| longleaf | 187 | 180 | | red | 161 | 154 | | sugar | 168 | 189 | | western yellow | 162 | 187 | | white | 144 | 160 | | Spruce, Engelmann | 110 | 135 | | Tamarack | 167 | 159 | |---------------------------------------------|

PART II FACTORS AFFECTING THE MECHANICAL PROPERTIES OF WOOD

INTRODUCTION

Wood is an organic product—­a structure of infinite variation of detail and design.[17] It is on this account that no two woods are alike—­in reality no two specimens from the same log are identical.  There are certain properties that characterize each species, but they are subject to considerable variation.  Oak, for example, is considered hard, heavy, and strong, but some pieces, even of the same species of oak, are much harder, heavier, and stronger than others.  With hickory are associated the properties of great strength, toughness, and resilience, but some pieces are comparatively weak and brash and ill-suited for the exacting demands for which good hickory is peculiarly adapted.

[Footnote 17:  For details regarding the structure of wood see Record, Samuel J.:  Identification of the economic woods of the United States.  New York, John Wiley & Sons, 1912.]

It follows that no definite value can be assigned to the properties of any wood and that tables giving average results of tests may not be directly applicable to any individual stick.  With sufficient knowledge of the intrinsic factors affecting the results it becomes possible to infer from the appearance of material its probable variation from the average.  As yet too little is known of the relation of structure and chemical composition to the mechanical and physical properties to permit more than general conclusions.

RATE OF GROWTH

To understand the effect of variations in the rate of growth it is first necessary to know how wood is formed.  A tree increases in diameter by the formation, between the old wood and the inner bark, of new woody layers which envelop the entire stem, living branches, and roots.  Under ordinary conditions one layer is formed each year and in cross section as on the end of a log they appear as rings—­often spoken of as annual rings.  These growth layers are made up of wood cells of various kinds, but for the most part fibrous.  In timbers like pine, spruce, hemlock, and other coniferous or softwood species the wood cells are mostly of one kind, and as a result the material is much more uniform in structure than that of most hardwoods. (See Frontispiece.) There are no vessels or pores in coniferous wood such as one sees so prominently in oak and ash, for example.  (See Fig. 22.)

[Illustration:  FIG. 22.—­Cross sections of a ring-porous hardwood (white ash), a diffuse-porous hardwood (red gum), and a non-porous or coniferous wood (eastern hemlock).  X 30. Photomicrographs by the author.]