- Trees raised specifically for pulp production account for 16% of world pulp production, old growth forests 9% and second- and third- and more generation forests account for the balance.  Reforestation is practiced in most areas, so trees are a renewable resource.
- Pulpwood is also used as the raw material for some wood products, such as oriented strand board (OSB).[ citation needed]
- There is an increasing demand for pulpwood as a source of 'green energy' by the bio-energy sector for burning and baking into charcoal.[ citation needed]
The fiber length of the cellulose fiber is the most important parameter of the pulpwood and determines what it may be used for. The first separation is into softwood and hardwood, that have long and short fibers respectively. In paper production fiber from softwood give tensile strength and fibers from hardwood give opacity.
In the logging of mixed forest stands, the better trees are usually used for sawlogs for lumber production, while the inferior trees and components are harvested for pulpwood production. Pulpwood usually derives from four types of woody materials in a mixed logging operation:
- Open-grown trees, that are heavily branched low on the trunk, and so make poor sawlogs.
- Dead or diseased trees.
- Tops cut from trees harvested for sawlogs (branches are rarely used since they contain little usable wood after the bark has been removed).
- Small trees, too small to harvest for sawlogs.
Natural forest stands may also be harvested solely for pulpwood where, for various reasons, the value of the trees as sawlogs is low. This may be due to the predominant species in the forest stand (for example, some aspen forests in northern North America), or to the relative proximity of the nearest sawmill or pulp mill.
Pulpwood is also harvested from tree farms established for the specific purpose of growing pulpwood, with little or minimal sawlog production. Monoculture of species intended specifically for pulpwood include loblolly and slash pines in the southern USA; various species of eucalyptus (most commonly Eucalyptus globulus and Eucalyptus grandis) in Latin America, Iberian Peninsula, Australia, south-east Asia  and southern Africa and acacia (most commonly Acacia mangium) in south-east Asia and southern Africa.
Salvage cuts after forest fires, tornadoes, hurricanes, or other natural disasters are often used for pulpwood. An alternative source of wood for use in Kraft pulping is recovered lumber from demolition, industrial processing of wood and wooden pallets. 
Saw residuals are used as pulp wood. The most important of these are the side cuttings from lumber edger. This gives wood with almost only sapwood and no heartwood. The sapwood is easier to pulp.  due to a more open structure and less content of extractive than the heartwood. The fiber length of sapwood is generally longer than the fiber length of heartwood. The sapwood is also normally lighter and that is an advantage when producing mechanical pulp as less Bleaching of wood pulp bleaching is needed.
Earlier sawdust had some limited use in paper production. It gives very short fibers that are suitable as part of the furnish for paper tissue and writing papers. Saw blades have become thinner and with smaller teeth making the sawdust too small as fiber source. 
|Chemical composition of pulpwood  (%)|
- Martin, Sam (2004). "Paper Chase". Ecology Communications, Inc. Archived from the original on 2007-06-19. Retrieved 2007-09-21.
- Kittisiri, Areerat (1996-06-02). Impacts of Monoculture: The Case of Eucalyptus Plantations in Thailand. Monoculture: Environmental and Social Effects and Sustainable Alternatives Conference. Songkhla, Thailand. Archived from the original on 2006-02-07. Retrieved 2007-10-16.
- Ahmed, Aziz; Akhtar, Masood; Myers, Gary C.; Scott, Gary M. (1998). "Kraft Pulping of Industrial Wood Waste" (PDF). TAPPI Pulping Conference, Montreal. pp. 993–1000. Archived (PDF) from the original on 2007-12-03. Retrieved 2007-10-16.
- Gullichsen, Johan; Paulapuro, Hannu, eds. (1999). "3". Forest Products Chemistry. Paper making Science and Technology. 6A. Helsinki, Finland: Capet YO. p. 298. ISBN 952-5216-06-3.
- Biermann, Christopher J. (1993). Essentials of Pulping and Paper making. San Diego: Academic Press, Inc. p. 22. ISBN 0-12-097360-X.
- Robert Summit, Alan Sliker. 1980. "Handbook of Materials Science, Volume IV: Wood". Florida: CRC Press, Inc.