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A Guide to Soil Quality Monitoring for Long Term Ecosystem Sustainability on Northern Region National Forests
NITROGEN FIXATION IN FOREST SOILS OF THE INLAND NORTHWEST
ABSTRACT
Significant amounts of soil nitrogen (N) are lost from the soil during timber harvesting and related activities. Symbiotic N-fixing plants have the potential to replace much of these N losses on many sites in the Inland Northwest, especially during early stand development. However, many of these plants are site specific and can cause competition problems during stand establishment. Much more information is needed on the successional roles of N-fixing plants in Inland Northwest forests. Nonsymbiotic N fixation in forest soils of this region is low, but is an important source of N on sites where N-fixing plants are lacking or of low frequency. Appreciable amounts of N can be added to the soil by nonsymbiotic N fixation over long stand rotation ages typical for this region. Silvicultural systems need to be developed that minimize soil N losses and maintain the biological N fixation potential of the site.
INTRODUCTION
Timber harvesting and subsequent site preparation methods used in western forests can cause significant reductions in the levels of nitrogen (N) in forest soils (Cromack and others 1979; Page-Dumroese and others, these proceedings). The use of prescribed burns could greatly increase such soil N losses (Little and Klock 1985; Little and Ohmann 1988; Macadam 1987; Wells and others 1979). Nitrogen is required for tree growth in greater amounts than any other mineral nutrient, and is usually the nutrient most limiting in western forest soils (Edmonds and others 1989). Nitrogen is unique among the soil nutrients because it is present almost entirely in organic forms. No inorganic soil reserve is normally present to alleviate losses of N due to natural or human-caused factors (Wollum and Davey 1975).
Replacement of soil N lost due to forest management practices or wildfire in the Inland Northwest can come from four sources: (1) N present in precipitation and dry deposition, (2) biological N fixation by microorganisms living in plant roots (symbiotic N fixation), (3) N fixation by free-living soil microorganisms (nonsymbiotic N fixation), and (4) N fertilizers. The contribution of each will vary depending on forest age and vegetation type, site location, and management practices. Rainfall can add in excess of 20 kg/ha/yr to sites influenced by industrialized areas, but amounts normally average between 0.5 and 2 kg N/ha/yr in the Inland Northwest (Clayton and Kennedy 1985; Fahey and others 1988; Tiedemann and others 1978). Although some N fertilization trials have been conducted in this region (for example, Graham and Tonn 1985; Shafii and others 1989), widespread fertilizer applications are not presently considered economically feasible.
Symbiotic N fixation has the potential to add significant amounts of N to forest soils of the Inland Northwest. Nitrogen-fixing plants are amenable to manipulation by forest managers and could be considered when developing silvicultural prescriptions, especially those emphasizing forest biodiversity. However, as will be shown, many N-fixing plants are quite site specific, and can cause considerable problems for conifer regeneration. Nonsymbiotic N fixation rates in forest soils are quite low, but this N source is likely critical on sites where N-fixing plants are lacking.
SYMBIOTIC NITROGEN FIXATION
Nitrogen-fixing plants found in forests of the Inland Northwest are grouped into two categories: (1) plants in the family Leguminosaenine genera, and (2) nonleguminous plantsfive genera from four different families (table 1). The distribution patterns of these N-fixing plants generally reflect soil moisture/temperature conditions and stand successional stage. Early seral forests usually have greater shrub and herb development than late seral-climax forests, and would give a different picture of N-fixing plant distribution and importance.
| Nonleguminous plants |
|---|
| 1Information from Pfister and others (1977); Steele and others (1981, 1983); Cooper and others (1987). |
| Betalaceae |
| Alnus incana (L.) Moench A. rubra Bong. A. sinuata (Regel) Rydb. |
| Elaeagnaceae |
| Shepherdia canadensis (L.) Nutt. |
| Rhamnaceae |
| Ceanothus sanguineus Pursh C. velutinus Dougl. |
| Rosaceae |
| Cercocarpus ledifolius Nutt. Purshia tridentata (Pursh) DC. |
| Leguminous plants |
|
Astragalus adsurgens Hook. A. agrestis Dougl. A. alpinus L. A. atropubescens Coult. & Fish. A. canadensis L. A. drummondii Hook. A. kentrophyta Gray A. miser Dougl. Hedysarum boreale Nutt. H. occidentalis Greene H. sulphurescens Rydb. Lathyrus bijugatus White L. nevadensis Wats. L. ochroleucus Hook. L. pauciflorus Fern. Lotus nevadensis (Wats.) Greene Lupinus spp. L. argenteus Pursh L. caudatus Kell. L. laxiflorus Dougl. L. lepidus Dougl. L. leucophyllus Dougl. L. polyphyllus Lindl. L. sericeus Pursh L. wyethii Wats. Oxytropis sericea Nutt. Thermopsis montana Nutt. Trifolium gymnocarpon Nutt. T. kingii Wats. T. latifolium (Hook.) Greene T. longipes Nutt. T. parryi Gray Vicia americana Muhl. |
Late Seral-Climax Stands
Legumes are more widely distributed than nonleguminous N-fixing plants in late seral-climax stands throughout the Inland Northwest. Studies in Idaho, Montana, and Wyoming have shown the genus Lupinus to be the most common N-fixing plant across all habitat types, while species of Oxytropis and Lotus were found only in scattered locations (tables 2 and 3). Shepherdia was the most frequently occurring nonleguminous N-fixing plant, although Alnus and Purshia were common in certain habitat types. Purshia was restricted to the drier sites, while Alnus was found in cooler, wetter stands. Ceanothus showed a scattered distribution in these late seral-climax stands, especially in Idaho. Ponderosa pine (Pinus ponderosa Laws.) and Douglas-fir (Pseudotsuga menziesii [Beissn.] Franco) sites had the greatest occurrence of N-fixing plants, which likely reflects their more open stand structure.
| N-fixing plant | Climax series (Percent of stands in which genus found) |
|||||||
|---|---|---|---|---|---|---|---|---|
| Pinus flexilis (24)2 |
Pinus ponderosa (81) |
Pseudotsuga (415) |
Picea (100) |
Abies grandis (30) |
Thuja (42) |
Tsuga (36) |
Abies lasiocarpa (682) |
|
| 1Data are from late
seral-climax forest stands (Pfister and others 1977). 2Total number of stands examined within each habitat series. |
||||||||
| Nonlegumes | ||||||||
| Alnus | 0 | 0 | 23 | 17 | 17 | 12 | 14 | 15 |
| Ceanothus | 0 | 3 | 5 | 0 | 7 | 0 | 0 | 1 |
| Purshia | 4 | 23 | 7 | 0 | 0 | 0 | 0 | 0 |
| Shepherdia | 33 | 10 | 23 | 37 | 20 | 10 | 11 | 13 |
| Legumes | ||||||||
| Astragalus | 54 | 26 | 27 | 3 | 0 | 0 | 0 | 6 |
| Hedysarum | 21 | 5 | 6 | 12 | 7 | 0 | 0 | 5 |
| Lathyrus | 0 | 0 | 1 | 7 | 0 | 0 | 0 | 1 |
| Lupinus | 21 | 41 | 35 | 16 | 13 | 5 | 3 | 18 |
| Oxytropis | 4 | 4 | 1 | 0 | 0 | 0 | 0 | 0 |
| Trifolium | 0 | 0 | 1 | 2 | 0 | 0 | 0 | 2 |
| Vicia | 4 | 17 | 3 | 10 | 0 | 2 | 8 | 1 |
| N-fixing plant | Climax series (Percent of stands in which genus found) |
|||||||||
|---|---|---|---|---|---|---|---|---|---|---|
| Pinus flexilis (34)2 |
Pinus ponderosa (99) |
Pseudotsuga (709) |
Abies grandis (381) |
Thuja (269) |
Tsuga heterophylia (153) |
Picea (119) |
Tsuga mertensiana (103) |
Abies lasiocarpa (963) |
Pinus albicaulis (53) |
|
| 1Data are from
late seral and climax forest stands (Cooper and others 1987; Steele
and others 1981, 1983). 2Total number of stands examined within each habitat series. |
||||||||||
| Nonlegumes | ||||||||||
| Alnus | 0 | 0 | <1 | 3 | 3 | 1 | 3 | 3 | 3 | 0 |
| Ceanothus | 6 | 13 | 14 | 10 | 5 | 2 | 0 | 0 | 1 | 0 |
| Cercocarpus | 9 | 3 | 4 | 0 | 0 | 0 | 0 | 0 | 0 | 0 |
| Purshia | 9 | 36 | 8 | <1 | 0 | 0 | 0 | 0 | <1 | 6 |
| Shepherdia | 9 | 2 | 8 | 2 | 0 | 3 | 34 | 0 | 20 | 23 |
| Legumes | ||||||||||
| Astragalus | 53 | 7 | 14 | 4 | 3 | 0 | 37 | 0 | 8 | 28 |
| Hedysarum | 20 | 5 | 2 | 0 | <1 | 0 | 10 | 2 | 5 | 7 |
| Lathyrus | 0 | 15 | 3 | 11 | 7 | <1 | 0 | 0 | <1 | 0 |
| Lotus | 0 | 8 | 0 | 0 | 0 | 0 | 0 | 0 | 0 | 0 |
| Lupinus | 6 | 41 | 17 | 4 | <1 | 1 | 3 | 2 | 18 | 23 |
| Oxytropis | 8 | 0 | 0 | 0 | 0 | 0 | 0 | 0 | 0 | 2 |
| Thermopsis | 0 | 2 | <1 | 14 | 10 | 0 | 0 | 2 | 2 | 0 |
| Trifolium | 0 | 9 | 3 | 6 | 3 | <1 | 3 | 0 | 2 | 2 |
| Vicia | 0 | 16 | 4 | 6 | 4 | 0 | 0 | 0 | <1 | 0 |
Although species of at least one nitrogen-fixing plant occurred in all but six of the 115 habitat types examined in Montana, Idaho, and Wyoming, these plants are not major understory components in most older Inland Northwest forests. Even when several N-fixing species are found on the same site, as often happens, the combined effect rarely averages more than 10 percent canopy coverage (Jurgensen and others 1979). However, some genera are so predominant on certain sites they have been designated the understory indicator for the habitat type: Pinus flexilis/ Cercocarpus ledifolius (PIFL/CELE), Pinus ponderosa/Purshia tridentata (PIPO/PUTR), Pseudotsuga menziesii/Cercocarpus ledifolius (PSME/CELE), and Abies lasiocarpa/Alnus sinuata (ABLA/ALSI).
Early Seral Stands
Much less information is available on the distribution and frequency of N-fixing plants in early seral stands across the region. Most studies have been very site specific and usually detail early successional development after a disturbance, such as timber harvesting or fire. Ceanothus has received particular attention since it often becomes abundant after prescribed burns or wildfires. Ceanothus seed, which can remain viable in the soil for up to 200 years, requires a heat treatment to break dormancy (Noste and Bushey 1987). Reports of Ceanothus canopy coverage on burned sites in Idaho and Montana have ranged from less than 5 percent to over 80 percent (Arno and others 1985; Brown and DeByle 1989; Cholewa and Johnson 1983; Lyon 1971; Mueggler 1965; Noste 1985; Stickney 1980, 1986; Zamora 1975). Generally the hotter and more complete the burn, the greater the development of Ceanothus from buried seed (Noste and Bushey 1987; Orme and Leege 1976).
Other N-fixing plants would also be expected to increase after site disturbance, as part of the general increase in understory vegetation. However, few reports are available on the distribution of these plants in young stands of the Inland Northwest. Separate studies in northern Idaho cedar (Thuja plicata Donn ex D. Don)-hemlock (Tsuga heterophylla [Raf.] Sarg.) habitat types have reported Alnus to be either more common or more restricted after burning (Mueggler 1965; Stickney 1986; Wittinger and others 1977). In Montana, Stickney (1980) noted that Alnus frequency was reduced on subalpine fir (Abies lasiocarpa [Hook.] Nutt.) sites after prescribed burning, but this species is commonly observed on road cuts or other scarified sites (Arno and others 1985). Growth and population density of Purshia are generally reduced after prescribed burns and wildfires in the Northern Rocky Mountains (Noste and Bushey 1987; Wagstaff 1980). Shepherdia showed a slight reduction in canopy coverage after a prescribed burn in a mixed aspen (Populus tremuloides Michx.)-conifer stand in western Wyoming (Brown and DeByle 1989). Both Purshia and Shepherdia are common mid-seral forest plants in central Idaho habitat types (Steele and Geier-Hayes 1987, 1989).
Little is known about legume distribution after forest disturbance. Some Lupinus species are fire survivors that are able to maintain themselves in the initial stages of plant succession after fire. Lyon and Stickney (1976) observed that species of Lupinus were abundant after wildfire in southwestern Montana. Canopy coverage of Lupinus was little changed after wildfire in a northern Idaho cedar-hemlock stand (Stickney 1986), or following prescribed burns in aspen or mixed aspen-conifer stands of eastern Idaho and northwestern Wyoming (Brown and DeByle 1989). Astragalus miser occurred in one of these Wyoming stands prior to burning, and was not present 4 years later. However, Astragalus canadensis became abundant following broadcast burning on grand fir (Abies grandis [Dougl. ex D. Don] Lindl.) sites in northern Idaho and northeastern Oregon and maintained a sizable population for at least 20 years (Zamora 1975). Trifolium was found on disturbed and burned sites in northern Idaho, but showed a rapid decline as the successional plant community developed (Mueggler 1965; Stickney 1986). Two species of Hedysarum responded strongly to burning and mechanical site preparation in Douglas-fir and subalpine fir habitat types in western Montana, while Astragalus and Lupinus did not (Arno and others 1985). Several nitrogen-fixing legumes (Astragalus, Lupinus, and Thermopsis) are important successional components of several central Idaho habitat types (Steele and Geier-Hayes 1987, 1989). The scattered and incomplete nature of these studies indicates that much more information is needed on the successional roles of N-fixing plants in this region.
Nitrogen Additions
Little information is available on the actual contribution of N-fixing plants to the N economy of Inland Northwest forests. The scattered distribution and low numbers of N-fixing plants in most late seral-climax stands suggests that annual N gains on such sites would be small. Fahey and others (1985) estimated that a Lupinus argenteus density of 1,000 plants/ha in older, southeastern Wyoming lodgepole pine (Pinus contorta Dougl. ex Loud.) stands would add only 0.1 kg N/ha/yr. Lupinus growing in Utah aspen stands were reported to fix 0.6 kg N/ha/yr (Skujins and others 1987).
In contrast, much greater amounts of N could be added by N-fixing plants in successional forests. Studies on moist, highly productive sites in western Oregon and Washington have reported additions up to 100 kg of N/ha/yr from Ceanothus and Alnus, which became established on cut or burned sites (Conard and others 1985; Kimmins and others 1985). Much less information is available on the generally drier sites in the Inland Northwest, but indications are that N gains from N-fixing plants are lower. Youngberg and Wollum (1976) estimated N gains from Ceanothus velutinus (70 percent canopy cover) on a clearcut central Oregon ponderosa pine site to be 72 kg N/ha/yr over a 10-year period. A similar 11-year-old stand of Ceanothus velutinus (64 percent canopy cover) in northeastern Oregon was reported to fix 32 kg N/ha/yr (McNabb and others 1979). Lupinus arcticus (21,600 stems/ha) growing on a cutover lodgepole pine site in southern British Columbia was estimated to fix 2 kg N/ha/yr (Hendrickson and Burgess 1989). Shepherdia was also present on this site and added an additional 0.75 kg N/ha/yr.
The presence of N-fixing plants on a site in high numbers does not necessarily mean that significant amounts of N are being fixed. Dalton and Zobel (1977) estimated that less than 0.1 kg N/ha/yr was added to ponderosa and lodgepole pine stands in central Oregon by understories of Purshia (20 percent canopy cover). The amount of light reaching the soil surface and soil moisture levels during the growing season are critical factors in determining N-fixing plant activity (Sprent and Sprent 1990).
NONSYMBIOTIC NITROGEN FIXATION
The occurrence of N-fixing plants in most habitat types in the Inland Northwest should not obscure the fact that these plants are lacking or of low frequency on many sites (tables 2 and 3). On these sites, nonsymbiotic N-fixation becomes an important source of N to replace N lost from timber harvesting.
Nonsymbiotic N-fixation rates are strongly related to soil organic matter contents, being much higher in woody residue and surface organic layers than in mineral soil (table 4). Organic matter is required as an energy source for most N-fixing microorganisms (Jurgensen and Davey 1970), and has a high water-holding capacity. However, when these N-fixing rates were multiplied by soil weight/volume ratios to obtain the total amount of N fixed for each soil component, N gains in mineral soil also became important. This was especially evident on a cedar-hemlock site in Idaho, which had mineral soil N-fixation rates 500-600 percent greater than three sites in Montana (table 4). Favorable temperatures and moisture in the fertile northern Idaho ash cap soil encouraged the incorporation of surface organic matter into the mineral soil. Such higher organic matter levels would stimulate the activity of N-fixing bacteria (Granhall and Lindberg 1980).
| Soil component | Subalpine fir (Montana) |
Cedar-hemlock (Montana) |
Douglas-fir (Montana) |
Cedar-hemlock (Montana) |
||||
|---|---|---|---|---|---|---|---|---|
| 1Nanograms (10−9)
of N fixed/g of soil/day from June-October
1977 as measured by the acetylene reduction technique using a 3:1 ethylene
to N conversion ratio. 2Total N fixed/ha over a 180-day period. Mineral soil sampled to a depth of 30 cm. |
||||||||
| ng N/d1 | g N2 | ng N/d | g N | ng N/d | g N | ng N/d | g N | |
| Wood residue | 21.0 | 515 | 15.6 | 230 | 18.6 | 159 | 35.2 | 1,428 |
| Forest floor | 32.5 | 328 | 15.7 | 192 | 12.1 | 101 | 14.0 | 88 |
| Soil wood | 26.3 | 250 | 7.0 | 91 | 9.1 | 95 | 19.1 | 178 |
| Mineral soil | .7 | 379 | .6 | 326 | .6 | 442 | 4.0 | 1,197 |
| Total | 1,472 | 839 | 797 | 2,891 | ||||
Nitrogen Gains
The amounts of N fixed by nonsymbiotic N fixation in forest soils of the Inland Northwest generally reflect site productivity (table 4). Of the four old-growth stands examined, the highest N gain was found in a very productive, northern Idaho cedar-hemlock stand, and the lowest in a dry Douglas-fir stand in western Montana. These N-fixation differences were related to amounts of surface organic materials on each site, especially large woody residue (table 5). The greater the woody residue loadings on a site, the greater the N gains. On warm, dry sites, the accumulation of woody residue and other surface organic matter is reduced. Consequently, total N fixation on dry sites is lower than on wetter, more productive sites, while the proportion of N fixed in the mineral soil of these drier sites is greater.
| Soil component | Subalpine fir (Montana) |
Cedar-hemlock (Montana) |
Douglas-fir (Montana) |
Cedar-hemlock (Montana) |
||||
|---|---|---|---|---|---|---|---|---|
| 1Dry weight (metric
tonnes/ha) of organic material on top of mineral soil. 2Percentage of total N fixation shown in table 4. |
||||||||
| Mg1 | % N fix2 | Mg | % N fix | Mg | % N fix | Mg | % N fix | |
| Wood residue | 145.7 | 35 | 83.2 | 27 | 45.1 | 20 | 154.3 | 49 |
| Forest floor | 36.0 | 22 | 49.7 | 23 | 26.3 | 13 | 23.2 | 3 |
| Soil wood | 35.9 | 17 | 50.5 | 11 | 37.0 | 12 | 47.9 | 7 |
| Mineral soil | — | 26 | — | 39 | — | 55 | — | 41 |
The residue weights for the stands shown in table 4 are higher than regional averages for the Inland Northwest (Jurgensen and others 1987). Therefore, N fixation in woody residue on the majority of sites in this region would likely be lower than the results presented here. However, on many sites with heavy residue loadings, such as in overmature stands on moist sites or after a recent harvest, N gains could be much higher.
The results shown in tables 4 and 5 are from measurements taken during one year—1977. Longer term measurement of soil N-fixation rates has shown considerable annual variation (table 6). These N-fixation differences were related to yearly fluctuations in soil temperature and moisture. The highest N gains were obtained in a cool, wet year (1976), while the lowest were measured in a warm, dry year (1980). Surprisingly, the average N fixation for these three stands over this 5-year period was quite similar. However, these values do not include N fixation in woody residue.
| Year | Subalpine fir (g N/ha/180d) |
Cedar-hemlock (g N/ha/180d) |
Douglas-fir (g N/ha/180d) |
|---|---|---|---|
| 1Nitrogen fixed in the forest floor, soil wood, and the surface 30 cm of mineral soil as measured by the acetylene reduction technique. | |||
| 1976 | 1,246 | 1,817 | 1,496 |
| 1977 | 957 | 609 | 638 |
| 1978 | 348 | 309 | 346 |
| 1980 | 130 | 209 | 307 |
| 1981 | 1,097 | 985 | 832 |
| Average | 756 | 786 | 724 |
Many studies have tried to estimate the amounts of nonsymbiotic N fixation in forest soils of different timber types. Values in the literature range from <0.1 to 55 kg N/ha/yr (Boring and others 1988; Dawson 1983; Kimmins and others 1985), but most studies in the Western United States have reported N-fixation rates of <2 kg N/ha/yr (table 7). A direct comparison of these results is difficult due to the different soil layers tested and the various experimental conditions used to measure N fixation. Also, most of these studies were conducted for relatively short times (1 year or less), and as shown in table 6, annual fluctuations in N fixation can be considerable.
| Forest type | Location | Source | N fixation kg N/ha/yr |
Reference1 |
|---|---|---|---|---|
| 1(1)Sollins and others 1987; (2) Silvester and others 1982; (3) Jurgensen and others 1987; (4) this papertable 4; (5) Heath and others 1988; (6) Larsen and others 1978; (7) Harvey and others 1989; (8) Cushon and Feller 1989; (9) Fahey and others 1985; (10) Skujins and others 1987. | ||||
| Douglas-fir | ||||
| old growth | Oregon | Woody residue | 1.0 | 1 |
| old growth | Oregon | Woody residue | 1.4 | 2 |
| old growth | Montana | Woody residue, forest floor, mineral soil |
0.8 | 4 |
| various ages | Montana | Woody residue | 0–1.0 | 3 |
| 23 yr old | Oregon | Forest floor | 0.4–1.1 | 5 |
| Subalpine fir | ||||
| old growth | Montana | Woody residue | 0.7 | 6 |
| various ages | Montana | Woody residue | 0–1.7 | 3 |
| various ages | Montana | Woody residue, forest floor, mineral soil |
1.5 | 4 |
| Cedar-hemlock | ||||
| old growth | Idaho | Woody residue, forest floor, mineral soil |
2.9 | 4 |
| old growth | Montana | Woody residue, forest floor, mineral soil |
0.8 | 4 |
| various ages | Idaho | Woody residue | 0–4.3 | 3 |
| various ages | Montana | Woody residue | 0–1.8 | 3 |
| Mixed conifer | ||||
| various ages | Idaho | Living trees | <0.1–4.8 | 7 |
| 120 yr old | British Columbia | Woody residue, leaves, bark, forest floor, mineral soil |
0.3 | 8 |
| Lodgepole pine | ||||
| 80 yr old | Wyoming | Woody residue | <0.2 | 9 |
| Aspen | ||||
| mature | Utah | Forest floor, mineral soil | <0.5 | 10 |
Harvesting Impacts
Nonsymbiotic N fixation is especially susceptible to harvesting impacts, since it is dependent on adequate organic matter supplies. The greater the amounts of organic matter removed or destroyed by timber harvesting and site treatments, the greater the possible reduction in N fixation. This effect was studied on a clearcut cedar-hemlock site in northern Idaho that had four harvest/site preparation treatments (table 8). The largest decrease in N fixation (63 percent) occurred after the prescribed burn, which removed 62 percent of the forest floor, soil wood, and woody residue. Slash removal by a bulldozer lowered N fixation by 48 percent, while clearcutting without any site preparation reduced N fixation by only 16 percent. In contrast, N fixation on the heavy residue treatment was 33 percent greater than in the uncut stand. Harvesting and site preparation destroyed much of the forest floor, except on the heavy slash treatment. However, decayed wood in the soil was much less disturbed by logging operations, and became a more important source of N fixation than the forest floor after harvesting. Soil wood is a major organic matter component in many Inland Northwest forest soils and generally retains more moisture than the forest floor during dry summer months (Page-Dumroese and others, these proceedings).
| Soil component | Residue treatment | Uncut Mg2 |
Uncut gN3 |
|||||||
|---|---|---|---|---|---|---|---|---|---|---|
| None Mg |
None gN |
Prescribed burn Mg |
Prescribed burn gN |
Intensive removal Mg |
Intensive removal gN |
Heavy residue Mg |
Heavy residue gN |
|||
1Site was clearcut to a 12.7-cm
diameter top. Residue treatments: noneresidue left; prescribed burned
broadcast burned in the fall; intensive removalresidue removed by
blading with a crawler tractor; heavy residue removed by blading was
added to residue left on another area. |
||||||||||
| Wood residue | 146.0 | 984 | 57.9 | 177 | 10.6 | 111 | 249.8 | 1,483 | 154.3 | 1,428 |
| Forest floor | 16.7 | 110 | 5.5 | 26 | 13.3 | 73 | 34.5 | 326 | 23.2 | 88 |
| Soil wood | 50.9 | 109 | 22.4 | 47 | 51.6 | 195 | 50.3 | 430 | 47.9 | 178 |
| Mineral soil | — | 1,218 | — | 826 | — | 1,125 | — | 1,608 | — | 1,197 |
| Total | 213.6 | 2,421 | 85.8 | 1,076 | 75.5 | 1,504 | 334.6 | 3,847 | 225.4 | 2,891 |
Woody residue was an important source of nonsymbiotic N fixation in the cedar-hemlock stand prior to cutting. Much of this material was removed from the site or destroyed by the prescribed burn and intensive harvesting treatments (table 5). This was especially evident on the tractor-piled treatment, where woody residue loadings were reduced by >90 percent. The low N fixation on both the intensive harvest and burn treatments reflected the low woody residue levels. In contrast, the amount of woody residue remaining after clearcutting was nearly the same as in the uncut stand, but the N fixed was 30 percent less. A similar pattern was seen in the heavy slash treatment, where woody residue loadings were 60 percent higher than in the uncut stand, but N fixation was nearly equal.
The contribution of woody residues to soil N fixation on this site depended on both the amount and type of woody material left after harvest. In the heavy slash treatment 45 percent of the woody residue was in the crumbly or solid rot stage, and 55 percent was undecayed. Solid rot residue is sound enough to withstand fragmentation during logging operations, while crumbly rot residue is easily destroyed (Benson and Schlieter 1980). Decayed wood of both rot types amounted to 59 percent of the total residue on the clearcut treatment. In contrast, 95 percent of the woody residue on the uncut site was large decaying logs, mostly in the crumbly rot stage. Many of these logs were destroyed during harvest and were not present on the cut treatments. They were replaced by smaller pieces of sound wood from harvested trees, which have much lower rates of N fixation (Jurgensen and others 1987).
REPLACEMENT OF NITROGEN LOSSES
While nonsymbiotic N fixation was generally lower after harvesting a northern Idaho cedar-hemlock stand (table 8), the actual reduction was quite small (1-2 kg/ha/yr). The question is whether such small losses in N fixation are important to maintaining long-term site productivity. Using soil organic matter weights before and after harvest (table 8), the N content for these materials (Page-Dumroese and others, these proceedings), and assuming N is lost in proportion to weight losses, 440 kg of N were estimated to have been lost from this cedar-hemlock site by clearcutting and prescribed burning. This does not include any N losses that may have occurred in the mineral soil. Another 200-250 kg N were likely removed from the site in bolewood (Prescott and others 1989). Using an N-fixation gain of 1.08 kg/ha/yr (table 8), and 1.5 kg N/ha/yr added in precipitation, these N losses would be replaced in 250 to 270 years. Such a slow return to original soil N levels could have a considerable impact on subsequent stand growth.
This calculation was based on the assumption that inputs from N fixation will not change as the next stand develops. Nitrogen fixation should increase in the forest floor as this layer increases in thickness during stand development. Nitrogen fixation in the mineral soil was reduced by burning (table 8), but would likely increase as the forest floor becomes thicker. However, these N gains would be at least partially offset by a decrease of N fixation in woody residue. Residue weights would likely decrease with time, as wood decomposition rates are usually greater than residue inputs from young, fast-growing stands. It is only after 100 to 150 years that woody residue begins to increase as mature trees die (Harmon and others 1986; Spies and others 1988). A similar situation would probably occur for the soil wood.
Other sources of nonsymbiotic N fixation not accounted for in these calculations could also add appreciable amounts of N to the soil, and reduce the time required for site recovery. Tree stumps, cull trees left for snags, and large dead roots can add up to 1 kg/ha/yr after harvesting (Granhall and Lindberg 1980; Harvey and others 1989). Increased development of N-fixing algae and lichens on the soil surface after harvest could also add N, but this would likely be small due to generally dry conditions throughout the summer. Nitrogen-fixing bacteria may also be active in the rhizospheres of developing tree seedlings and shrubs (Amaranthus and others 1990).
Nitrogen-fixing plants are present in many cedar-hemlock habitat types in the Inland Northwest (tables 2 and 3). If any of these plants became established on the harvested site, soil N losses could be replaced more rapidly than by nonsymbiotic N fixation alone. Assuming symbiotic N fixation on this cedar-hemlock site could vary from a low of 3 kg N/ha/yr (Hendrickson and Burgess 1989) to a high of 72 kg N/ha/yr (Youngberg and Wollum 1976), the recovery time to preharvest soil N levels would range from 10 to 125 years.
MANAGEMENT IMPLICATIONS
Nitrogen-fixing plants have the potential to add significant amounts of N to forest sites in the Inland Northwest. Of the many N-fixing plants present in this region, Ceanothus seems most amenable to management. Fire, as part of postharvest site treatments or stand underburning, would favor Ceanothus development in many habitat types. Alnus, Shepherdia, Lupinus, and Astragalus also have management possibilities on many sites, but much more information is needed on the response of these genera to stand disturbance in a wide range of habitat types.
While the N added by N-fixing plants could be important in replacing N losses from harvesting or fire, these plants are serious competition for tree seedlings on many sites (McDonald and Fiddler 1989; Petersen and others 1988; Stewart and others 1984). In the short term, reduced stand growth from such plant competiton often far outweighs the benefits from added soil N. Youngberg and Wollum (1976) recommended using Ceanothus for soil N enrichment during initial seedling development, followed by herbicide treatment to release the trees. Whether such a chemical treatment would be economically or environmentally possible in the Inland Northwest is questionable. A better alternative would be to create a mosaic of microsite conditions using fire or mechanical scarification, which allows the development of both N-fixing plants and adequate tree regeneration (Geier-Hayes 1987), or to artificially establish N-fixing plants after harvest (Everett and others, these proceedings).
Another option would be to develop silvicultural systems to minimize competing vegetation, but leave as much organic matter on the soil surface as possible. This would favor the activity of nonsymbiotic N-fixing bacteria. While annual N inputs from these bacteria are small, such N gains over the life of the stand can be appreciable. Maintaining soil N levels is critical to continued productivity of Inland Northwest forests. These forests must be managed to minimize N losses from timber harvesting activities, and to encourage N inputs from biological sources.
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Paper presented at the Symposium on Management and Productivity of Western-Montane Forest Soils, Boise, ID, April 10-12, 1990.
Martin F. Jurgensen is Professor of Forest Soils, School of Forestry and Wood Products, Michigan Technological University, Houghton, MI 49931. Jonalea R. Tonn is Forester, Russell T. Graham is Silviculturist, and Alan E. Harvey is Principal Plant Pathologist, Intermountain Research Station, Forest Service, U.S. Department of Agriculture, Moscow, ID 83843. Kathleen Geier-Hayes is Research Forester, Intermountain Research Station, Boise, ID 83702.