higher basic density values were found in higher distances from the pith (Fig. 4).
Some studies indicate a negative but not very strong correlation between growth rate and wood density in Betula species (Bhat 1980; Heräjärvi 2004b; Repola 2006). Bhat (1980) reported that basic density was negatively related to annual ring width in Betula species, which is in accordance with the results of this study (Table 5).
Wood density has been reported to be closely related to mechanical properties, such as static bending and compressive strength in both hardwood and softwood species, including B. platyphylla trees (Hakkila 1966; Panshin and de Zeeuw 1980; Kollman and Côté 1984; Zobel and van Buijtenen 1989; Zhang 1997; Heräjärvi 2002, 2004a,b). Our results also suggest that wood density is a good indicator for predicting mechanical properties in B. platyphylla trees (Table 5). However, compressive strength and other measured growth characteristics and wood properties did not correlate in this study.
Although the number of sample trees and selection of tested properties were limited, possibility for tree breeding for wood quality was evaluated on the basis of the results in order to assess the need for future plantation establishment of this species in Mongolia.
In tree breeding programs, the early selection of trees with good wood properties is an important issue to reduce the breeding period (West 2006). The relationships of basic density between inner wood and outer wood were reported by several researchers (e.g., Wiemann and Williamson 1988; Ishiguri et al. 2011). Significant correlation coefficients of wood density in tropical pioneer trees were recognized between the inner wood within 3 cm from the pith, and the outer wood (within 3 cm from the bark side) (r2 = 0.71 to 0.88, r = 0.843 to 0.938, p < 0.01) (Wiemann and Williamson 1988). The correlation coefficients were almost similar to those obtained in this study (Fig. 7). Thus, early evaluation of basic density in B. platyphylla trees should be possible using wood at 2 cm from the pith.
As shown in Table 4, significant differences between the three Mongolian study sites were observed in the average basic densities of wood from the position between the 1st and 15th annual ring from the pith. The experimental sites were not far from each other (Table 1), thus the environmental conditions did not differ much between the three sites. The differences in basic densities at initial stage of growth might occur due to genetic differences. This result suggests that improvement of basic density is possible for selection of trees in tree breeding programs. However, further research is needed to clarify the effects of environmental conditions on wood properties in Mongolian B. platyphylla trees.
In the present study, growth characteristics and wood properties of core samples were investigated for B. platyphylla naturally regenerated in Selenge, Mongolia with the reference of that grown in Japan. The aim was to preliminary evaluate the potentials for wood utilization. The values for wood properties in Mongolian B. platyphylla were similar to those in Japanese B. platyphylla and in other Betula species used in many countries. In addition, positive correlations were found between the growth characteristics and stress-wave velocity of stems or basic density, suggesting that trees with good growth not always produce lower quality wood. If tree breeding programs will be established for this species in Mongolia, early selection and improvement of basic density can be possible. Based on the results, it is concluded that wood from B. platyphylla trees grown in Mongolia has the potential to be used as a raw material for a multitude of industrial products. Further research is needed to clarify the detailed wood properties and to determine the best utilization of wood from Mongolian B. platyphylla trees.
Part of this research was financially supported by the Higher Engineering Education Development Project, implemented by the Ministry of Education, Culture, Science, and Sports, Mongolia. The authors would like to thank Mr. Murzabyek Sarkhad, Mr. Yusuke Takahashi, Ms. Yui Kobayashi, and Mr. Tappei Takashima for their great assistance in the field experiments.
Armstrong J.P., Patterson D.W. (1991). Comparison of three equations for predicting stress wave velocity as a function of grain angle. Wood and Fiber Science 23(1): 32–43.
Bekhta P., Hiziroglu S., Shepelyuk O. (2009). Properties of plywood manufactured from compressed veneer as building material. Materials and Design 30(4): 947–953. https://doi.org/10.1016/j.matdes.2008.07.001.
Bhat K.M. (1980). Variation in structure and selected properties of Finnish birch wood I: Interrelationships of some structural features, basic density and shrinkage. Silva Fennica 14(4): 384–396. https://doi.org/10.14214/sf.a15032.
Chowdhury M.Q., Ishiguri F., Iizuka K., Takashima Y., Matsumoto K., Hiraiwa T., Ishido M., Sanpe H., Yokota S., Yoshizawa N. (2009). Radial variations of wood properties in Casuarina equisetifolia growing in Bangladesh. Journal of Wood Science 55(2): 139–143. https//doi 10.1007/s10086-008-1004-2.
Dubois H., Verkasalo E., Claessens H. (2020). Potential of birch (Betula pendula Roth and B. pubescens Ehrh.) for forestry and forest-based industry sector within the changing climatic and socio-economic context of western Europe. Forests 11(3): 336. https://doi.org/10.3390/f11030336.
eFloras (2008). Missouri Botanical Garden, St. Louis, MO & Harvard University Herbaria, Cambridge, MA. http://www.efloras.org. [Cited 11 June 2020].
Hakkila P. (1966). Investigation on the basic density of Finnish pine, spruce and birch wood. Communicationes Instituti Forestalis Fenniae 61(5): 1–98. http://urn.fi/urn:nbn:fi-metla-201207171093.
Heräjärvi H. (2002). Properties of birch (Betula pendula, B. pubescens) for sawmilling and further processing in Finland. Finnish Forest Research Institute, Research Papers 871. 52 p. http://urn.fi/urn:isbn:951-40-1856-7.
Heräjärvi H. (2004a). Static bending properties of Finnish birch wood. Wood Science and Technology 37(6): 523–530. https://doi.org/10.1007/s00226-003-0209-1.
Heräjärvi H. (2004b). Variation of basic density and Brinell hardness within mature Finnish Betula pendula and B. pubescens stems. Wood and Fiber Science 36(2): 216–227.
Hidayati F., Ishiguri F., Makino K., Tanabe J., Aiso H., Prasetyo V.E., Marsoem S.N., Wahyudi I., Iizuka K., Yokota S. (2017). The effects of radial growth rate on wood properties and anatomical characteristics and an evaluation of the xylem maturation process in a tropical fast-growing tree species, Gmelina arborea. Forest Products Journal 67(3): 297–303. https://doi.org/10.13073/fpj-d-16-00027.
Hynynen J., Niemistö P., Viherä-Aarnio A., Brunner A., Hein S., Velling P. (2010). Silviculture of birch (Betula pendula Roth and Betula pubescens Ehrh.) in northern Europe. Forestry 83(1): 103–119. https://doi.org/10.1093/forestry/cpp035.
Ilic J. (2003). Dynamic MOE of 55 species using small wood beams. Holz als Roh- und Werkstoff 61(3): 167–172. https://doi.org/10.1007/s00107-003-0367-8.
Ishiguri F., Matsui R., Iizuka K., Yokota S., Yoshizawa N. (2008). Prediction of the mechanical properties of lumber by stress-wave velocity and Pilodyn penetration of 36-year-old Japanese larch trees. Holz als Roh- und Werkstoff 66(4): 275–280. https://doi 10.1007/s00107-008-0251-7.
Ishiguri F., Makino K., Wahyudi I., Takashima Y., Iizuka K., Yokota S., Yoshizawa N. (2011). Stress wave velocity, basic density, and compressive strength in 34-year-old Pinus merkusii planted in Indonesia. Journal of Wood Science 57(6): 526–531. https://doi 10.1007/s10086-011-1208-8.
Ishiguri F., Takeuchi M., Makino K., Wahyudi I., Takashima Y., Iizuka K., Yokota S., Yoshizawa N. (2012). Cell morphology and wood properties of Shorea acuminatissima planted in Indonesia. IAWA Journal 33(1): 25–38. https://doi.org/10.1163/22941932-90000077.
Ishiguri F., Aiso H., Hirano M., Yahya R., Wahyudi I., Ohshima J. (2016). Effects of radial growth rate on anatomical characteristics and wood properties of 10-year-old Dysoxylum mollissimum trees planted in Bengkulu, Indonesia. Tropics 25(1): 23–31. https://doi.org/10.3759/tropics.25.23.
Ishimaru Y., Furuta Y., Sugiyama M. (2017). Physics of wood. Wood Science Series 3. Kaiseisha Press, Ohtsu. 210 p. [In Japanese].
Johnson O., More D. (2004). Broadleaves. Tree guide. Harper Collins, London. p. 182–189.
Kärhä K. (2011). Integrated harvesting of energy wood and pulpwood in first thinnings using the two-pile cutting method. Biomass and Bioenergy 35(8): 3397–3403. https://doi.org/10.1016/j.biombioe.2010.10.029.
Kollmann F.F.P., Côté W.A.Jr. (1984). Principles of wood science and technology: I solid wood. Springer-Verlag, Berlin, Heidelberg, New York, Tokyo. 592 p.
Lachowicz H., Bieniasz A., Wojtan R. (2019). Variability in the basic density of silver birch wood in Poland. Silva Fennica 53(1) article 9968. https://doi.org/10.14214/sf.9968.
Luostarinen K., Verkasalo E. (2000). Birch as sawn timber and in mechanical further processing in Finland. A literature study. Silva Fennica Monographs 1. 40 p.
Luostarinen K., Huotari N., Tillman-Sutela E. (2009). Effect of regeneration method on growth, wood density and fibre properties of Downy birch (Betula pubescens Ehrh.). Silva Fennica 43(3): 329–338. https://doi.org/10.14214/sf.191.
Makino K., Ishiguri F., Wahyudi I., Takashima Y., Iizuka K., Yokota S., Yoshizawa N. (2012). Wood properties of young Acacia mangium trees planted in Indonesia. Forest Products Journal 62(2): 102–106. https://doi.org/10.13073/0015-7473-62.2.102.
Mao Q., Watanabe M., Koike T. (2010). Growth characteristics of two promising tree species for afforestation, birch and larch in the northeastern part of Asia. Eurasian Journal of Forest Research 13(2): 69–76. http://hdl.handle.net/2115/44672.
Matsumoto K., Ishiguri F., Iizuka K., Yokota S., Yoshizawa N. (2008). Evaluation of bending and compressive strength of wood using Fractometer. Wood Industry 63(8): 358–363. [In Japanese with English summary].
Ministry of Environment and Tourism (2016). Forest resource in Mongolia. Forest Research and Development Center, Ministry of Environment and Tourism, Mongolia, Ulaanbaatar. 25 p. [In Mongolian].
Panshin A.J., de Zeeuw C. (1980). Variability of wood within a species. In: Provenzano M.D., Wagley S. (eds.). Textbook of wood technology. 4th edition. McGraw-Hill, New York. 722 p.
Prasetyo A., Aiso H., Ishiguri F., Wahyudi I., Wijaya I.P.G., Ohshima J. (2017). Variations on growth characteristics and wood properties of three Eucalyptus species planted for pulpwood in Indonesia. Tropics 26(2): 59–69. https://doi.org/10.3759/tropics.MS16-15.
Repola J. (2006). Models for vertical wood density of Scots pine, Norway spruce and birch stems, and their application to determine average wood density. Silva Fennica 40(4): 673–685. https://doi.org/10.14214/sf.322.
Sambuu B., Dolgorhuu N. (2009). Хус модны механик шинжийн үзүүлэлт тодорхойлсон үр дүн. [Study on mechanical properties of birch wood]. Academic Bulletin of Mongolian University of Science and Technology 105(3): 168–181. [In Mongolian].
Shmulsky R., Jones P.D. (2011). Forest products and wood science: an introduction. 6th edition. Wiley-Blackwell, West Sussex. 477 p.
Smulski S.J. (1991). Relationship of stress wave- and static bending-determined properties of four northeastern hardwoods. Wood and Fiber Science 23(1): 44–57.
Tumenjargal B., Ishiguri F., Aiso-Sanada H., Takahashi Y., Baasan B., Chultem G., Ohshima J., Yokota S. (2018). Geographic variations of wood properties of Larix sibirica naturally grown in Mongolia. Silva Fennica 52(4) article 10002. https://doi.org/10.14214/sf.10002.
Verkasalo E. (1990). Birch and aspen as a raw material for mechanical forest industries in the United States. Finnish Forest Research Institute. Research paper 367. 93 p. http://urn.fi/un:isbn:951-40-1128-7. [In Finnish with English summary].
Viherä-Aarnio A., Velling P. (2017). Growth, wood density and bark thickness of silver birch originating from the Baltic countries and Finland in two Finnish provenance trials. Silva Fennica 51(4) article 7731. https://doi.org/10.14214/sf.7731.
Wang X., Ross R.J., McClellan M., Barbour R.J., Erickson J.R., Forsman J.W., McGinnis G.D. (2001). Nondestructive evaluation of standing trees with a stress wave method. Wood and Fiber Science 33(4): 522–533.
Wang X., Ross R.J., Green D.W., Brashaw B., Englund K., Wolcott M. (2004). Stress wave sorting of red maple logs for structural quality. Wood Science and Technology 37(6): 531–537. https://doi.org/10.1007/s00226-003-0202-8.
West P.W. (2006). Tree breeding. In: Czeschlik D. (ed.). Growing plantation forests. Springer-Verlag, Berlin, Heidelberg. p. 191–216.
Wiemann M.C., Williamson G.B. (1988). Extreme radial changes in wood specific gravity in some tropical pioneers. Wood and Fiber Science 20(3): 344–349.
Yin Y., Jiang X., Wang L., Bian M. (2011). Predicting wood quality of green logs by resonance vibration and stress wave in plantation-grown Populus × euramericana. Forest Products Journal 61(2): 136–142. https://doi.org/10.13073/0015-7473-61.2.136.
Zhang S.Y. (1997). Wood specific gravity-mechanical property relationship at species level. Wood Science and Technology 31(3): 181–191. https://doi.org/10.1007/BF00705884.
Zobel B.J., van Buijtenen J.P. (1989). Wood variations, its causes and control. Timell T.E. (ed.). Springer-Verlag, Berlin, Heidelberg, NewYork. 363 p.
Total of 44 references.