The Science of Restoration Rorestry

A brief compilation by Mike Peterson, Inland Empire Lands Council

CAN LOGGING RESTORE OUR FORESTS - WHAT DOES THE SCIENCE SAY?

I have compiled a list of reasons why logging may not restore our forests, and included a bibliography. Hope you find it useful. It is attached as Restore.doc as well as at the bottom of this message. Thanks to Evan Frost, Tim Inglesbee, Rick Brown and others for a substantial part of this.

Timber harvest may increase insect activity and productivity and associated mortality to trees.

Timber harvest will remove dead and dying material from the site and inhibit the recruitment of downed woody material as time progresses.

Timber harvest and associated reduced structural complexity and reduced age and size class diversity are all known to reduce population abundance and diversity of ants and a number of birds. For instance, ants are documented to require downed woody material in a variety of sizes and in all stages of decomposition (Torgersen and Bull, 1995).

This is an attribute that is negatively correlated with harvest of the dead and dying trees and positively correlated with natural succession, especially after disturbance. Ants and birds are known to predate on insect species which cause mortality to trees, serving as a potentially important population control in the case of epidemics or before they occur (Campbell, Torgersen and Srivastava, 1983). Structural and functional characteristics associated with unlogged forests are also important for canopy arthropods, which play an important role in regulating pest outbreaks (Schowalter, 1989).

Structural complexity, functional diversity, diversity of ecological process and diversity of structure in roadless areas are all expected to be less susceptible to the outbreak of pests and regulate insect activity in surrounding homogenized forests (Schowalter and Means, 1989; Franklin, Perry, Schowalter, Harmon, McKee and Spies, 1989).

A large body of scientific evidence also indicates that increased edge effect and increased sunlight into stands, resulting from reduced canopy cover associated with timber harvest, can directly promote the population abundance, productivity and persistence of insects which cause mortality to trees of (Roland, 1993; Rothman and Roland, 1998; Kouki, McCullough and Marshall, 1997; Bellinger, Ravlin and McManus, 1989).

Establishing Historical Range of Conditions. Before restoration can occur on the logged lands, a more accurate assessment of the historic conditions must be made. The Interior Columbia Basin Ecosystem Project cites Hann, Jones, Karl, et al 1997 and gives a general discussion of succession and the disruptions by a century of Forest Service/BLM management in the interior Columbia basin, but implies a pre-settlement condition in forested stands such as the following statement (pg. 2-60, SDEIS) "... the open late seral single story forests changed to relatively dense late seral multi-story forests ..." While this may be the case in areas that have been heavily logged, we don’t believe this is generally accurate, and that the maps of changes in fire regime severity (pgs. 2-54 to 2-57) are based on unfounded assumptions.

A current example is the Olmstead timber sale, Prairie City Ranger District, Malheur National Forest. Here, much of the project is designed to create a single-stratum with large tree development, over one third of the entire project area is proposed for heavy thinning (Olmstead EA, Purpose of and Need for Action, April 26, 2000). Yet, 1924 photo points from the Skovlin/Thomas report (1995) pages 70-71, clearly show a thick stand at the edge of Lyman and Olmstead meadows, both in or near the project area.

The Douglas Fir beetle project in NE Washington and N. Idaho tells the same story. The FEIS discusses the need to log to increase resiliency to fire and insects, the prescription is stand conversion to a much lower basal area, yet the Lieberg report show pictures of this area over a hundred years ago as a thick stand of trees.

Every timber sale in the past few years in the interior West has claimed a need to return conditions to a "pre-settlement" status. We question the authenticity of this model and cite two references that seem to refute the idea that our forests were far more open. The John Lieberg reports,1897-9, part of the US Geological Surveys of the 1890’s indicate stand densities, species by type and size, and contain photographs and descriptions of forest reserves in North Idaho, including the Priest River, Bitterroot and Coeur d’Alene areas. They clearly show high stem densities, many snags and burnt areas and few open stands.

The Skovlin and Thomas report Interpreting Long-Term Trends in Blue Mountain Ecosystems from Repeat Photography, Pacific Northwest Research Station PNW GTR-315, June 1995, shows many photos from 60-80 years ago with stands that are very dense, as well as many stands that appear to be recently burned. In the case of both the USGS, John Lieberg reports and the Blue Mountain report there is little evidence of the widely spaced forest that current Forest Service timber sales are trying to attain. We believe the bias toward logging has corrupted forest managment and that an honest appraisal of stand succession, historic processes and desired future condition must be made.

Logging may spread insects and disease. At a staff meeting on October 6, 1998, in North Idaho, plans for the Douglas Fir Bark Beetle timber were discussed. One staff person stated "Seems to be a lot of the kill is in the areas that we actively manage", while another remarked that "I think our treatment could have an impact as well, especially if we’re talking about regeneration harvest."

On the Okanogan National Forest, the Forest Service had plans to log the Long Draw roadless area, David Greenwald stated the following in his paper, An evaluation of the Long Draw Salvage Timber Sale Using Fire Behavior and Effects Models, written in 1996:

"In conclusion, it is my opinion based on reading the literature and on this modeling exercise that there is no forest health crisis in the Long Draw area and salvage logging does little to nothing to increase the long-term resilience of these forests to stand destroying fires or insect outbreaks."

With regards to the spread of insects and disease, the following is from the Fish Bate Timber Sale analysis file, Lolo National Forest, Idaho/Montana, page 152:

Repeated intermediate harvests, partial harvesting, or uneven-age management, such as economic selection cutting or sanitation/salvage cutting could increase both the frequency and severity of root diseases in stands. Even one harvest entry in stands has been found to greatly increase the frequency of root disease compared with stands that have not had tree harvest entries. Studies have shown a doubling of root disease frequency in stands on the Lolo National Forest in Montana with at least one harvest entry compared to those with no history of tree harvest.

Logging Increases Fire Risk. The Sierra Nevada Ecosystem Project summary states that, "more than any other human activity, logging has increased the risk and severity of fires by removing the cooling shade of trees and leaving flammable debris." (Status of the Sierra Nevada, Vol. 1., Assessment of Summaries and Management Strategies, pg. 62. Sierra Nevada Ecosystem Project; "As a by-product of clearcutting, thinning, and other tree-removal activities, activity fuels create both short- and long-term fire hazards to ecosystems...Even though these hazards (with logging slash) diminish, their influence on fire behavior can linger for up to 30 years in the dry forest ecosystems of eastern Washington and Oregon.". (M.H. Huff and others, 1995. U.S. Forest Service).

"Fires in unroaded areas are not as severe as in roaded areas because of less surface fuel… Many of the fires in the unroaded areas produce a forest structure that is consistent with the fire regime, while the fires in the roaded areas commonly produce a forest structure that is not in sync with the fire regime. Fires in the roaded areas are more intense, due to drier conditions, wind zones on the foothill/valley interface, high surface-fuel loading, and dense stands". (Interior Columbia Basin Project, Hann et al. 1997.

Logging Isn’t Needed on Our National Forests. A recent scientific review team, led by Wenatchee Forest Service Research Station Scientists Paul Hessburg and John Lemkuhl, has found that on dry sites (which include much of the intermountain west), the use of prescribed fire alone would restore tree stocking levels and can be implemented on a broad range of cases without prior thinning. - Science Peer-Review Summary of the Wenatchee National forest’s Dry Forest Strategy, June 1999.

The available evidence indicates that logging operations, even when carefully conducted, can result in numerous adverse environmental impacts, including:

Unmanaged, Roadless Areas Provide Important Habitat. The Summary of Scientific Findings for the Interior Columbia Basin Ecosystem Management Project (PNW-GTR-385) found that undeveloped, roadless areas are important for providing habitat for native fish and water quality; are economically valuable to society; and are in relatively good ecological condition. "Because roads crisscross so many forested areas in Eastside (Columbia Basin), existing roadless regions have enormous ecological value. Existing roadless regions offer important sanctuary.

Roadless regions constitute the least-human-disturbed forest and stream systems, the last reservoirs of ecological diversity, and the primary benchmarks for restoring ecological health and integrity." Rhodes, McCullough and Espinosa 1994.

Roads Damage Streams. "Roads may have unavoidable effects on streams, no matter how well they are located, designed or maintained. The sediment contribution to streams from roads is often much greater than that from all other land management activities combined, including log skidding and yarding." (Gibbons and Salo 1973). Research by Megahan and Kidd in 1972 found that roads built in areas with highly erosive soils can contribute up to 220 times as much sediment to streams as intact forests.

Helicopter logging is a poor alternative to building logging roads into roadless areas. Not only are helicopters very expensive to operate, helicopter logging can also contribute sediment to streams. Megahan (1987) found that sediment delivery from helicopter logging and prescribed burning increased sediment delivery by more than 100% in a watershed where 75 foot buffers were provided.

Helicopter logging also fragments the forest landscape, dries out the soil, and destroys important wildlife habitat.

Thinning Dries Out Forests. "Dr. James Agee's (1996) research has demonstrated that reducing groundfuels is the most effective treatment to prevent crownfires, while thinning tree canopies results in hotter, drier, windier conditions on the ground surface." (Dr. Timothy Ingalsbee). According to Forest Service Chief Mike Dombeck, 87% of areas at high risk for catastrophic fire on National Forest lands are in roaded areas, while only 13% in roadless areas. The Sierra Nevada Ecosystem Project Report (USFS 1996) states that "Mechanical treatments fail to mimic the numerous ecological effects of fire."

LITERATURE CITED

  • Agee, J.K. 1997. Severe fire weather: Too hot to handle? Northwest Science 71: 153-156.
  • Bellinger, R. G., F. W. Ravlin and M. L. McManus. 1989. Forest edge effects and their influence on gypsy moth (Lepidoptera: Lymantriidae) egg mass distribution. Environmental Entomology 18: 840-843.
  • Beschta, R.L. 1978. Long-term patterns of sediment production following road construction and logging in the Oregon Coast Range. Water Resources Research 14: 1011-1016.
  • Beschta, R.L., C.A. Frissell, R. Gresswell, R. Hauer, J.R. Karr, G.W. Minshall, D.A. Perry,and J.J. Rhodes. 1995. Wildfire and salvage logging: Recommendations for ecologically sound post-fire salvage logging and other post- fire treatments on federal lands in the West. Pacific Rivers Council, Eugene, OR. 16 pp.
  • Campbell, R. W., T. R. Torgersen and N. Srivastava. 1983. A suggested role for predaceous birds and ants in the population dynamics of the western spruce budworm. Forest Science 29: 779-790.
  • Fahnestock, G.R. 1968. Fire hazard from pre-commercially thinning ponderosa pine. USDA Forest Service, Pacific Northwest Region Station, Research Paper 57. Portland, OR. 16 pp.
  • Filip, G.M. 1994. Forest health decline in central Oregon: A 13-year case study. Northwest Science 68(4): 233-240.
  • Clearwater National Forest. 1998. Fish Bate Timber Sale Analysis File, page 152.
  • Forest Ecosystem Management Assessment Team (FEMAT). 1993. Forest Ecosystem Management: An ecological, economic, and social assessment. Report of the Forest Ecosystem Management Assessment Team. July 1993. Portland, OR.
  • Franklin, J. F., D. A. Perry, T. D. Schowalter, M. E. Harmon, A. McKee and T.A. Spies. 1989. Importance of ecological diversity in maintaining long-term site productivity. pp. 82-97 in Maintaining the Long-Term Productivity of Pacific Northwest Forest Ecosystems. D. A. Perry, R. Meurisse, B. Thomas, R. Miller, J. Boyle, J. Means, C.R. Perry, R. F. Powers, eds. Timber Press, Portland, Oregon.
  • Grant, G.E., and A.L. Wolff. 1991. Long-term patterns of sediment transport after timber harvest, western Cascade Mountains, Oregon, USA. Pages 31-40 in Sediment and stream water quality in a changing environment: Trends and explanations. IAHS Publication 203. Proceedings of the Symposium, 11-24 August 1991, Vienna, Austria.
  • Greenwald, David, 1996, An evaluation of the Long Draw Salvage Timber Sale Using Fire Behavior and Effects Models.
  • Hagle, S., and R. Schmitz. 1993. Managing root disease and bark beetles. Pages 209-228 in T.D. Schowalter and G.M. Filip eds. Beetle-Pathogen Interactions in Conifer Forests. Academic Press, New York.
  • Hann, W.J. et al. 1997. Landscape dynamics of the Basin. Pp. 337-1,055 in: Quigley, T.M. and S.J. Arbelbide (eds.). An Assessment of Ecosystem Components in the Interior Columbia Basin and Portions of the Klamath and Great Basins: Volume II. USDA Forest Service Pacific Northwest Research Station Gen. Tech. Rep. PNW-GTR-405. Portland, OR.
  • Harvey, A.E., J.M. Geist, G.I. McDonald, M.F. Jurgensen, P.H. Cochran, D. Zabowski, and R.T. Meurisse. 1994. Biotic and abiotic processes in Eastside ecosystems: the effects of management on soil properties, processes, and productivity. General Technical Report PNW-GTR-323, U.S. Forest Service, Pacific Northwest Research Station.
  • Henjum, M.G., J.R. Karr, D.L. Bottom, D.A. Perry, J.C. Bednarz, S.G. Wright, S.A. Beckwitt, and E. Beckwitt. 1994. Interim protection for late-successional forests, fisheries, and watersheds: National forests east of the Cascades crest, Oregon and Washington. The Wildlife Society Technical Review 94-2, Bethesda, MD. 245 pp.
  • Huff, M.H., R.D. Ottmar, E. Alvarado, R.E. Vihnanek, J.F. Lehmkuhl, P.F. Hessburg, and R.L. Everett. 1995. Historical and current landscapes in eastern Oregon and Washington. Part II: Linking vegetation characteristics to potential fire behavior and related smoke production. USDA Forest Service Pacific Northwest Forest and Range Experiment Station, PNW-GTR- 355. Portland, OR.
  • Husari, S.J. and K.S. McKelvey. 1996. Fire-management policies and programs. Pp. 1101-1114 in: Status of the Sierra Nevada: Sierra Nevada Ecosystem Project Final Report to Congress Volume II. Wildland Resources Center Report No. 37. Center for Water and Wildland Resources. Univ. of California, Davis.
  • Kouki, J., D. G. McCullough and L. D. Marshall. 1997. Effect of forest stand and edge characteristics on the vulnerability of jack pine stands to jack pine budworm (Choristoneura pinus pinus) damage. Canadian Journal of Forest Research 27: 1765-1772.
  • Lehmkuhl, J.F. et al. 1995. Assessment of terrestrial ecosystems in eastern Oregon and Washington: The Eastside Forest Ecosystem Health Assessment. Pp. 87-100 in: R.L. Everett and D.M. Baumgartner, eds. Symposium Proceedings: Ecosystem Management in Western Interior Forests. May 3-5, 1994, Spokane, WA. Washington State University Cooperative Extension, Pullman, WA.
  • McKelvey, K.S. et al. 1996. An overview of fire in the Sierra Nevada. In: Status of the Sierra Nevada: Sierra Nevada Ecosystem Project Final Report to Congress Volume II. Wildland Resources Center Report No. 37. Center for Water and Wildland Resources. University of California, Davis.
  • Megahan, W.F, L.L. Irwin, and L.L. LaCabe. 1994. Forest roads and forest health. Pages 97-99 in R.L. Everett, ed. Volume IV: Restoration of Stressed Sites, and Processes. General Technical Report PNW-GTR-330, U.S. Forest Service, Pacific Northwest Research Station.
  • Meurisse, R.T. and J.M. Geist. 1994. Conserving soil resources. Pages 50-58 in R.L. Everett, ed. Volume IV: Restoration of Stressed Sites, and Processes. General Technical Report PNW-GTR-330, U.S. Forest Service, Pacific Northwest Research Station.
  • Roland, J. 1993. Large-scale forest fragmentation increases the duration of tent caterpillar outbreak. Oecologia 93: 25-30.
  • Rothman, L. D. and J. Roland. 1998. Forest fragmentation and colony performance of forest tent caterpillar. Ecography 21: 383-391.
  • Schowalter, T. D. and J. E. Means. 1989. Pests link site productivity to the landscape. pp. 248-250 in Maintaining the Long-Term Productivity of Pacific Northwest Forest Ecosystems. D. A. Perry, R. Meurisse, B. Thomas, R. Miller, J. Boyle, J. Means, C.R. Perry, R. F. Powers, eds. Timber Press, Portland, Oregon.
  • Skovlin, John M. and Thomas, Jack Ward, 1995, Interpreting Long-Term Trends in Blue Mountain Ecosystems from Repeat Photography, Pacific Northwest Research Station PNW GTR-315.
  • Sierra Nevada Ecosystem Project (SNEP). 1996. Status of the Sierra Nevada: Sierra Nevada Ecosystem Project, Final Report to Congress Volume I, Assessment summaries and management strategies. Wildland Resources Center Report No. 37. Center for Water and Wildland Resources. University of California, Davis, CA. (Status of the Sierra Nevada, Vol. 1., Assessment of Summaries and Management Strategies, pg. 62. Sierra Nevada Ecosystem Project; pg. 62. Sierra Nevada Ecosystem Project.
  • U.S. Department of Agriculture and U.S. Department of Interior (USDA/USDI). 1997. Eastside Draft Environmental Impact Statement, Interior Columbia Basin Ecosystem Management Project. USDA Forest Service, Pacific Northwest Region, and USDI Bureau of Land Management, Oregon and Washington.
  • U.S. Deparment of Agriculture and U.S. Department of Interior (USDA/USDI). 1995. Federal Wildland Fire Management Policy and Program Review: Final report. U.S. Department of Agriculture and U.S. Department of Interior, Washington, D.C.
  • Weatherspoon, C.P. and C.N. Skinner. 1996. Landscape-level strategies for forest fuel management. Pp. 1471-1492 in: Status of the Sierra Nevada: Sierra Nevada Ecosystem Project Final Report to Congress Volume II. Wildland Resources Center Report No. 37. Center for Water and Wildland Resources. University of California, Davis.
  • Wenatchee National Forest, Science Peer-Review Summary of the Wenatchee National forest’s Dry Forest Strategy, Paul Hessburg and John Lemkuhl, June 1999.
  • Wilson, C.C. and J.D. Dell. 1971. The fuels buildup in American forests: A plan of action and research. Journal of Forestry. August.