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Review

The Macroscopic Structure of Wood

1
Department of Agricultural, Forestry and Food Sciences, University of Torino, Largo Paolo Braccini, 2, 10095 Grugliasco, Italy
2
Forest Biometrics Laboratory, Faculty of Forestry, “Stefan cel Mare” University of Suceava, Str. Universitatii 13, 720229 Suceava, Romania
*
Author to whom correspondence should be addressed.
Forests 2023, 14(3), 644; https://doi.org/10.3390/f14030644
Submission received: 7 February 2023 / Revised: 9 March 2023 / Accepted: 15 March 2023 / Published: 21 March 2023
(This article belongs to the Special Issue Reviews on Structure and Physical and Mechanical Properties of Wood)

Abstract

:
Understanding the macroscopic structure of wood and its formation is essential to identifying wood and evaluating its properties and quality. Depending on genetic background, environmental conditions, and tree developmental stage, the macroscopic structure of wood can vary greatly and produce specific macroscopic signatures. Here, a comprehensive outline of the wood’s macroscopic structure and the features that can be used to identify wood by macroscopic examination is presented. The planes of observations are first depicted, and the fundamental differences between softwoods and hardwoods are outlined. Then, all the different cell characteristics, arrangements, and distributions that can be macroscopically observed are illustrated with their influence on wood figure and texture and non-anatomical features.

1. Introduction

When we handle a piece of wood, we observe its esthetic characteristics and feel some of its physical properties. What we see and feel results from a highly organized agglomerate of diverse cells and the chemical compounds deposited in their lumina or on their cell walls [1]. Although wood cell types are only a few, their size, arrangement, grouping, wall thickness, and content account for wood’s remarkable aesthetic, physical, and mechanical properties [2,3,4]. The wood’s cellular origin is also originating anomalies or specific wood characteristics [5].
Based on wood features visible by the naked eye or with a 10–15× magnification lens, a trained individual can identify an unknown piece of wood or validate a supposed taxa attribution. This process is known as macroscopic wood identification (MWI). The first to realize that wood looked different in its anatomical and macroscopic structure was Anton van Leeuwenhoek (1632–1723) [6], and the first MWI atlases date back to the beginning of the 20th century [4].
MWI is based on both wood anatomical characters, defined by the cellular structure of wood, and non-anatomical ones, determined by physical, chemical, or other wood characteristics. MWI is recognized as a reliable scientific method for wood identification [7] and is extensively adopted worldwide for various applications. Being a fast, cheap, and easy-to-apply method that does not require extensive wood anatomy knowledge, MWI is particularly interesting as a field tool for forensic wood identification. It represents an effective method for the first screening in applying international regulations such as the Lacey Act Amendment in the United States [8] and the European Regulation n. 995/2010, known as European Timber Regulation (EUTR) [9]. Many references [10,11,12,13] also testify to its usefulness in the first screening of CITES-listed woods.
More recently, several authors explored the potential of automating the process of MWI through the adoption of artificial neural networks [14]. This is of particular interest in the forensic field, where various factors currently hamper MWI: training of law enforcement officers is time-consuming, wood anatomy experts able to provide such training are scarce [14], and it is not so unlikely that trained officers can be changed of duty over time, leading to a relevant dispersion of resources.
This paper aims to describe and depict the macroscopic structure of wood based on its cellular foundation after summarizing the main references of traditional and computer vision MWI. This work provides a comprehensive guide to MWI by presenting state-of-the-art descriptions and images of each character, discussing their relevance for identification and providing hints and guidelines for their interpretation and use.
The authors directly acquired magnified transverse images with XyloScope [15], a digital wood imaging device developed by the Forest Products Laboratory of Madison, Wisconsin. All images in this paper have the same magnification, and each image represents a 6.35 × 6.35 mm area.

2. Traditional and Computer Vision Macroscopic Wood Identification References

As noted by the authors in [4], despite the century-long history and the wide number of references on MWI, variability in the number and nature of diagnostic characters used by different authors is relatively small. Still, their definitions and interpretation are often varying. For this reason, the authors in [4] standardized the characters and terminology used for traditional MWI. In the following text, macroscopic characters follow the terms and definitions provided by [4] as shown in Table 1.
To provide a general overview, Table 2 reports a selection of the most recent and representative references available for both traditional and artificial intelligence MWI. A proper comparison of the advantages and disadvantages of the two methods can be hardly provided without an in-depth analysis of computer vision-based systems. Deep learning, in fact, includes different techniques such as artificial neural networks, deep neural networks, recurrent neural networks, deep reinforcement learning, and convolutional neural networks, each with its own pros and cons when applied to wood. Additionally, there is great variability in the accuracy and reliability of the currently available systems. This topic is thoroughly analyzed in [14].

3. Wood Planes of Observation

For whatever purpose, and at any magnification, identifying wood requires adequately orientating it according to three anatomical planes of reference, dictated by its original position within the stem. These are the named transverse, longitudinal radial, and longitudinal tangential (Figure 1). The transverse and longitudinal planes are respectively perpendicular and parallel to the stem longitudinal axis. The transverse plane is the one across which a tree is cut when felled by a logger; the longitudinal planes are the ones along which a board is cut from a log in a sawmill. Taking the circumference described by the stem as a reference, a radial longitudinal plane is cut along the direction of a ray (see Figure 1). In contrast, a tangential longitudinal one is cut perpendicular to the direction of a ray.

4. Fundamental Differences between the Macroscopic Structure of Softwoods and Hardwoods

The macroscopic differences between softwoods and hardwoods are related to the different cell types among the two groups and the consequent appearance of their surfaces (Table 3).
Most of the wood in conifers consists of axial tracheids [1,35]. Parenchyma cells occupy a smaller fraction of conifer woods’ volume and are organized in the radial tissues (parenchyma rays) and, in a few species, in axial strands. Earlywood tracheids, being wider and thinner-walled compared to latewood tracheids, appear lighter in color in transverse and longitudinal sections. Even if of variable width, depending on the species and year-to-year variation of growing conditions, the latewood always appears darker in color [3]. Parenchyma rays in conifers are uniseriate and therefore not visible to the naked eye on transverse and tangential sections. However, on radial surfaces, especially those obtained by splitting—not sawing—the wood, parenchyma rays might be visible as linear ribbon-like shining structures. Axial parenchyma, either scattered or tangentially oriented, is hardly visible to the naked eye but detectable under a low magnification lens.
The wood of hardwoods is more heterogeneous and consists of vessels, fibers, fiber tracheids s.l., and axial and radial parenchyma [1,36]. Vessels are circular, oval to polygonal in the transverse section, and are differently organized within the ring boundaries. Fibers usually appear darker in color compared to the other cell types as seen in the transverse section, whereas fiber tracheids and axial parenchyma usually appear lighter-colored [3]. The appearance of rays varies with their width. Wide rays are visible in all observation planes, but smaller rays might be visible only on one surface. As a rule of thumb, only rays larger than 6–8 cells are visible to the naked eye on all the planes of observation, however, the overall color of the wood also influences their appearance.

5. Wood Color in Heartwood and Sapwood

Looking at a transverse section of a log, the wood of most recent formation lies on the outside, originating from underneath the bark, while older wood lies closer to the pith (i.e., the center of the stem). As the outermost wood still functions as a means of water and solute upward transport, the innermost wood has lost this function in old enough trees. The outermost and younger wood is called sapwood, while the heartwood is the innermost and older part of a stem. Sapwood is typically yellowish and light-colored, while heartwood can be either of the same shade as sapwood (e.g., Acer spp., Abies spp., Ochroma pyramidale, etc.) or darker (e.g., Quercus spp., Larix spp., Millettia spp., etc.), and therefore easily distinguishable from it (Figure 2).
The occurrence of extractives defines heartwood color and plays a crucial role in determining the aesthetic value of timber. While woods with brown, white, and gray hues are common, red, yellow, black, purple, pink, green, orange, and variegated ones are less common to rare (Table 4 and Figure 2). During MWI, cautiousness must be paid when evaluating wood color (Table 1, features 59 to 64) because it might have been altered by different factors: color can change from green to dry wood state, moreover, dry wood color is often subject to changes resulting from exposition to light and/or contact with oxygen (air) [3]; treatments can be applied to modify it, for instance, to minimize the difference between sapwood and heartwood, or to confer valuable tones [37,38].

6. Texture

The diameter of vessels and tracheids determines wood texture in hardwoods and softwoods, respectively. Vessel elements are tube-shaped cells with a diameter ranging from less than 0.05 mm (e.g., Buxus sempervirens) to over 0.5 mm (e.g., Cedrelinga catenaeformis) when the wood is sampled in the outer wood at the base of the stem of tall plants [39,40]. Vessel diameter is macroscopically divided into three classes (Table 1, features 19 to 21). However, the distinction between two close classes (small and medium or medium and large) may be difficult depending on the sample. In such cases, while performing an MWI, it is advisable to proceed by exclusion by ruling out only the class not included in the two possible ones.
A hardwood wood texture (Table 5) is defined as fine if vessels are too narrow to be visible to the naked eye (Table 1, feature 19), medium if vessels are barely visible (Table 1, feature 20), and coarse if vessels are visible (Table 1, feature 21) (Figure 3).
In softwoods, tracheids diameter is, on average, between 0.03 and 0.06 mm. Therefore, tracheids are not visible to the naked eye.

7. Wood Figure

The term ‘figure’ in wood refers to any distinctive pattern, design, or appearance visible on a longitudinal wood surface. The figure is determined by many anatomical structures, which are presented below.

7.1. Growth Rings

Each growing season, woody plants produce a new growth ring. Growth ring boundaries (Table 1, features 1 and 2) are visible to the naked eye on transverse surfaces as concentric circles in most temperate woods and several tropical ones. Growth rings are essential in defining the figure of wood since they draw hyperbola branches, or flames, on longitudinal tangential surfaces and parallel bands on radial surfaces (Figure 4), which are more evident the more pronounced the growth rings are. Growth rings are composed of earlywood and latewood: the more marked the transition between such portions, and the clearer the appearance of growth rings.
Growth rings are almost always distinct and visible in softwoods, while they can be indistinct in many tropical hardwoods. Caution should be paid when using growth rings for identification since their presence can be variable in several tropical hardwoods [41,42], and they can be difficult to detect macroscopically in numerous temperate ones (Table 6). Additionally, wide bands of parenchyma (e.g., Millettia spp.) and seemingly marginal bands of parenchyma (e.g., Swietenia spp.) (see “Section 7.2”) can be misinterpreted as growth ring boundaries.
The transition from earlywood to latewood can be described as abrupt or gradual in softwoods (Table 1, feature 56), with the latter being the most common one, and is marked by an increased tracheid wall thickness and smaller cell radial diameter. Tracheids are thin-walled with a wide lumen in earlywood and thick-walled with a smaller lumen in latewood. If the transition is abrupt, two distinct bands are macroscopically visible in the transverse section: a light-colored one corresponding to earlywood, and a dark-colored one corresponding to latewood. If the transition is gradual, the light-colored band blends into the dark-colored one (Figure 5). Growth rings and their consequent figures are usually more evident in woods with an abrupt transition.
Caution must be taken when using this feature for identification since many species have only one type of transition, either abrupt or gradual, but some others can present both of them (variable) depending on the growth ring (Table 7).
In hardwoods, the transition can be abrupt, gradual, or absent and is marked by porosity (Table 1, features 3 to 5), which is the difference in the diameter and density of vessel elements between earlywood and latewood. The transition is abrupt in ringporous woods, gradual in semi-ring porous woods, and absent in diffuse porous woods (Table 8).
A wood is ring-porous if earlywood vessels are distinctly larger than those in the latewood of the previous and same growth ring, and form a well-defined zone or ring, clearly discernible to the naked eye by its coarser texture (Figure 6). A finer analysis of the vessels of ring-porous woods’ earlywood can discriminate between species that present one row only (e.g., Carya ovata) or multiple ones (e.g., Castanea sativa) of earlywood vessels (Table 1, feature 6). Additionally, earlywood vessels on the same row can be packed together (widest tangential spacing less than one earlywood vessel, e.g., Gleditsia triacanthos) or be farther apart (widest tangential spacing more than one earlywood vessel, e.g., Paulownia tomentosa) (Table 1, feature 7). In ring-porous woods, the figure consequent to growth rings is usually evident (Figure 6).
Earlywood vessels’ diameter gradually narrows from earlywood to latewood (e.g., Juglans regia) in a semi-ring porous wood, or earlywood vessels are of the same diameter as latewood ones but much more closely spaced (e.g., Prunus avium) (Figure 6). To the naked eye, in the first case, it is still possible to see a difference in texture between earlywood and latewood, but without a clear boundary. In the second case, earlywood appears more porous than latewood. In semi-ring porous woods, the figure consequent to growth rings is visible but not evident (Figure 6).
Vessels have more or less the same diameter and density through earlywood and latewood in diffuse porous woods (Figure 6). Therefore, the two parts are indistinguishable both to the naked eye and at the microscope. It is the most common porosity type, as almost all tropical and most temperate species are diffuse-porous. In this case, growth rings can still be marked by other structural changes, such as the presence of marginal parenchyma (see “Section 7.2”) or of thick-walled radially flattened latewood fibers (see “density”) or of distinct fiber zones close to the ring boundary (see [43] for examples). These structural changes appear to the naked eye as a darker line that delimits two adjacent growth rings. In diffuse porous woods, the figure consequent to growth rings is usually faint or barely visible to not visible (Figure 6).
While most species have only one type of porosity, in some it may vary depending on the ring or the sample. Some examples are Dalbergia cearensis, Populus spp., and Salix spp., which can vary between diffuse porous and semi-ring porous, and Cedrela odorata, Tectona grandis, and Toona hexandra, which can vary between ring-porous and semi-ring porous.

7.2. Axial Parenchyma

Wood axial parenchyma cells are brick-shaped cells, alive in sapwood, and dead in the heartwood. They have the main axis vertically oriented, are stacked one upon each other in strands, and can be distributed according to many different patterns as seen in the transverse section.
In softwoods, they are usually so scarcely diffuse to be hardly visible to the naked eye, and therefore they do not contribute to determining any figure. However, in softwoods, axial parenchyma can be detected with a loupe as tiny dark spots on the transverse section and therefore be of help in MWI (Table 1, feature 58) (Table 9 and Figure 7). Be aware that resin spots can be easily mistaken for axial parenchyma, thus possibly deceiving the identifier.
When large enough, axial parenchyma aggregates are visible to the naked eye in hardwoods as lighter-colored areas on the transverse and longitudinal planes. In hardwoods, axial parenchyma can be distributed around vessels (paratracheal) or independently from them (apotracheal). Paratracheal distributions can be vasicentric, lozenge-aliform, and winged-aliform (Table 1, features 31 to 33). The type of distribution can be determined on a transverse plane, where the parenchyma around vessels appears as a round halo in the first case, like a diamond-shaped halo in the second case, and as a halo with narrow, elongated tangential extensions in the third case (Figure 8). When the parenchyma of two or more vessels merges, it is called confluent (Table 1, feature 34). If prominent enough, paratracheal parenchyma slightly contributes to the wood figure since it appears on longitudinal surfaces as a light-colored band along the vessels’ grooves (Figure 9). Apotracheal distributions range from single cells or short discontinuous lines of cells scattered among fibers (diffuse and diffuse-in-aggregates parenchyma) to more or less pronounced tangential bands (Table 1, features 29, 30, and 35 to 41) (Figure 8). When parenchyma bands are large enough to be visible to the naked eye, they appear as flames on longitudinal tangential surfaces and parallel bands on radial surfaces, like growth rings do (Figure 9). When parenchyma bands are particularly prominent, such as in Millettia spp., they can be mistaken for growth rings.
Axial parenchyma characterizes the transverse section pattern of numerous hardwoods, and is usually more abundant in tropical ones, thus proving to be very useful in the MWI of several woods (Table 10). While the more prominent forms of distribution (e.g., large bands or lozenges around big vessels) are easily visible to the naked eye, the more faint ones (e.g., diffuse or diffuse-in-aggregates) can be hardly distinguishable even with the aid of a loupe. Usually, a drop of water on the transverse surface greatly improves the visibility of axial parenchyma. Several woods have more than one type of distribution, while in some others, axial parenchyma is absent or rare.

7.3. Radial Parenchyma (Rays)

Radial parenchyma is composed of parenchyma cells grouped in band-like structures called rays. Rays are like walls oriented along the stem radial plane, usually several cm long, a few µm to a few mm wide, and 0.01 mm to several cm high.
Softwood rays are too narrow to be visible to the naked eye on transverse and longitudinal tangential planes. In contrast, they can be seen as faint horizontal stripes on longitudinal radial ones (Figure 10). Rays are, therefore, not useful for the MWI of softwoods.
Hardwoods rays’ dimension, instead, varies depending on the species. When large enough, other than being visible to the naked eye on the transverse plane as radial lines (Table 1, feature 43), they contribute to determining the wood figure [3]. In fact, rays appear as vertical lines on the longitudinal tangential plane (Table 1, features 44 and 48) and as horizontal stripes on the longitudinal radial. As in softwoods, they can still be seen on the longitudinal radial plane even when very narrow (Figure 10).
In hardwoods, rays can be storied, i.e., arranged in more or less regular horizontal tiers as viewed on the tangential plane (Table 1, feature 47). In such cases, they are always too small to be singularly visible to the naked eye but can confer fine horizontal striations, or ripple marks, on tangential surfaces (Figure 11). Storying is considered fine if there are 4 rows or more per axial millimeter, and coarse if the rows are 3 or fewer.
While in most tropical hardwoods, rays are not or barely visible, the occurrence of big rays easily visible on both transverse and tangential surfaces is much higher in temperate ones. On the contrary, storied rays are, with few exceptions, almost only present in tropical hardwoods (Table 11). As noted for axial parenchyma, a drop of water improves the visibility of tiny rays.
On the transverse surface, with the aid of a reference grid, the number of rays per mm (Table 1, feature 49) can be measured, as well as the ratio of ray width to pore diameter (Table 1, feature 45). In some species (such as Fagus sylvatica and Platanus occidentalis), rays are slightly swollen in correspondence with the growth-ring boundary (Table 1, feature 46), a character that can be seen with the aid of a loupe only (Figure 10).

7.4. Vessels’ Arrangement, Grouping, and Frequency

The arrangement of vessels usually does not impact wood figure, except when they are in wavy tangential bands, which can determine a characteristic jagged pattern on longitudinal tangential surfaces (e.g., Ulmus spp.) (Table 1, feature 8) (Figure 12). Other vessels’ arrangements include radial, diagonal, and dendritic patterns (Table 1, features 9 to 11). The presence of specific patterns in vessels’ arrangement is not very common, and thus not useful in MWI (Table 12). More than one arrangement can be present in the same species.
Vessels’ groupings do not contribute to determining wood figure, but are useful in MWI. They can be observed on the transverse surface with the aid of a loupe and can be: exclusively solitary (90% or more), in radial multiples of four or more, in clusters, and, most commonly, solitary and in radial multiples of 2 to 3 (Table 1, features 12 to 15) (Table 13 and Figure 13). Vessels’ grouping can be difficult to be accurately evaluated when vessels are small.
A particular type of “exclusively solitary vessels” grouping is “latewood pores large, individually distinct, and few enough that they can be readily counted” (Table 1, feature 22). This character is mainly used for the separation of the red oak group (which presents the character) from the white oak one (where the character is absent instead).
As noted for vessels’ groupings, also vessels’ frequency, i.e., the number of vessels per square mm, does not contribute to determining wood figure, but is a useful character for MWI (Table 1, features 16 to 18). Vessels’ frequency (Table 14) is applied in diffuse porous and semi-ring porous woods only and must be measured on the transverse plane, more accurately with the aid of a transparent reference grid. In some species (e.g., Celtis gomphophylla and Terminalia ivorensis), vesselless tangential bands can be present (Table 1, feature 23).

7.5. Grain

Grain refers to the longitudinal alignment or pattern of axial wood cells compared to the longitudinal axis. A straight-grained wood is one in which the longitudinal cells are aligned parallel to the axis of the log or timber and is the most common case.
Several grain deviations are responsible for highly appreciated decorative figures in wood (Figure 14). Interlocked grain occurs when axial elements are aligned at an angle to the vertical axis and such spirals reverse at intervals. This produces a ribbon stripe figure on longitudinal surfaces, which is particularly pronounced on quartersawn surfaces. If axial elements have instead a wavy arrangement along the vertical axis, the grain is defined as ‘wavy’ and the consequent figure, characterized by a horizontal pattern perpendicular to the grain, is called curly or fiddleback. A less common and extremely priced figure due to a peculiar wavy arrangement of axial elements is the quilt, characterized by seemingly bubbles on longitudinal surfaces. Burls are instead the consequence of an anomalous concentration of dormant buds that force axial cells to grow in a twisted direction, giving origin to highly decorative irregular figures. Finally, crotches form in correspondence of large tree forks.
Although these alterations of grain direction are usually characteristic of certain species (Table 15), their occurrence is occasional to rare depending on the alteration type and species. They are generally not useful in MWI, except for interlocked grain, that in some species is consistent enough to be considered an identification character (Table 1, feature 105).
On the one hand, these irregular grain patterns give distinctive and highly priced wood figures, but on the other hand they are usually responsible for lower mechanical performances, anomalous shrinkage, and processing difficulties [44]. This is the case also with any other grain deviation that does not produce any decorative pattern, the most common ones being spiral grain, where axial elements are aligned at an angle to the vertical axis, and deviations due to knots, where axial cells are diverted in the proximity of a branch, whose cells are, in turn, oriented perpendicular to the grain of the trunk grain. (Figure 15).

8. Superficial Marks

During heartwood formation processes, gums and tyloses may be deposited in vessel lumina in some species (Table 16). Vessel deposits (Table 1, features 25 to 28) include a wide variety of variously colored (white, yellow, red, brown, black) chemical compounds. They can be seen as spots on transverse surfaces and frequently determine colored streaks on longitudinal ones. Tyloses (Table 1, feature 24) are balloon-like structures that, being light-reflective, can be seen shining in the vessels on the transverse plane (Figure 16).
Intercellular canals may produce distinct marks on the wood surface, too. They are tube-shaped intercellular spaces, axially or radially oriented, found in both hardwoods and softwoods; they contain resin in the latter and several types of chemical compounds in the former. Radial canals are always included in rays and are usually extremely difficult to spot macroscopically both in softwoods and hardwoods.
Axial canals in softwoods (Table 1, feature 57) are usually scattered and can be seen on the transverse surface as tiny spots darker- or lighter-colored than the background tissue. The only softwood genera that present axial canals are Larix, Picea, Pseudotsuga, and Pinus. In the first three, they are small and difficult to see even with a loupe, and in such cases, a drop of water can enhance their visibility. In Pinus, they are big enough to be often visible as streaks on longitudinal surfaces, too (Figure 17). In softwoods, the presence of radial canals is restricted to the same genera that present axial canals.
Axial canals in hardwoods (Table 1, feature 52) can be found in some tropical species, with distributions that can vary from diffuse to short or long tangential lines (Table 17).
Axial canals in hardwoods can be identified on the transverse plane by their arrangement and/or by the presence of exudations, and they sometimes appear as streaks on longitudinal surfaces (Figure 18). In hardwoods, radial canals (Table 1, feature 54) are also found in tropical species, such as Antrocaryon spp., Astronium spp., Gluta renghas, and Mammea africana, but they are very hard to spot even with the aid of a loupe.
Some hardwoods and softwoods that do not have regular canals may still form so-called traumatic canals in response to traumatic events (Table 1, features 53 and 57b). They usually have an irregular outline and, being mostly larger than normal canals, are visible to the naked eye on both transverse and longitudinal planes, sometimes with the appearance of ‘scars’. This is, for instance, the case of several Eucalyptus spp., in which such traumatic canals are called ‘kino veins’ from the name of the gum they are filled with. Other examples of species that can present traumatic canals are Balfourodendron riedelianium, Cariniana micrantha, Cedrus spp., Erisma uncinatum, and Lovoa trichilioides (Figure 19).
Another possible source of superficial marks is the presence of included phloem (Table 1, feature 55), a quite uncommon feature in trees, that appears as diffuse (e.g., Aquilaria spp.) or concentric (e.g., Koompassia malaccensis) patches of bark included within the wood. Finally, some other marks of different origins may characterize the surfaces of some species (Table 1, feature 106), some of the most common ones being the pith flecks of Prunus serotina and Betula pendula (Figure 20).

9. Wood Density

Wood density (Table 1, feature 65) refers to the amount of actual wood substance (i.e., cell walls) present in a unit volume of wood, and is usually reported at a moisture content of 12%. It is a fundamental property, key for many wood end applications. With values that can range from <200 kg/m3 (e.g., Ochroma pyramidale) to >1200 kg/m3 (e.g., Dalbergia melanoxylon), its variability is much higher in hardwoods than in softwoods, where it ranges between 350 and 700 kg/m3 (Table 18).

10. Odor and Oily Surface

The presence of volatile heartwood extractives determines odor (Table 1, feature 66) that, depending on the wood, can be pleasant or unpleasant (Table 19). In several woods, the fragrance is quite characteristic and therefore very useful for identification, however, while it can be distinctively detected during wood processing, it usually fades away with wood aging.
The wood of some species, such as Tectona grandis, contains oily compounds which give a greasy feel to wood surfaces (Table 1, feature 67).

11. Heartwood Fluorescence and Other Extractives Properties

The heartwood of several hardwoods shows surface fluorescence when exposed to a UV lamp (Table 1, features 96 and 97). Clearly, it is recommended to perform the test in a darkened room. Fluorescence can be weak or strong, the most common colors being yellow and green [45] (Table 20). Heartwood fluorescence must always be tested on a freshly cut surface [36] since it fades away with exposure to light.
Hardwoods that do not present surface fluorescence can have fluorescent extractives when extracted in water or ethanol (Table 1, features 98 and 99). The test can be performed by putting a few shavings in a glass vial filled with some drops of water or ethanol. Attention must be paid when using this test for identification because some species have a well-defined and consistent extractives of color fluorescence, e.g., in Platymiscium spp., both water and ethanol extractives have a bright blue fluorescence [3]. In contrast, other species provide outcomes that vary depending on the sample, e.g., in Dalbergia oliveri, ethanol extractives have a yellowish-green or bluish-purple fluorescence depending on the origin of the sample [13]. Even higher variability may be present in the water and ethanol extractive color (Table 1, features 100 and 101); for instance, the ethanol extractives of Dalbergia stevensonii can be either violet, brown, yellow, or do not show any color depending on the sample [46]. In some species, instead, colors are consistent and thus helpful in identification, such as in the case of Paubrasilia echinata, whose gold-yellow ethanol extractives are quite peculiar [3].
Finally, the extractives of some hardwoods (e.g., all Vochysiaceae) react to the chrome azurol-S reagent by developing a blue color (Table 1, feature 104). The test can be performed by putting a few drops of the solution described in [36] on a freshly cut surface and checking if the stain becomes blue (it may take from a few minutes to a few hours depending on the species).

12. Conclusions

MWI is a fast, cheap, and easy-to-apply method extensively adopted worldwide in several fields, such as forensics, cultural heritage, and the forestry sector. This paper provides a comprehensive guide to MWI by presenting state-of-the-art descriptions and images of each character, discussing their relevance for identification, and providing hints and guidelines for their interpretation and use. This work is intended as a support to teach MWI in academic and vocational courses, and a guide for wood scientists, customs officers, wood restorers, wood sellers, foresters, and any person involved in wood identification.

Author Contributions

Conceptualization, F.R. and A.C.; methodology, F.R., F.N. and A.C.; investigation, F.R., F.N. and A.C.; writing—original draft preparation, F.R. and A.C.; writing—review and editing, F.R. and F.N.; supervision, F.R. and A.C. All authors have read and agreed to the published version of the manuscript.

Funding

This research received no external funding.

Data Availability Statement

Not applicable.

Acknowledgments

We hereby acknowledge Hans Beeckman (Royal Museum for Central Africa, Tervuren, Belgium) for providing wood specimens, and Alex C. Wiedenhoeft (USDA Forest Products Laboratory, Madison, WI, USA) for providing the XyloScope.

Conflicts of Interest

The authors declare no conflict of interest.

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Figure 1. Wood planes of observation. The transverse (Tr) plane is perpendicular to the stem longitudinal axis; the radial longitudinal (Rd) plane is parallel to the stem longitudinal axis and oriented along the direction of a ray of the circumference described by the stem; the tangential longitudinal (Tg) plane is parallel to the stem longitudinal axis and perpendicular to the direction of a ray of the circumference described by the stem.
Figure 1. Wood planes of observation. The transverse (Tr) plane is perpendicular to the stem longitudinal axis; the radial longitudinal (Rd) plane is parallel to the stem longitudinal axis and oriented along the direction of a ray of the circumference described by the stem; the tangential longitudinal (Tg) plane is parallel to the stem longitudinal axis and perpendicular to the direction of a ray of the circumference described by the stem.
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Figure 2. Sapwood and heartwood color. (A) heartwood color darker than sapwood color (Larix decidua); (B) heartwood and sapwood of the same color (Picea abies); (C) heartwood white (Aesculus hippocastanum); (D) heartwood brown (Tectona grandis); (E) heartwood yellow (Buxus sempervirens); (F) heartwood green (Bulnesia sarmientoi); (G) heartwood red (Pterocarpus soyauxii); (H) heartwood purple (Peltogyne paniculata); (I) heartwood black (Diospyros ebenum); (L) heartwood variegated (Microberlinia brazzavillensis).
Figure 2. Sapwood and heartwood color. (A) heartwood color darker than sapwood color (Larix decidua); (B) heartwood and sapwood of the same color (Picea abies); (C) heartwood white (Aesculus hippocastanum); (D) heartwood brown (Tectona grandis); (E) heartwood yellow (Buxus sempervirens); (F) heartwood green (Bulnesia sarmientoi); (G) heartwood red (Pterocarpus soyauxii); (H) heartwood purple (Peltogyne paniculata); (I) heartwood black (Diospyros ebenum); (L) heartwood variegated (Microberlinia brazzavillensis).
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Figure 3. Hardwood texture (longitudinal and transverse sections). (A1,A2): fine texture (Pyrus communis); (B1,B2): medium texture (Baillonella toxisperma); (C1,C2): coarse texture (Terminalia superba).
Figure 3. Hardwood texture (longitudinal and transverse sections). (A1,A2): fine texture (Pyrus communis); (B1,B2): medium texture (Baillonella toxisperma); (C1,C2): coarse texture (Terminalia superba).
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Figure 4. Growth rings appear as concentric circles on transverse surfaces ((A), Pinus echinata), as parallel bands on radial surfaces ((B), Pinus rigida), and as hyperbola branches, or flames, on longitudinal tangential surfaces ((C), Pinus taeda).
Figure 4. Growth rings appear as concentric circles on transverse surfaces ((A), Pinus echinata), as parallel bands on radial surfaces ((B), Pinus rigida), and as hyperbola branches, or flames, on longitudinal tangential surfaces ((C), Pinus taeda).
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Figure 5. Earlywood/latewood transition. Pseudotsuga menziesii is an example of abrupt transition ((A1), transverse section) and evident wood figure is ((A2), tangential section); Cupressus sempervirens is an example of gradual transition ((B1), transverse section) and faint wood figure ((B2), tangential section).
Figure 5. Earlywood/latewood transition. Pseudotsuga menziesii is an example of abrupt transition ((A1), transverse section) and evident wood figure is ((A2), tangential section); Cupressus sempervirens is an example of gradual transition ((B1), transverse section) and faint wood figure ((B2), tangential section).
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Figure 6. Wood porosity ((AF) transverse sections, (GI) tangential sections). (A) ring-porous, one row only of earlywood vessels, widest tangential spacing between earlywood vessels: more than one earlywood vessel (Carya ovata); (B) ring-porous, more than one row of earlywood vessels, widest tangential spacing between earlywood vessels: one earlywood vessel at most (Gleditsia triacanthos); (C) semi-ring porous, vessels’ diameter gradually narrows from earlywood to latewood (Juglans regia); (D) semi-ring porous, vessels are of the same diameter as latewood ones but much more closely spaced (Prunus avium); (E) diffuse porous, vessels are small (Acer rubrum); (F) diffuse porous, vessels are medium (Astronium graveolens). The figure consequent to growth rings is evident in ring-porous woods ((G) Fraxinus excelsior), visible in semi-ring porous woods ((H), Juglans regia), and faint in diffuse porous woods ((I), Betula pendula).
Figure 6. Wood porosity ((AF) transverse sections, (GI) tangential sections). (A) ring-porous, one row only of earlywood vessels, widest tangential spacing between earlywood vessels: more than one earlywood vessel (Carya ovata); (B) ring-porous, more than one row of earlywood vessels, widest tangential spacing between earlywood vessels: one earlywood vessel at most (Gleditsia triacanthos); (C) semi-ring porous, vessels’ diameter gradually narrows from earlywood to latewood (Juglans regia); (D) semi-ring porous, vessels are of the same diameter as latewood ones but much more closely spaced (Prunus avium); (E) diffuse porous, vessels are small (Acer rubrum); (F) diffuse porous, vessels are medium (Astronium graveolens). The figure consequent to growth rings is evident in ring-porous woods ((G) Fraxinus excelsior), visible in semi-ring porous woods ((H), Juglans regia), and faint in diffuse porous woods ((I), Betula pendula).
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Figure 7. Axial parenchyma distribution in softwoods (transverse sections). (A) scarce diffuse (Chamaecyparis lawsoniana); (B) tangentially zonate (Cryptomeria japonica); (C) absent (Araucaria angustifolia).
Figure 7. Axial parenchyma distribution in softwoods (transverse sections). (A) scarce diffuse (Chamaecyparis lawsoniana); (B) tangentially zonate (Cryptomeria japonica); (C) absent (Araucaria angustifolia).
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Figure 8. Axial parenchyma distribution in hardwoods (transverse sections). (A) vasicentric (Khaya ivorensis); (B) lozenge-aliform, confluent, and in marginal or seemingly marginal bands (Afzelia bipindensis); (C) winged-aliform and confluent (Gonystylus bancanus); (D) diffuse (Alstonia macrophylla); (E) diffuse-in-aggregates and vasicentric (Dalbergia retusa); (F) narrow bands and reticulate (Autranella congolensis); (G) wide bands (Millettia laurentii); (H) festooned and scalariform (Grevillea robusta); (I) absent (Salix alba).
Figure 8. Axial parenchyma distribution in hardwoods (transverse sections). (A) vasicentric (Khaya ivorensis); (B) lozenge-aliform, confluent, and in marginal or seemingly marginal bands (Afzelia bipindensis); (C) winged-aliform and confluent (Gonystylus bancanus); (D) diffuse (Alstonia macrophylla); (E) diffuse-in-aggregates and vasicentric (Dalbergia retusa); (F) narrow bands and reticulate (Autranella congolensis); (G) wide bands (Millettia laurentii); (H) festooned and scalariform (Grevillea robusta); (I) absent (Salix alba).
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Figure 9. If prominent enough, axial parenchyma appears on longitudinal surfaces as a light-colored band along the vessels’ grooves when paratracheal ((A) Afzelia bipindensis), and as seemingly growth rings when apotracheal in tangential bands ((B) Amphimas pterocarpoides).
Figure 9. If prominent enough, axial parenchyma appears on longitudinal surfaces as a light-colored band along the vessels’ grooves when paratracheal ((A) Afzelia bipindensis), and as seemingly growth rings when apotracheal in tangential bands ((B) Amphimas pterocarpoides).
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Figure 10. Rays’ visibility to the naked eye. In Quercus petraea, some of the rays are clearly more evident than the others on the transverse surface ((A1) transverse section), are visible on the tangential surface and over 5 mm high ((A2) longitudinal tangential surface), and visible on the radial surface ((A3) longitudinal radial surface); in Platanus occidentalis, rays are visible on the transverse surface and noded ((B1) transverse section), they are visible on the tangential surface and less than 5 mm high ((B2) longitudinal tangential surface), and visible on the radial surface ((B3) longitudinal radial surface); in Populus tremula, rays are not visible on either the transverse surface ((C1) transverse section) and the tangential surface ((C2) longitudinal tangential surface), while barely noticeable on the radial surface ((C3) longitudinal radial surface); in Pinus sylvestris, rays are not visible on either the transverse surface ((D1) transverse surface) and the tangential surface ((D2) tangential surface), while barely noticeable on the radial surface ((D3) longitudinal radial surface).
Figure 10. Rays’ visibility to the naked eye. In Quercus petraea, some of the rays are clearly more evident than the others on the transverse surface ((A1) transverse section), are visible on the tangential surface and over 5 mm high ((A2) longitudinal tangential surface), and visible on the radial surface ((A3) longitudinal radial surface); in Platanus occidentalis, rays are visible on the transverse surface and noded ((B1) transverse section), they are visible on the tangential surface and less than 5 mm high ((B2) longitudinal tangential surface), and visible on the radial surface ((B3) longitudinal radial surface); in Populus tremula, rays are not visible on either the transverse surface ((C1) transverse section) and the tangential surface ((C2) longitudinal tangential surface), while barely noticeable on the radial surface ((C3) longitudinal radial surface); in Pinus sylvestris, rays are not visible on either the transverse surface ((D1) transverse surface) and the tangential surface ((D2) tangential surface), while barely noticeable on the radial surface ((D3) longitudinal radial surface).
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Figure 11. Ripple marks determined by storied rays on a tangential section of Swietenia macrophylla.
Figure 11. Ripple marks determined by storied rays on a tangential section of Swietenia macrophylla.
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Figure 12. Vessels’ arrangement (all transverse sections except (E)). (A) tangential bands (latewood vessels only) (Ulmus glabra); (B) radial pattern (Ilex aquifolium); (C) diagonal pattern (Eucalyptus deglupta); (D) dendritic pattern (Bulnesia sarmientoi); (E) jagged pattern on longitudinal tangential surface determined by wavy tangential bands of latewood vessels (Ulmus glabra).
Figure 12. Vessels’ arrangement (all transverse sections except (E)). (A) tangential bands (latewood vessels only) (Ulmus glabra); (B) radial pattern (Ilex aquifolium); (C) diagonal pattern (Eucalyptus deglupta); (D) dendritic pattern (Bulnesia sarmientoi); (E) jagged pattern on longitudinal tangential surface determined by wavy tangential bands of latewood vessels (Ulmus glabra).
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Figure 13. Vessels’ groupings (transverse sections). (A) in radial multiples of 2–3 vessels (Hevea brasiliensis); (B) exclusively solitary (Quercus ilex); (C) radial multiples of 4 or more common (Dyera costulata); (D) clusters common (Celtis occidentalis).
Figure 13. Vessels’ groupings (transverse sections). (A) in radial multiples of 2–3 vessels (Hevea brasiliensis); (B) exclusively solitary (Quercus ilex); (C) radial multiples of 4 or more common (Dyera costulata); (D) clusters common (Celtis occidentalis).
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Figure 14. Decorative grain deviations. (A) interlocked grain (Entandrophragma candollei); (B) wavy grain (Acer sp.); (C) quilt (Pterocaprus sp.); (D) burl (Pterocarpus indicus); (E) burl (Ulmus campestris); (F) crotch (Juglans regia).
Figure 14. Decorative grain deviations. (A) interlocked grain (Entandrophragma candollei); (B) wavy grain (Acer sp.); (C) quilt (Pterocaprus sp.); (D) burl (Pterocarpus indicus); (E) burl (Ulmus campestris); (F) crotch (Juglans regia).
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Figure 15. (A) spiral grain is visible in the tree in the foreground, while it is not present in that in the background (Fagus sp.); (B) spiral grain in a softwood pole. Grain deviates around knots ((C) small knots on Larix decidua; (D) pair of knots on Castanea sativa).
Figure 15. (A) spiral grain is visible in the tree in the foreground, while it is not present in that in the background (Fagus sp.); (B) spiral grain in a softwood pole. Grain deviates around knots ((C) small knots on Larix decidua; (D) pair of knots on Castanea sativa).
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Figure 16. Vessel deposits (all transverse sections except (E), longitudinal section). Tyloses in the vessels of Robinia pseudoacacia (A) and Morus mesozygia (B); gums in the vessels of Swietenia humilis (C) and Lophira alata (D,E).
Figure 16. Vessel deposits (all transverse sections except (E), longitudinal section). Tyloses in the vessels of Robinia pseudoacacia (A) and Morus mesozygia (B); gums in the vessels of Swietenia humilis (C) and Lophira alata (D,E).
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Figure 17. Axial canals in softwoods (all transverse sections except (C)). (A) axial canals small (Picea engelmannii); (B) axial canals large (Pinus rigida); (C) vertical streaks on a longitudinal surface determined by axial canals (Pinus chihuahuana).
Figure 17. Axial canals in softwoods (all transverse sections except (C)). (A) axial canals small (Picea engelmannii); (B) axial canals large (Pinus rigida); (C) vertical streaks on a longitudinal surface determined by axial canals (Pinus chihuahuana).
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Figure 18. Axial canals in hardwoods (all transverse sections except (D)). (A) axial canals diffuse (Daniellia ogea); (B) axial canals in short tangential lines (Dipterocarpus alatus); (C) axial canals in long tangential lines (Shorea acuminata); (D) streaks on a longitudinal surface determined by axial canals (Prioria sp.).
Figure 18. Axial canals in hardwoods (all transverse sections except (D)). (A) axial canals diffuse (Daniellia ogea); (B) axial canals in short tangential lines (Dipterocarpus alatus); (C) axial canals in long tangential lines (Shorea acuminata); (D) streaks on a longitudinal surface determined by axial canals (Prioria sp.).
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Figure 19. Traumatic canals as they appear on the transverse section of Scleronema micranthum (A) and Cedrus atlantica (B), and on the longitudinal section of Cariniana micrantha (C) and Eucalyptus obliqua (D).
Figure 19. Traumatic canals as they appear on the transverse section of Scleronema micranthum (A) and Cedrus atlantica (B), and on the longitudinal section of Cariniana micrantha (C) and Eucalyptus obliqua (D).
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Figure 20. Diffuse included phloem on Aquilaria malaccensis ((A) transverse section) and pith flecks on Prunus serotina ((B) longitudinal section).
Figure 20. Diffuse included phloem on Aquilaria malaccensis ((A) transverse section) and pith flecks on Prunus serotina ((B) longitudinal section).
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Table 1. List of macroscopic features for hardwood and softwood identification according to [4]. MFN = macroscopic feature number, P = present, A = absent, V = variable, NA = not applicable, TR = Transverse section, TLS = Tangential longitudinal section, RLS = Radial longitudinal section.
Table 1. List of macroscopic features for hardwood and softwood identification according to [4]. MFN = macroscopic feature number, P = present, A = absent, V = variable, NA = not applicable, TR = Transverse section, TLS = Tangential longitudinal section, RLS = Radial longitudinal section.
StructurePropertyMFNCharacterCharacter States
Anato-mical featuresHardwoodGrowth ringsGrowth rings1Growth rings distinctP/A/V
2Growth rings per cmNumerical value/NA
VesselsPorosity3Diffuse porousP/A/V
4Semi-ring porousP/A/V
5Ring-porousP/A/V
6Number of rows of earlywood poresOne row/More than one row/V/NA
7Widest tangential spacing between earlywood vesselsOne earlywood vessel at most/More than one earlywood vessel
Arrangement8Vessels in tangential bandsP/A/V
9Vessels in radial patternP/A/V
10Vessels in diagonal pattern (echelon)P/A/V
11Vessels in dendritic pattern (flame-like)P/A/V
Groupings12Solitary and in radial multiples of 2–3 vesselsP/A/V
13Exclusively solitary (90% or more)P/A/V
14Radial multiples of 4 or more commonP/A/V
15Clusters commonP/A/V
Frequency16≤5 vessels per square mmP/A/V
176–20 vessels per square mmP/A/V
18>20 vessels per square mmP/A/V
Vessel diameter/Pore visibility19Small (not visible to the naked eye, less than 80 μm)P/A/V
20Medium (just visible to the naked eye, 80–130 μm)P/A/V
21Large (commonly visible to the naked eye, larger than 130 μm)P/A/V
Latewood pore visibility22Latewood pores large, individually distinct, and few enough that they can be readily countedP/A/V/NA
Vesselless bands23Vesselless tangential bandsP/A
Tyloses24Tyloses common (TR, TLS, RLS)P/A/V
Vessel deposits25Gums and other deposits in heartwood vessels (TR, TLS, RLS)P/A/V
26Deposits white (TR, TLS, RLS)P/A
27Deposits yellow (TR, TLS, RLS)P/A
28Deposits dark (TR, TLS, RLS)P/A
Axial parenchymaDistribution29DiffuseP/A/V
30Diffuse-in-aggregatesP/A/V
31VasicentricP/A/V/Unilateral
32Lozenge-aliformP/A/V/Unilateral
33Winged-aliformP/A/V/Unilateral
34ConfluentP/A/V/Unilateral
35BandedMajority wide/Majority narrow/V/A
36Banded parenchyma distributionThroughout the ring/In latewood only/In earlywood only/NA
37Parenchyma bands wider than raysP/A/V
38Parenchyma in marginal or seemingly marginal bandsP/A/V
39ReticulateP/A/V
40ScalariformP/A/V
41FestoonedP/A/V
42Predominant parenchyma pattern within the body of the ‘growth ring’A/Diffuse/Diffuse-in-aggregates/Vasicentric/Lozenge-aliform/Winged-aliform/Confluent/Ban-ded/In marginal or seemingly marginal bands/Reticulate/Scalariform/Festooned
RaysWidth43Ray visibility to the naked eye on the transverse sectionRays not visible/Rays visible/Some of the rays clearly more evident than the others
44Ray visibility with the naked eye on the tangential surface (TLS)Rays not visible/Rays visible
45Ratio of ray width to pore diameterLarger rays narrower than wider pores/Larger rays as wide or wider than wider pores
46Noded raysP/A/V
Storying47Ray storying (TLS)Not storied (absent)/Regular coarse storying/Regular fine storying/Irregular coarse storying/Irregular fine storying
Height48Ray height (TLS)Highest rays less than 5 mm high/Highest rays more than 5 mm high
Rays per mm49Rays per mm≤4 mm/5–12 mm/>12 mm/NA
Wood rayless50
FibersArrangement51Fibers in radial arrangementP/A
CanalsIntercellular canals52Axial canalsA/Diffuse/In short tangential lines/In long tangential lines/V
53Traumatic canalsP
54Radial canalsP/A
PhloemPhloem55Included phloemA/Diffuse/Concentric
SoftwoodGrowth ringsEarlywood/
Latewood transition
56Earlywood/Latewood transitionAbrupt transition from earlywood to latewood/Gradual transition from earlywood to latewood/V
Axial canalsAxial canals57Axial canalsLarge/Small/A
57bTraumatic canalsP
Axial parenchymaVisibility58Axial parenchyma visible with hand lensScarce diffuse/Tangentially zonate/A
Non- anato-mical featuresHardwood + SoftwoodHeartwoodColor59Heartwood color darker than sapwood colorP/A
60Heartwood basically brown or shades of brownP/A
61Heartwood basically red or shades of redP/A
62Heartwood basically yellow or shades of yellowP/A
63Heartwood basically white to grayP/A
64Heartwood with streaksP/A
Density65DensityDensity low: <0.40 g/cm3/Density medium: 0.40–0.75 g/cm3/Density high: >0.75 g/cm3
Odor66OdorA/Distinctly present and pleasant (sweet, spicy, floral)/Distinctly present and unpleasant (sour, bitter, fetid)
Oily surface67Oily surfaceP/A
Habit68TreeP/A/V
69ShrubP/A/V
70Vine/Liana/ClimberP/A/V
Geographical distribution71Europe and temperate Asia (Brazier and Franklin region 74)P/A
72Europe, excluding MediterraneanP/A
73Mediterranean including Northern Africa and Middle EastP/A
74Temperate Asia (China), Japan, USSRP/A
75Central South Asia (Brazier and Franklin region 75)P/A
76India, Pakistan, Sri LankaP/A
77BurmaP/A
78Southeast Asia and the Pacific (Brazier and Franklin region 76)P/A
79Thailand, Laos, Vietnam, Cambodia (Indochina)P/A
80Indomalesia: Indonesia, Philippines, Malaysia, Brunei, Singapore, Papua New Guinea, and Solomon IslandsP/A
81Pacific Islands (including New Caledonia, Samoa, Hawaii, and Fiji)P/A
82Australia and New Zealand (Brazier and Franklin region 77)P/A
83AustraliaP/A
84New ZealandP/A
85Tropical mainland Africa and adjacent islands (Brazier and Franklin region 78)P/A
86Tropical AfricaP/A
87Madagascar & Mauritius, Reunion & ComoresP/A
88Southern Africa (south of the Tropic of Capricorn) (Brazier and Franklin region 79)P/A
89North America, north of Mexico (Brazier and Franklin region 80)P/A
90Neotropics and temperate Brazil (Brazier and Franklin region 81)P/A
91Mexico and Central AmericaP/A
92CarribbeanP/A
93Tropical South AmericaP/A
94Southern BrazilP/A
95Temperate South America including Argentina, Chile, Uruguay, and S. Paraguay (Brazier and Franklin region 82)P/A
HardwoodHeartwoodFluorescence96Surface fluorescence colorA/Basically yellow/Basically green/Other colors/V
97Surface fluorescence intensityWeakly fluorescent/Strongly fluorescent/V/NA
Extractives98Water extract fluorescenceA/Basically blue/Basically green/Bluish-green/V
99Ethanol extract fluorescenceA/Basically blue/Basically green/Bluish-green/V
100Water extract colorColorless/Brown or shades of brown/Red or shades of red/Yellow or shades of yellow/Other shades
101Ethanol extract colorColorless/Brown or shades of brown/Red or shades of red/Yellow or shades of yellow/Other shades
Froth test102Froth after shaking in waterPositive/Weakly positive/A
Burning splinter test103Splinter burns to:Charcoal/Partial ash/Full ash (white)/Full ash (yellow-brown)/Full ash (other)
Chrome Azurol-S test104Chrome Azurol-S testPositive/Negative
Grain105Interlocked grainP
Surface marks106Surface marksPith flecks/Gum deposits/Kino veins/Pitch pockets/Latex traces/Resin veins
Table 2. List of recent references on macroscopic wood identification. The identification method is reported as traditional when performed by humans, and as machine vision when on an automated basis.
Table 2. List of recent references on macroscopic wood identification. The identification method is reported as traditional when performed by humans, and as machine vision when on an automated basis.
NameYearAreaTaxa (n)Method (Traditional/Machine Vision)References
Identification of Central American, Mexican, and Caribbean Woods2022Mexico, Central America, Caribbean138 speciesTraditional[16]
UTForest—UTFPR Classificador2021Brazil44 speciesTraditional[17]
Macroscopic wood identification key for Atlantic Forest species2021Brazil102 speciesTraditional[18]
Macroscopic wood identification key for Brazilian endangered species2021Brazil29 speciesTraditional[19]
Identification of Tree Species from the Peruvian Tropical Amazon “Selva Central” Forests According to Wood Anatomy2021Peru20 speciesTraditional[20]
Macroscopic wood identification key for Itatiaia National Park, RJ, Brazil2020Brazil41 speciesTraditional[21]
Field identification manual for Ghanaian timbers 2020Ghana102 speciesTraditional[22]
Atlas of macroscopic wood identification: with a special focus on timbers used in Europe and CITES-listed species2019Global292 genera
335 species
Traditional[3]
Forest Species Classifier2018Brazil112 speciesTraditional[23]
MacroHOLZdata2016Global150 speciesTraditional[24]
Forest Species
Database—Macroscopic
2014Brazil41 speciesTraditional[25]
Brazilian commercial timbers2010Brazil275 speciesTraditional[26]
CITESwoodID2005Various world regions 75 speciesTraditional[13]
Towards Sustainable North American Wood Product Value Chains, Part I: Computer Vision Identification of Diffuse Porous Hardwoods2022North America24 genera
105 species
Machine vision[27]
Towards sustainable North American wood product value chains, Part 2: computer vision identification of ring-porous hardwoods2022North America15 genera
68 species
Machine vision[28]
Wood identification based on longitudinal section images by using deep learning2021North America11 speciesMachine vision[29]
Wood species automatic identification from wood core images with a residual convolutional neural network2021Europe14 speciesMachine vision[30]
Machine vision for field-level wood identification2020Amazonia Atlantic region21 speciesMachine vision[31]
Rapid field identification of CITES timber species by deep learning2020Suriname14 speciesMachine vision[32]
Software for forest species recognition based on digital images of wood2018Brazil41 speciesMachine vision[33]
Forest species recognition using deep convolutional neural networks2014Brazil41 speciesMachine vision[34]
Table 3. List of macroscopic features of softwoods and hardwoods.
Table 3. List of macroscopic features of softwoods and hardwoods.
Macroscopic FeatureSoftwoodsHardwoods
Axial tracheidsPresentRare (fibre tracheids s.l.)
RaysNot visible to the naked eye on transverse and tangential planesIn several species visible to the naked eye on all three planes
VesselsAbsentPresent. In some species big enough to be seen by the naked eye
FibersAbsentPresent
CanalsPresent in some speciesPresent in some species
Appearance of growth rings Distinct in most speciesVariable
Table 4. Examples of species for different heartwood colors.
Table 4. Examples of species for different heartwood colors.
Heartwood ColorHardwoodsSoftwoods
White Acer spp., Carpinus betulus, Dyera costulata, Ilex aquifolium, Tilia cordataAbies spp., Picea spp.
BrownCarya ovata, Castanea sativa, Cordia dodecandra, Quercus spp., Tectona grandisAraucaria spp., Pinus spp.
YellowBerberis vulgaris, Buxus sempervirens, Chloroxylon swietenia, Zanthoxylum flavumAgathis spp., Cupressus spp.
GreenCholorocardum rodiei, Guaiacum officinale, Liriodendron tulipifera, Handroanthus spp., Pistacia spp.-
RedBrosimum rubescens, Paubrasilia echinata, Pterocarpus soyauxiiLarix decidua, Taxus baccata
OrangeCentrolobium spp., Dalbergia retusa, Pterocarpus dalbergioides-
PinkBerchemya zeyheri, Dalbergia decipularis-
PurpleDalbergia cearensis, Peltogyne spp.-
BlackDalbergia melanoxylon, Diospyros crassiflora, Diospyros ebenum-
VariegatedAstronium graveolens, Cordia dodecandra, Dalbergia nigra, Diospyros malabarica, Microberlinia brazzavillensis, Olea europaea, Zygia racemosa-
Table 5. Examples of species for fine, medium, and coarse textures (these texture types are commonly reported in literature, for instance in [41]).
Table 5. Examples of species for fine, medium, and coarse textures (these texture types are commonly reported in literature, for instance in [41]).
TextureHardwood Species
FineBuxus sempervirens, Fagus sylvatica, Machaerium scleroxylon, Paubrasilia chinate, Pericospsis elata, Pyrus communis, Santalum album
MediumAstromiun graveolens, Bowdichia nitida, Cordia dodecandra, Dipteryx odorata, Gonystylus bancanus, Mansonia altissima, Morus mesozygia
CoarseAfzelia spp., Aucoumea klaineana, Castanea sativa, Dalbergia stevensonii, Hevea brasiliensis, Hymenaea courbaril, Terminalia superba
Table 6. Examples of species for different growth rings’ occurrence and visibility.
Table 6. Examples of species for different growth rings’ occurrence and visibility.
Growth RingsHardwood Species
Distinct and clearly visibleCarya ovata, Cedrela odorata, Fagus sylvatica, Fraxinus excelsior, Juglans regia, Prunus avium, Quercus petraea, Tectona grandis, Ulmus glabra
Distinct but difficult to seeEucalyptus camaldulensis, Malus sylvestris, Olea europaea, Platanus orientalis, Pyrus communis
IndistinctAcacia koa, Brosimum alicastrum, Intsia bijuga, Khaya spp., Metopium brownei, Milicia spp., Millettia spp., Swietenia macrophylla
VariableAniba rosodora, Cordia dodecandra, Dalbergia cearensis, Dalbergia nigra, Santalum album, Tessmannia africana
Table 7. Examples of species for different types of transition in softwoods.
Table 7. Examples of species for different types of transition in softwoods.
TransitionSoftwood Species
AbruptLarix decidua, Pinus spp. (hard pines group), Pseudotsuga menziesii, Tsuga heterophylla
GradualAbies alba, Agathis australis, Araucaria angustifolia, Calocedrus decurrens, Cedrus atlantica, Chamaecyparis lawsoniana, Cryptomeria japonica, Cupressus sempervirens, Pinus spp. (soft pines group), Taxus baccata
VariableFitzroya cupressoides, Picea abies, Sequoia sempervirens, Taxodium distichum, Thuja plicata
Table 8. Examples of species for different types of porosity in hardwoods.
Table 8. Examples of species for different types of porosity in hardwoods.
PorosityHardwood Species
Ring-porous Carya ovata, Castanea sativa, Gleditsia triacanthos, Paulownia tomentosa, Quercus rubra, Robinia pseudoacacia, Ulmus minor
Semi-ring porousDalbergia decipularis, Juglans nigra, Juglans regia, Prunus avium, Prunus serotina, Pterocarpus indicus
Diffuse porousAcer pseudoplatanus, Amphimas pterocarpoides, Betula spp., Handroanthus spp., Intsia bijuga, Liriodednron tulipifera, Magnolia ovata, Pyrus communis
Table 9. Examples of species for different types of axial parenchyma distribution in softwoods.
Table 9. Examples of species for different types of axial parenchyma distribution in softwoods.
Axial Parenchyma DistributionSoftwood Species
Scarce diffuseCedrus atlantica, Chamaecyparis lawsoniana
Tangentially zonateCalocedrus decurrens, Cryptomeria japonica, Cupressus sempervirens, Fitzroya cupressoides, Podocarpus neriifolius, Thuja plicata
AbsentAbies alba, Araucaria angustifolia, Larix decidua, Picea abies, Pinus spp., Taxus baccata
Table 10. Examples of species for different types of axial parenchyma distribution in hardwoods.
Table 10. Examples of species for different types of axial parenchyma distribution in hardwoods.
Axial Parenchyma DistributionHardwood Species
AbsentAcer pseudoplatanus, Alnus glutinosa, Buxus sempervirens, Casearia praecox, Euxylophora paraensis, Nothofagus pumilio, Populus spp.
DiffuseAlstonia macrophylla, Aspidosperma polyneuron, Dillenia indica, Testulea gabonensis, Tetramerista glabra
Diffuse-in-aggregatesCarpinus betulus, Caryocar glabrum, Coula edulis, Dalbergia nigra, Heritiera utilis, Mammea Africana, Tilia cordata
VasicentricAcacia mangium, Antiaris toxicaria, Cordia dodecandra, Khaya ivorensis, Myroxylon balsamum, Newtonia leucocarpa
Lozenge-aliformAfzelia spp., Berlinia bracteosa, Dipteryx odorata, Hymenaea courbaril, Koompassia malaccensis, Mangifera indica
Winged-aliformBrosimum spp., Gonystylus spp., Jacaranda copaia, Poga oleosa, Simarouba amara, Tessmannia africana, Vochysia tetraphylla
ConfluentAndira coriacea, Dicorynia guianensis, Hymenolobium flavum, Leplaea cedrata, Milicia spp., Pterocaprus spp., Zygia racemosa
Narrow bandsAlstonia scholaris, Autranella congolensis, Cariniana legalis, Carya ovata, Diospyros spp., Dyera costulata, Hevea brasiliensis
Wide bandsAmphimas pterocarpoides, Clarisia racemosa, Ficus spp., Lophira alata, Millettia laurentii, Morus mesozygia, Swartzia cubensis
Marginal or seemingly marginal bandsCarapa guianensis, Chloroxylon swietenia, Gluta renghas, Swietenia macrophylla, Swintonia floribunda, Zanthoxylum flavum
ReticulateAlstonia scholaris, Autranella congolensis, Cariniana legalis, Chrysophyllum africanum, Diospyros spp., Lophira alata
ScalariformCeiba pentandra, Dyera costulata, Grevillea robusta, Hexalobus crispiflorus, Roupala montana, Sterculia rhinopetala
FestoonedGrevillea robusta, Roupala montana
Table 11. Examples of species for different ray features in hardwoods.
Table 11. Examples of species for different ray features in hardwoods.
Ray FeaturesHardwood Species
Rays not visible on the transverse surface Autranella congolensis, Baikiaea plurijuga, Betula pendula, Dalbergia spp., Populus spp., Pterocarpus spp.
Rays visible on the transverse surfaceAucoumea klaineana, Celtis adolfi-friderici, Entandrophragma spp., Ilex aquifolium, Prunus avium
Some of the rays clearly more evident than the others on the transverse surfaceAlnus glutinosa, Carpinus betulus, Fagus sylvatica, Gleditsia triacanthos, Quercus spp., Roupala montana
Rays not visible on the tangential surfaceAfzelia spp., Dalbergia spp., Dyera costulata, Gluta renghas, Juglans regia, Salix spp.
Rays visible on the tangential surface, less than 5 mm highAcer pseudoplatanus, Entandrophragma spp., Fagus sylvatica, Khaya spp., Platanus spp.
Rays visible on the tangential surface, over 5 mm highAlnus glutinosa, Carpinus betulus, Quercus spp., Scaphium macropodum
Rays storied, fineDalbergia spp., Guaiacum officinale, Handroanthus spp., Machaerium scleroxylon, Pterocarpus spp.
Rays storied, coarseAndira coriacea, Dipteryx odorata, Mansonia altissima, Millettia laurentii, Swietenia macrophylla
Table 12. Examples of species for different types of vessels’ arrangement.
Table 12. Examples of species for different types of vessels’ arrangement.
Vessels’ ArrangementHardwood Species
Tangential bandsCatalpa speciosa, Celtis australis, Gleditsia triacanthos, Grevillea robusta, Morus rubra, Roupala montana, Ulmus spp.
Radial patternAutranella congolensis, Baillonella toxisperma, Ilex aquifolium, Madhuca utilis, Manilkara bidentata, Palaquium obovatum
Diagonal pattern (echelon)Bulnesia sarmientoi, Calophyllum canum, Eucalyptus spp., Mammea africana, Tieghemella heckelii
Dendritic pattern (flame-like)Autranella congolensis, Bulnesia sarmientoi, Calophyllum canum, Castanea sativa, Quercus spp.
Table 13. Examples of species for different types of vessels’ groupings.
Table 13. Examples of species for different types of vessels’ groupings.
Vessels’ GroupingsHardwood Species
In radial multiples of 2–3 vesselsAcer pseudoplatanus, Amburana cearensis, Dalbergia spp., Erythrophleum ivorense, Fagus sylvatica, Hevea brasiliensis, Myroxylon balsamum
Exclusively solitary (90% or more)Buxus sempervirens, Eucalyptus camaldulensis, Guaiacum officinale, Malus sylvestris, Quercus ilex, Santalum album
Radial multiples of 4 or more commonAlnus glutinosa, Aquilaria malaccensis, Baillonella toxisperma, Dyera costulata, Manilkara bidentata, Parahancornia fasciculata
Clusters commonCatalpa speciosa, Gleditsia triacanthos, Gymnocladus dioicus, Morus rubra, Robinia pseudoacacia, Ulmus spp.
Table 14. Examples of species for different vessel frequencies.
Table 14. Examples of species for different vessel frequencies.
Vessels’ FrequencyHardwood Species
≤5 vessels per square mmBerlinia bracteosa, Dalbergia nigra, Hevea brasiliensis, Lophira alata, Ochroma pyramidale, Pterocarpus soyauxii
6–20 vessels/square mmCarapa guianensis, Entandrophragma cylindricum, Leplaea cedrata, Juglans regia, Swietenia macrophylla
>20 vessels/square mmAcer spp., Betula spp., Dalbergia cearensis, Hopea ferrea, Liriodendron tulipifera, Prunus avium
Table 15. Examples of species that may present decorative figures due to grain deviations.
Table 15. Examples of species that may present decorative figures due to grain deviations.
Decorative FigureSpecies
InterlockedChloroxylon swietenia, Entandrophragma cylindricum, Khaya spp., Lovoa trichilioides, Myroxylon balsamum, Turraeanthus africanus
Curly/FiddlebackAcer spp., Chloroxylon swietenia, Entandrophragma cylindricum., Fraxinus spp., Guibourtia spp., Juglans regia
QuiltAcer spp., Afzelia xylocarpa, Guibourtia tessmannii, Pterocarpus spp., Entandrophragma cylindricum.
BurlEucalyptus spp., Juglans regia, Pterocarpus indicus, Tetraclinis articulata, Ulmus spp.
CrotchAmburana cearensis, Juglans spp., Swietenia spp.
Table 16. Examples of species for different types of vessel deposits.
Table 16. Examples of species for different types of vessel deposits.
Vessel DepositsHardwood Species
TylosesBagassa guianensis, Carya ovata, Eucalyptus spp., Gluta renghas, Morus mesozygia, Quercus petraea, Robinia psuedoacacia
GumsAfzelia spp., Dalbergia spp., Intsia spp., Khaya spp., Lophira alata, Platymiscium spp., Pterocarpus spp., Swartzia spp.
Table 17. Examples of species for different types of axial canals’ distribution.
Table 17. Examples of species for different types of axial canals’ distribution.
Axial Canals’ DistributionHardwood Species
DiffuseAnisoptera spp., Daniellia spp., Detarium spp., Dipterocarpus spp., Prioria spp., Tessmannia spp., Vatica spp.
In short tangential linesDaniellia spp., Detarium spp., Dipterocarpus spp., Sindoropsis letestui, Tessmannia spp.
In long tangential linesCopaifera spp., Eperua spp., Hopea spp., Neobalanocarpus heimii, Shorea spp., Sindora spp.
Table 18. Examples of species for different wood density classes.
Table 18. Examples of species for different wood density classes.
Wood DensitySpecies
<400 kg/m3Aquilaria malaccensis., Bombax spp., Calocedrus decurrens, Ceiba pentandra, Ochroma pyramidale, Paulownia tomentosa, Thuja plicata
400–750 kg/m3Abies alba, Castanea sativa, Fagus sylvatica, Gmelina arborea, Juglans regia, Pinus spp., Quercus rubra, Tectona grandis
760–1000 kg/m3Afzelia spp., Baikiaea plurijuga, Buxus sempervirens, Dalbergia nigra, Koompassia malaccensis, Olea europaea, Peltogyne spp.
>1000 kg/m3Brosimum guianense, Dalbergia melanoxylon, Guaiacum officinale, Handroanthus spp., Manilkara bidentata, Zollernia paraensis
Table 19. Examples of species for different wood odors.
Table 19. Examples of species for different wood odors.
Wood OdorSpecies
Present and pleasant (sweet, spicy, floral)Aniba rosodora, Cedrela odorata, Cedrus spp., Cupressus spp., Juniperus spp., Myroxylon balsamum, Santalum album
Present and unpleasant (sour, bitter, fetid)Alstonia congensis, Dinizia excelsa, Gonystylus spp., Microberlinia brazzavillensis, Piptadeniastrum africanum
Table 20. Examples of species with different heartwood fluorescence.
Table 20. Examples of species with different heartwood fluorescence.
Heartwood FluorescenceHardwood Species
Yellow, strongAcacia mangium, Albizia ferruginea, Cedrelinga cateniformis, Dipteryx odorata, Robinia pseudoacacia
Yellow, weakBrachystegia zenkeri, Guibourtia tessmannii, Mangifera indica, Pentaclethra macrophylla
Green, strongBalfouridendron riedelianium, Dimorphandra polyandra
Green, weakCentrolobium robustum, Dinizia excelsa
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Ruffinatto, F.; Negro, F.; Crivellaro, A. The Macroscopic Structure of Wood. Forests 2023, 14, 644. https://doi.org/10.3390/f14030644

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Ruffinatto F, Negro F, Crivellaro A. The Macroscopic Structure of Wood. Forests. 2023; 14(3):644. https://doi.org/10.3390/f14030644

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Ruffinatto, Flavio, Francesco Negro, and Alan Crivellaro. 2023. "The Macroscopic Structure of Wood" Forests 14, no. 3: 644. https://doi.org/10.3390/f14030644

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Ruffinatto, F., Negro, F., & Crivellaro, A. (2023). The Macroscopic Structure of Wood. Forests, 14(3), 644. https://doi.org/10.3390/f14030644

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