Your search keyword '"April Hulet"' showing total 32 results

1. Breaking Dormancy and Increasing Restoration Success of Native Penstemon Species Using Gibberellic Acid Seed Coatings and U-Shaped Furrows

Author

Amber J. Johnson, Bradley Geary, April Hulet, and Matthew D. Madsen

Subjects

dormancy, planting season, forbs, microsite, habitat, Botany, QK1-989

Abstract

Many plant species exhibit strong seed dormancy. This attribute benefits the species’ long-term survival but can impede restoration when rapid establishment is required. Soaking seeds in gibberellic acid (GA3) can overcome dormancy and increase germination but this treatment may not be effective outside the laboratory. An easier and potentially more effective method to apply this hormone is to coat seeds with a GA3-impregnated polymer. Seed dormancy can also be mitigated by creating a favorable microsite with increased soil moisture. We compared the emergence and establishment of penstemon seeds coated with GA3 to those of uncoated seeds planted in shallow drill rows versus deep, U-shaped furrows. Overall, 6 times more Palmer’s penstemon (Penstemon palmeri; p < 0.01) and 21 times more thickleaf penstemon (P. pachyphyllus; p < 0.001) established when coated with GA3, but GA3 coating did not affect the establishment of firecracker penstemon (P. eatonii; p = 1). Establishment was higher from deep furrows than shallow rows (p < 0.001). These results indicate that GA3 seed coating and deep, U-shaped furrows may improve the restoration success of some native forbs by breaking dormancy and providing a favorable microsite. Land managers could use these techniques to restore native forbs in dry, disturbed areas.

Published

2023

2. Assessing Within-Field Variation in Alfalfa Leaf Area Index Using UAV Visible Vegetation Indices

Author

Keegan Hammond, Ruth Kerry, Ryan R. Jensen, Ross Spackman, April Hulet, Bryan G. Hopkins, Matt A. Yost, Austin P. Hopkins, and Neil C. Hansen

Subjects

leaf area index, unmanned aerial vehicle, alfalfa, visible vegetation index, management zones, variable-rate irrigation, Agriculture

Abstract

This study examines the use of leaf area index (LAI) to inform variable-rate irrigation (VRI) for irrigated alfalfa (Medicago sativa). LAI is useful for predicting zone-specific evapotranspiration (ETc). One approach toward estimating LAI is to utilize the relationship between LAI and visible vegetation indices (VVIs) using unmanned aerial vehicle (UAV) imagery. This research has three objectives: (1) to measure and describe the within-field variation in LAI and canopy height for an irrigated alfalfa field, (2) to evaluate the relationships between the alfalfa LAI and various VVIs with and without field average canopy height, and (3) to use UAV images and field average canopy height to describe the within-field variation in LAI and the potential application to VRI. The study was conducted in 2021–2022 in Rexburg, Idaho. Over the course of the study, the measured LAI varied from 0.23 m2 m−2 to 11.28 m2 m−2 and canopy height varied from 6 cm to 65 cm. There was strong spatial clustering in the measured LAI but the spatial patterns were dynamic between dates. Among eleven VVIs evaluated, the four that combined green and red wavelengths but excluded blue wavelengths showed the most promise. For all VVIs, adding average canopy height to multiple linear regression improved LAI prediction. The regression model using the modified green–red vegetation index (MGRVI) and canopy height (R2 = 0.93) was applied to describe the spatial variation in the LAI among VRI zones. There were significant (p < 0.05) but not practical differences (

Published

2023

3. Treatment longevity and changes in surface fuel loads after pinyon–juniper mastication

Author

Samuel S. Wozniak, Eva K. Strand, Timothy R. Johnson, April Hulet, Bruce A. Roundy, and Kert Young

Subjects

decomposition, down woody debris, pinyon pine, sagebrush, Special Feature: Sagebrush Steppe Treatment Evaluation Project, Ecology, QH540-549.5

Abstract

Abstract In the Intermountain West, land managers masticate pinyon pine (Pinus spp.) and juniper (Juniperus spp.) trees that have encroached sagebrush steppe communities to reduce canopy fuels, alter potential fire behavior, and promote growth of understory grasses, forbs, and shrubs. At three study sites in Utah, 45 sampling plots spanning a range of tree cover from 5% to 50% were masticated. We measured surface fuel load components three times over a 10‐yr period. We also measured tree cover, density, and height as indicators of treatment longevity. Changes in these variables were analyzed across the range of pre‐treatment tree cover using linear mixed effects modeling. We detected decreases in 1‐h down woody debris by 5–6 yr post‐treatment, and from 5–6 to 10 yr post‐treatment, but did not detect changes in 10‐h or 100 + 1000‐h down woody debris. By 10 yr post‐treatment, there was very little duff and tree litter left for all pre‐treatment tree cover values. Herbaceous fuels (all standing live and dead biomass) increased through 10 yr post‐treatment. At 10 yr post‐treatment, pinyon–juniper cover ranged 0–2.6%, and the majority of trees were

Published

2020

4. Rangeland monitoring using remote sensing: comparison of cover estimates from field measurements and image analysis

Author

Ammon Boswell, Steven Petersen, Bruce Roundy, Ryan Jensen, Danny Summers, and April Hulet

Subjects

Image classification, canopy cover, rangeland monitoring, remote sensing, Environmental sciences, GE1-350

Abstract

Rangeland monitoring is important for evaluating and assessing semi-arid plant communities. Remote sensing provides an effective tool for rapidly and accurately assessing rangeland vegetation and other surface attributes such as bare soil and rock. The purpose of this study was to evaluate the efficacy of remote sensing as a surrogate for field-based sampling techniques in detecting ground cover features (i.e., trees, shrubs, herbaceous cover, litter, surface), and comparing results with field-based measurements collected by the Utah Division of Wildlife Resources Range Trent Program. In the field, five 152 m long transects were used to sample plant, litter, rock, and bare-ground cover using the Daubenmire ocular estimate method. At the same location of each field plot, a 4-band (R,G,B,NIR), 25 cm pixel resolution, remotely sensed image was taken from a fixed-wing aircraft. Each image was spectrally classified producing 4 cover classes (tree, shrub, herbaceous, surface). No significant differences were detected between canopy cover collected remotely and in the field for tree (P = 0.652), shrub (P = 0.800), and herbaceous vegetation (P = 0.258). Surface cover was higher in field plots (P < 0.001), likely in response to the methods used to sample surface features by field crews. Accurately classifying vegetation and other features from remote sensed information can improve the efficiency of collecting vegetation and surface data. This information can also be used to improve data collection frequency for rangeland monitoring and to efficiently quantify ecological succession patterns.

Published

2017

5. Estimating pinyon and juniper cover across Utah using NAIP imagery

Author

Darrell B. Roundy, April Hulet, Bruce A. Roundy, Ryan R. Jensen, Jordan B. Hinkle, Leann Crook, and Steven L. Petersen

Subjects

Object-based image analysis, canopy cover, National Agriculture Imagery Program, eCognition, Feature AnalystTM, ENVI Feature Extraction, Environmental sciences, GE1-350

Abstract

Expansion of Pinus L. (pinyon) and Juniperus L. (juniper) (P-J) trees into sagebrush (Artemisia L.) steppe communities can lead to negative effects on hydrology, loss of wildlife habitat, and a decrease in desirable understory vegetation. Tree reduction treatments are often implemented to mitigate these negative effects. In order to prioritize and effectively plan these treatments, rapid, accurate, and inexpensive methods are needed to estimate tree canopy cover at the landscape scale. We used object based image analysis (OBIA) software (Feature AnalystTM for ArcMap 10.1®, ENVI Feature Extraction®, and Trimble eCognition Developer 8.2®) to extract tree canopy cover using NAIP (National Agricultural Imagery Program) imagery. We then compared our extractions with ground measured tree canopy cover (crown diameter and line point intercept) on 309 plots across 44 sites in Utah. Extraction methods did not consistently over- or under-estimate ground measured P-J canopy cover except where tree cover was >45%. Estimates of tree canopy cover using OBIA techniques were strongly correlated with estimates using the crown diameter method (r = 0.93 for ENVI, 0.91 for Feature AnalystTM, and 0.92 for eCognition). Tree cover estimates using OBIA techniques had lower correlations with tree cover measurements using the line-point intercept method (r = 0.85 for ENVI, 0.83 for Feature AnalystTM, and 0.83 for eCognition). All software packages accurately and inexpensively extracted P-J canopy cover from NAIP imagery when the imagery was not blurred, and when P-J cover was not mixed with Amelanchier alnifolia (Utah serviceberry) and Quercus gambelii (Gambel’s oak), which had similar spectral values as P-J.

Published

2016

6. Inducing rapid seed germination of native cool season grasses with solid matrix priming and seed extrusion technology.

Author

Matthew D Madsen, Lauren Svejcar, Janae Radke, and April Hulet

Subjects

Medicine, Science

Abstract

There is a need to develop effective techniques for establishing native vegetation in dryland ecosystems. We developed a novel treatment that primes (hydrates) seeds in a matrix of absorbent materials and bio-stimulants and then forms the mixture into pods for planting. In the development process, we determined optimal conditions for priming seeds and then compared seedling emergence from non-treated seeds, non-primed-seed pods, and primed-seed pods. Emergence trials were conducted on soils collected from a hillslope and ridgetop location on the Kaibab Plateau, Arizona, USA. Poa fendleriana and Pseudoroegneria spicata were used as test species. Seeds were primed from -0.5 to -2.5 MPa for up to 12 d. Seeds primed under drier conditions (-1.5 to -2.5 MPa) tended to have quicker germination. Days to 50% emergence for primed-seed pods was between 66.2 to 82.4% faster (5.2 to 14.5 d fewer) than non-treated seeds. Seedling emergence from primed-seed pods for P. fendleriana was 3.8-fold higher than non-treated seeds on the ridgetop soil, but no difference was found on the other soil. Final density of P. spicata primed-seed pods were 2.9 to 3.8-fold higher than non-treated seeds. Overall, primed-seed pods show promise for enhancing germination and seedling emergence, which could aid in native plant establishment.

Published

2018

7. Strategic Partnerships to Leverage Small Wins for Fine Fuels Management

Author

Sergio A. Arispe, Dustin D. Johnson, Katherine L. Wollstein, April Hulet, K. Scott Jensen, Brad W. Schultz, James E. Sprinkle, Michele F. McDaniel, Thomas Ryan, Mark Mackenzie, and Sean Cunningham

Subjects

Ecology, Animal Science and Zoology, Management, Monitoring, Policy and Law, Nature and Landscape Conservation

Published

2022

8. When a weed is not a weed: succession management using early seral natives for Intermountain rangeland restoration

Author

Derek Tilley, April Hulet, Shaun Bushman, Charles Goebel, Jason Karl, Stephen Love, and Mary Wolf

Subjects

Ecology, Geography, Planning and Development, Management, Monitoring, Policy and Law

Published

2022

9. Oil and gas reclamation on US public lands: How it works and improving the process with land potential concepts

Author

Michael C. Duniway, Jason W. Karl, J.D. Wulfhorst, April Hulet, Sean Di Stéfano, and Robert Heinse

Subjects

Resource (biology), Ecology, Public land, business.industry, Process (engineering), Abandonment (legal), Geography, Planning and Development, Environmental resource management, Fossil fuel, Management, Monitoring, Policy and Law, Private sector, Adaptive management, Land reclamation, Environmental science, business

Abstract

On the Ground • There are three general stages of a well's life on US public land: 1) the permitting process to drill, 2) active extraction of fossil fuel resource, and 3) plugging and abandonment of well. • There is no national standard for oil and gas reclamation in the United States similar to mining and therefore current reclamation practices and standards fail to achieve long-term effectiveness across the western United States. • A reclaimed well pad's land potential is determined by 3 properties: static (e.g., climate), dynamic (e.g., soil stability), and process (e.g., water retention). • Understanding a reclaimed well pad's land potential enables federal land agencies to outline surface reclamation goals and requirements consistently and clearly. • Monitoring for land potential increases the capacity of the private industry to practice adaptive management by enabling companies to respond to plant community changes while maintaining long-term progress toward recovery.

Published

2021

10. Estimates of fine fuel litter biomass in the northern Great Basin reveal increases during short fire-free intervals associated with invasive annual grasses

Author

José Manuel Fernández-Guisuraga, Leonor Calvo, Paulo M. Fernandes, April Hulet, Barry Perryman, Brad Schultz, K. Scott Jensen, Josh Enterkine, Chad S. Boyd, Kirk W. Davies, Dustin D. Johnson, Katherine Wollstein, William J. Price, Sergio A. Arispe, Ecologia, and Facultad de Ciencias Biologicas y Ambientales

Subjects

Fire regime, Environmental Engineering, Environmental Chemistry, Western US, Wildfire, Rangeland, RAP, Pollution, Waste Management and Disposal, Ecología. Medio ambiente, Net primary productivity

Abstract

[EN] Exotic annual grasses invasion across northern Great Basin rangelands has promoted a grass-fire cycle that threatens the sagebrush (Artemisia spp.) steppe ecosystem. In this sense, high accumulation rates and persistence of litter from annual species largely increase the amount and continuity of fine fuels. Here, we highlight the potential use and transferability of remote sensing-derived products to estimate litter biomass on sagebrush rangelands in southeastern Oregon, and link fire regime attributes (fire-free period) with litter biomass spatial patterns at the landscape scale. Every June, from 2018 to 2021, we measured litter biomass in 24 field plots (60 m × 60 m). Two remote sensing-derived datasets were used to predict litter biomass measured in the field plots. The first dataset used was the 30-m annual net primary production (NPP) product partitioned into plant functional traits (annual grass, perennial grass, shrub, and tree) from the Rangeland Analysis Platform (RAP). The second dataset included topographic variables (heat load index -HLI- and site exposure index -SEI-) computed from the USGS 30-m National Elevation Dataset. Through a frequentist model averaging approach (FMA), we determined that the NPP of annual and perennial grasses, as well as HLI and SEI, were important predictors of field-measured litter biomass in 2018, with the model featuring a high overall fit (R2 = 0.61). Model transferability based on extrapolating the FMA predictive relationships from 2018 to the following years provided similar overall fits (R2 ≈ 0.5). The fire-free period had a significant effect on the litter biomass accumulation on rangelands within the study site, with greater litter biomass in areas where the fire-free period was

Published

2022

11. Evaluating a Seed Technology for Sagebrush Restoration Across an Elevation Gradient: Support for Bet Hedging

Author

April Hulet, Jay D. Kerby, Kirk W. Davies, Chad S. Boyd, and Matthew D. Madsen

Subjects

0106 biological sciences, Ecology, biology, Elevation, food and beverages, Vegetation, Management, Monitoring, Policy and Law, Herbaceous plant, biology.organism_classification, 010603 evolutionary biology, 01 natural sciences, 010601 ecology, Probability of success, Agronomy, Seedling, Environmental science, Artemisia, Animal Science and Zoology, Seeding, Broadcast seeding, Nature and Landscape Conservation

Abstract

Big sagebrush (Artemisia tridentata Nutt.) restoration is needed across vast areas, especially after large wildfires, to restore important ecosystemservices. Sagebrush restoration success is inconsistent, with a high rate of seeding failures, particularly at lower elevations. Seed enhancement technologies may overcome limitations to restoration success. Seed pillows are one such technology designed to improve seed-soil contact in broadcast seedings by providing a favorable medium for seedling establishment and growth. Seed pillows have shown promising results in greenhouse studies; however, they have not been evaluated in the field. We compared broadcast-seeding seed pillows with broadcast-seeding bare seed in 2 yr across a large, burned elevation gradient. Compared with bare seed, we found no evidence that seed pillows improved sagebrush establishment and growth across the elevation gradient. Though our results suggest that seed pillows do not increase the likelihood of successful sagebrush restoration, they were successful at times when bare seeds were not, and the same was true for bare seeds. At least one of the two treatments was successful at 50% of the elevations over the 2 seeding yr. This suggests that a bet hedging approach, seeding both bare seed and seed pillows, may increase the probability of success. Further supporting the use of bet hedging, if both methods were used and seeding occurred in both years, success would have been 86%. Sagebrush density and cover varied by elevation. In the first-yr seeding, sagebrush density and cover generally increased with increasing elevation. In the second-yr seeding, sagebrush density and cover were greatest at the lowest and highest elevations. We speculate that at the lower elevations an unusually wet spring combined with limited herbaceous vegetation provided an ideal environment for sagebrush establishment and growth. Our results also demonstrate, counter to common assumptions, that lower elevations sagebrush seedings can be successful.

Published

2018

12. Pretreatment Tree Dominance and Conifer Removal Treatments Affect Plant Succession in Sagebrush Communities

Author

Bruce A. Roundy, Jeanne C. Chambers, April Hulet, Jeffrey W. Matthews, Rachel E. Williams, Dennis L. Eggett, Robin J. Tausch, Robert L. Schooley, and Richard F. Miller

Subjects

0106 biological sciences, Ecology, Perennial plant, ved/biology, ved/biology.organism_classification_rank.species, food and beverages, Ecological succession, Understory, Management, Monitoring, Policy and Law, Biology, biology.organism_classification, 010603 evolutionary biology, 01 natural sciences, Shrub, 010601 ecology, Agronomy, Botany, Dominance (ecology), Artemisia, Animal Science and Zoology, Juniper, Nature and Landscape Conservation, Woody plant

Abstract

In sagebrush (Artemisia tridentata Nutt.) ecosystems, expansion and infilling of conifers decreases the abundance of understory perennial vegetation and lowers ecosystem resilience and resistance of the once shrub grass—dominated state. We prescribed burned or cut juniper (Juniperus spp. L.) and pinyon (Pinus spp. L.) trees at 10 sites across the western United States. We measured vegetation cover and density on untreated and treated plots 3 and 6 yr after treatment across a gradient of pretreatment tree dominance as quantified by the tree dominance index (TDI); (tree cover)/(tree + shrub + tall grass cover). We analyzed plant responses by functional group using mixed-model analysis of covariance, with TDI treated as a covariate. As tree cover increased and TDI exceeded 0.5, shrub cover declined to < 25% of the maximum on untreated plots. Although total shrub cover recovered on burned plots to untreated percentages 6 yr after treatment, sagebrush cover was still 1.1–0.6% on burned plots compared ...

Published

2017

13. Using Activated Carbon to Limit Herbicide Effects to Seeded Bunchgrass When Revegetating Annual Grass-Invaded Rangelands

Author

April Hulet, Matthew D. Madsen, and Kirk W. Davies

Subjects

0106 biological sciences, Agropyron desertorum, Ecology, biology, Tussock, 04 agricultural and veterinary sciences, Vegetation, Management, Monitoring, Policy and Law, Bromus tectorum, Imazapic, biology.organism_classification, 010603 evolutionary biology, 01 natural sciences, chemistry.chemical_compound, Agronomy, chemistry, 040103 agronomy & agriculture, 0401 agriculture, forestry, and fisheries, Environmental science, Animal Science and Zoology, Seeding, Rangeland, Revegetation, Nature and Landscape Conservation

Abstract

Revegetation of exotic annual grass − invaded rangelands is challenging as annuals rapidly reinvade after control treatments. The most effective control of exotic annual grass is usually achieved with pre-emergent herbicides; however, species seeded simultaneously with these herbicides will likely experience nontarget damage. Thus, seeding often occurs 1 yr later to reduce herbicide effects to seeded vegetation, but by this time annual grasses may already be reinvading and limiting revegetation success. Activated carbon can be used to protect seeded species from herbicide damage because it has a high absorption capacity that can deactivate many herbicides. A pot study in a grow-room suggested that a pod containing activated carbon and seeds, herbicide protection pods (HPPs), may allow desired species to be seeded simultaneously with annual grass control with the pre-emergent herbicide imazapic. However, HPPs have not been field tested. We evaluated two seeding treatments (crested wheatgrass (Agropyron desertorum [Fisch.] Schult.) incorporated into HPPs and bare seed, simultaneously with an imazapic application to control annual grasses at two sites invaded by cheatgrass (Bromus tectorum L.) and medusahead (Taeniatherum caput-medusae [L.] Nevski). Crested wheatgrass abundance was 300% greater with HPPs compared with bare seed in late June. Imazapic application reduced exotic annual grass density at both sites by approximately half. These results suggest that HPPs can be used to allow desired species to be seeded simultaneously with imazapic application. This will allow seeded species a longer window to become established before experiencing pressure from exotic annuals and enable a single-entry approach compared with multiple entries currently employed to revegetate annual grass − invaded rangelands. Though further field testing is needed, in particular with multiple species and higher herbicide applications rates, these results suggest that HPPs could improve our ability to restore and revegetate exotic annual grass − invaded rangelands.

Published

2017

14. Attempting to restore mountain big sagebrush (Artemisia tridentata ssp. vaseyana ) four years after fire

Author

Kirk W. Davies, April Hulet, and Jon D. Bates

Subjects

0106 biological sciences, Ecology, Fire regime, biology, Agroforestry, ved/biology, ved/biology.organism_classification_rank.species, Growing season, biology.organism_classification, 010603 evolutionary biology, 01 natural sciences, Shrub, 010601 ecology, Agronomy, Disturbance (ecology), Juniperus occidentalis, Artemisia, Environmental science, Seeding, Juniper, Ecology, Evolution, Behavior and Systematics, Nature and Landscape Conservation

Abstract

Restoration of shrubs is needed throughout the world because of altered fire regimes, anthropogenic disturbance, and overutilization. The native shrub mountain big sagebrush (Artemisia tridentata Nutt. ssp. vaseyana (Rydb.) Beetle) is a restoration priority because of its value to wildlife in western North America. One of the principal threats to mountain big sagebrush is encroachment by western juniper (Juniperus occidentalis ssp. occidentalis Hook) and other conifers. Fire is frequently applied to control juniper; however, sagebrush recovery after fire can be variable. Seeding sagebrush postfire can hasten sagebrush recovery; however, seeding is not always necessary. Therefore, it may be advantageous to monitor postfire recovery to determine if seeding is needed. The effect of seeding sagebrush several years after fire is unknown. We evaluated the efficiency of seeding mountain big sagebrush four years after fire-controlled junipers at five sites. Sagebrush cover (

Published

2017

15. Sage Grouse Groceries: Forb Response to Piñon-Juniper Treatments

Author

Bruce A. Roundy, April Hulet, Kirk W. Davies, Jonathan D. Bates, Richard F. Miller, and Society for Range Management

Subjects

0106 biological sciences, Steppe, Management, Monitoring, Policy and Law, Pinus edulis, 010603 evolutionary biology, 01 natural sciences, food, Nature and Landscape Conservation, Pinus monophylla, geography, geography.geographical_feature_category, juniper, Ecology, biology, Plant Sciences, biology.organism_classification, food.food, 010601 ecology, fuel reduction, Juniperus occidentalis, Juniperus osteosperma, Forb, Environmental science, Animal Science and Zoology, Juniper, conifer woodland, Rangeland, sagebrush, prescribed fire

Abstract

Juniper and piñon coniferous woodlands have increased 2- to 10-fold in nine ecoregions spanning the Intermountain Region of the western United States. Control of piñon-juniper woodlands by mechanical treatments and prescribed fire are commonly applied to recover sagebrush steppe rangelands. Recently, the Sage Grouse Initiative has made conifer removal a major part of its program to reestablish sagebrush habitat for sage grouse (Centrocercus urophasianus) and other species. We analyzed data sets from previous and ongoing studies across the Great Basin characterizing cover response of perennial and annual forbs that are consumed by sage grouse to mechanical, prescribed fire, and low-disturbance fuel reduction treatments. There were 11 sites in western juniper (Juniperus occidentalis Hook.) woodlands, 3 sites in singleleaf piñon (Pinus monophylla Torr. & Frém.) and Utah juniper (Juniperus osteosperma [Torr.] Little), 2 sites in Utah juniper, and 2 sites in Utah juniper and Colorado piñon (Pinus edulis Engelm). Western juniper sites were located in mountain big sagebrush (A. tridentata ssp. vaseyana) steppe associations, and the other woodlands were located in Wyoming big sagebrush (A. tridentata ssp. wyomingensis) associations. Site potential appears to be a major determinant for increasing perennial forbs consumed by sage grouse following conifer control. The cover response of perennial forbs, whether increasing (1.5- to 6-fold) or exhibiting no change, was similar regardless of conifer treatment. Annual forbs favored by sage grouse benefitted most from prescribed fire treatments with smaller increases following mechanical and fuel reduction treatments. Though forb abundance may not consistently be enhanced, mechanical and fuel reduction conifer treatments remain good preventative measures, especially in phase 1 and 2 woodlands, which, at minimum, maintain forbs on the landscape. In addition, these two conifer control measures, in the short term, are superior to prescribed fire for maintaining the essential habitat characteristics of sagebrush steppe for sage grouse.

Published

2017

16. Rangeland monitoring using remote sensing: comparison of cover estimates from field measurements and image analysis

Author

Bruce A. Roundy, Ryan R. Jensen, Ammon Boswell, Steven L. Petersen, April Hulet, and Danny Summers

Subjects

lcsh:GE1-350, Canopy, 010504 meteorology & atmospheric sciences, Cover (telecommunications), Image classification, ved/biology, ved/biology.organism_classification_rank.species, Plant community, Vegetation, 010501 environmental sciences, 01 natural sciences, Shrub, remote sensing, Geography, Remote sensing (archaeology), canopy cover, Rangeland, Transect, rangeland monitoring, lcsh:Environmental sciences, 0105 earth and related environmental sciences, General Environmental Science, Remote sensing

Abstract

Rangeland monitoring is important for evaluating and assessing semi-arid plant communities. Remote sensing provides an effective tool for rapidly and accurately assessing rangeland vegetation and other surface attributes such as bare soil and rock. The purpose of this study was to evaluate the efficacy of remote sensing as a surrogate for field-based sampling techniques in detecting ground cover features (i.e., trees, shrubs, herbaceous cover, litter, surface), and comparing results with field-based measurements collected by the Utah Division of Wildlife Resources Range Trent Program. In the field, five 152 m long transects were used to sample plant, litter, rock, and bare-ground cover using the Daubenmire ocular estimate method. At the same location of each field plot, a 4-band (R,G,B,NIR), 25 cm pixel resolution, remotely sensed image was taken from a fixed-wing aircraft. Each image was spectrally classified producing 4 cover classes (tree, shrub, herbaceous, surface). No significant differences were detected between canopy cover collected remotely and in the field for tree (P = 0.652), shrub (P = 0.800), and herbaceous vegetation (P = 0.258). Surface cover was higher in field plots (P < 0.001), likely in response to the methods used to sample surface features by field crews. Accurately classifying vegetation and other features from remote sensed information can improve the efficiency of collecting vegetation and surface data. This information can also be used to improve data collection frequency for rangeland monitoring and to efficiently quantify ecological succession patterns.

Published

2017

17. Extruded seed pellets: a novel approach for enhancing sagebrush seedling emergence

Author

Kirk W. Davies, Tony J. Svejcar, Jerry L Staley, April Hulet, Karma Phillips, and Matthew D. Madsen

Subjects

0106 biological sciences, 010604 marine biology & hydrobiology, Pellets, food and beverages, Sowing, Biology, biology.organism_classification, 010603 evolutionary biology, 01 natural sciences, Water potential, Agronomy, Germination, Seedling, Pellet, Soil water, Artemisia

Abstract

Small or low-vigor species can be susceptible to being planted at depths that prevent seedling emergence. As an example, sagebrush ( Artemisia spp. L. [Anthemideae]) seed is often prone to being planted at depths where the seedlings cannot emerge from the soil. We evaluated a potential solution to this problem that incorporates seed within an extruded pellet that is designed to enhance seedling emergence through the swelling action of the pellet creating conduits for the emerging seedlings to follow. We quantified the swelling capacity of the extruded pellet and evaluated how the technology improves seedling emergence and plant growth of Wyoming big sagebrush ( Artemisia tridentate Nutt. ssp. wyomingensis Beetle & Young), over a range of seeding depths (5, 10, and 15 mm [0.2, 0.4, and 0.6 in]), within silt-loam and sandy-loam soils. Swelling capacity of the pellets in the silt-loam soil was approximately twice that of the sandy-loam soil. At all planting depths, pellets improved seedling emergence between 2.3- to 10.0-fold in the silt-loam soil. In the sandy-loam soil, no treatment effect occurred for seedling emergence at the 5 mm and 15 mm depths, but pellets enhanced emergence at the 10 mm depth by 3.1-fold. Some indications suggest that seedlings produced from the extruded pellets had greater growth than untreated seed. This technology opens up the possibility for sagebrush (and potentially other smallseeded species) to be seeded at deeper soil depths where soil water potential levels are more conducive for seed germination and seedling survival. Future development and field testing are merited.

Published

2016

18. Effects of Using Winter Grazing as a Fuel Treatment on Wyoming Big Sagebrush Plant Communities

Author

Aleta M. Nafus, Kirk W. Davies, Chad S. Boyd, Jon D. Bates, and April Hulet

Subjects

0106 biological sciences, Ecology, Perennial plant, Tussock, Plant community, Vegetation, Management, Monitoring, Policy and Law, 010603 evolutionary biology, 01 natural sciences, 010601 ecology, Agronomy, Standing crop, Grazing, Exclosure, Environmental science, Forb, Animal Science and Zoology, Nature and Landscape Conservation

Abstract

More frequent wildfires and incidences of mega-fires have increased the pressure for fuel treatments in sagebrush (Artemisia) communities. Winter grazing has been one of many fuel treatments proposed for Wyoming big sagebrush (A. tridentata Nutt. subsp. wyomingensis Beetle and A. Young) communities. Though fire risk and severity can be reduced with winter grazing, its impact on vegetation characteristics of Wyoming big sagebrush plant communities is largely unknown. We evaluate the effect of winter grazing at utilization levels between 40% and 60% at five sites in southeastern Oregon. Winter grazing was applied for 5–6 yr before measurements. The winter-grazed and ungrazed treatments generally had similar vegetation characteristics; however, a few characteristics differed. The consumption of prior years' growth resulted in less large perennial bunchgrass, perennial forb, and total herbaceous cover and standing crop and litter biomass. Large perennial bunchgrass and perennial forb density and biom...

Published

2016

19. Inducing rapid seed germination of native cool season grasses with solid matrix priming and seed extrusion technology

Author

April Hulet, Lauren N. Svejcar, Matthew D. Madsen, and Janae Radke

Subjects

0106 biological sciences, Time Factors, Light, Polymers, lcsh:Medicine, Invasive Species, Priming (agriculture), Poa fendleriana, Plant Science, Plant Reproduction, 01 natural sciences, Soil, Seed Germination, Evolutionary Emergence, lcsh:Science, Materials, Multidisciplinary, Plant Anatomy, Physics, Electromagnetic Radiation, food and beverages, Eukaryota, Native plant, Plants, Horticulture, Baccharis, Chemistry, Macromolecules, Germination, Artificial Light, Plant Physiology, Seeds, Physical Sciences, Pseudoroegneria spicata, Seasons, Research Article, Evolutionary Processes, Materials Science, Biology, Poaceae, 010603 evolutionary biology, Species Colonization, Grasses, Evolutionary Biology, 010604 marine biology & hydrobiology, lcsh:R, Ecology and Environmental Sciences, Organisms, Sowing, Water, Biology and Life Sciences, biology.organism_classification, Polymer Chemistry, Seedling, Seedlings, Soil water, lcsh:Q

Abstract

There is a need to develop effective techniques for establishing native vegetation in dryland ecosystems. We developed a novel treatment that primes seeds in a matrix of absorbent materials and bio-stimulants and then forms the mixture into pods for planting. In the development process, we determined optimal conditions for priming seeds and then compared seedling emergence from non-treated seeds, non-primed-seed pods, and primed-seed pods. Emergence trials were conducted on soils collected from a hillslope and ridgetop location on the Kaibab Plateau, Arizona, USAPoa fendlerianaandPseudoroegneria spicatawere used as test species. Seeds were primed from −0.5 to −2.5 MPa for up to 12 d. Seeds primed under drier conditions (−1.5 to −2.5 MPa) tended to have quicker germination. Days to 50% emergence for primed-seed pods was between 66.2 to 82.4% faster (5.2 to 14.5 d fewer) than non-treated seeds. Seedling emergence from primed-seed pods forP. fendlerianawas 3.8-fold higher than non-treated seeds on the ridgetop soil, but no difference was found on the other soil. Final density ofP. spicataprimed-seed pods were 2.9 to 3.8-fold higher than non-treated seeds. Overall, primed-seed pods show promise for enhancing germination and seedling emergence, which could aid in native plant establishment.

Published

2018

20. Prefire (Preemptive) Management to Decrease Fire-Induced Bunchgrass Mortality and Reduce Reliance on Postfire Seeding

Author

April Hulet, Kirk W. Davies, Chad S. Boyd, and Tony J. Svejcar

Subjects

Abiotic component, Ecology, Perennial plant, Resistance (ecology), Agroforestry, Tussock, media_common.quotation_subject, Land management, Management, Monitoring, Policy and Law, Disturbance (ecology), Environmental science, Animal Science and Zoology, Psychological resilience, Rangeland, Nature and Landscape Conservation, media_common

Abstract

Western rangelands are currently under severe threat from exotic annual grasses. To successfully manage rangelands that are either infested with or susceptible to exotic annual grasses, we must focus on increasing resilience to disturbance and resistance to exotic annual grass invasion. Here, we present a fuel-based model and research framework for Wyoming big sagebrush (Artemisia tridentata ssp. wyomingensis Beetle & Young) rangelands that focuses on increasing resilience to fire and resistance to exotic annual grasses through the maintenance of perennial bunchgrasses. By maintaining perennial bunchgrass, exotic annual grasses have limited resources, thus decreasing the invasibility of the site. In order for the fuel-based model to be effective in guiding land management practices, research that evaluates the interactions between biotic and abiotic factors that influence fire-induced bunchgrass mortality is needed. Hence, we propose a research framework to identify and fill potential gaps in current scientific knowledge. We also suggest potential research objectives that are necessary to make informed management decisions before wildfire, with a goal to ultimately decreasing our reliance on marginally successful postfire restoration practices through preemptive management strategies.

Published

2015

21. Understory Cover Responses to Piñon–Juniper Treatments Across Tree Dominance Gradients in the Great Basin

Author

April Hulet, Bruce A. Roundy, Dennis L. Eggett, Richard F. Miller, Kert R. Young, Benjamin M. Rau, Brad Jessop, Jeanne C. Chambers, Robin J. Tausch, and Society for Range Management

Subjects

Perennial plant, ved/biology.organism_classification_rank.species, mastication, Bromus tectorum, Management, Monitoring, Policy and Law, Felling, Shrub, Dominance (ecology), Revegetation, mechanical treatments, resilience, Nature and Landscape Conservation, biology, Ecology, ved/biology, Plant Sciences, thresholds, Understory, biology.organism_classification, Agronomy, Environmental science, Animal Science and Zoology, Juniper, brush control, prescribed fire, state and transition

Abstract

Piñon (Pinus spp.) and juniper (Juniperus spp.) trees are reduced to restore native vegetation and avoid severe fires where they have expanded into sagebrush (Artemisia tridentata Nutt.) communities. However, what phase of tree infilling should treatments target to retain desirable understory cover and avoid weed dominance? Prescribed fire and tree felling were applied to 8–20-ha treatment plots at 11 sites across the Great Basin with a tree-shredding treatment also applied to four Utah sites. Treatments were applied across a tree infilling gradient as quantified by a covariate tree dominance index (TDI = tree cover/&lsqb;tree + shrub + tall perennial grass cover]). Mixed model analysis of covariance indicated that treatment × covariate interactions were significant (P &spilt; 0.05) for most vegetation functional groups 3 yr after treatment. Shrub cover was most reduced with fire at any TDI or by mechanical treatment after infilling resulted in over 50% shrub cover loss (TDI &spigt; 0.4). Fire increased cheatgrass (Bromus tectorum L.) cover by an average of 4.2% for all values of TDI. Cutting or shredding trees generally produced similar responses and increased total perennial herbaceous and cheatgrass cover by an average of 10.2% and 3.8%, at TDIs ≥ 0.35 and ≥ 0.45. Cheatgrass cover estimated across the region was &spilt; 6% after treatment, but two warmer sites had high cheatgrass cover before (19.2% and 27.2%) and after tree reduction (26.6% and 50.4%). Fuel control treatments are viable management options for increasing understory cover across a range of sites and tree cover gradients, but should be accompanied by revegetation on warmer sites with depleted understories where cheatgrass is highly adapted. Shrub and perennial herbaceous cover can be maintained by mechanically treating at lower TDI. Perennial herbaceous cover is key for avoiding biotic and abiotic thresholds in this system through resisting weed dominance and erosion.

Published

2014

22. A Synopsis of Short-Term Response to Alternative Restoration Treatments in Sagebrush-Steppe: The SageSTEP Project

Author

Jeanne C. Chambers, Jason Williams, Paul S. Doescher, Dale W. Johnson, Frederick B. Pierson, April Hulet, Benjamin M. Rau, Bruce A. Roundy, Kim Rollins, Steve Bunting, Richard F. Miller, Robin J. Tausch, Mike Pellant, James D. McIver, Mark W. Brunson, Steven T. Knick, James B. Grace, Eugene W. Schupp, David A. Pyke, and Society for Range Management

Subjects

ecosystem management, geography, cheatgrass invasion, geography.geographical_feature_category, Resistance (ecology), Ecology, Agroforestry, Steppe, ecological resilience, Plant Sciences, woodland expansion, Biological soil crust, Plant community, Vegetation, Woodland, Understory, Management, Monitoring, Policy and Law, Environmental science, Animal Science and Zoology, environmental gradients, sagebrush restoration, Restoration ecology, Nature and Landscape Conservation

Abstract

The Sagebrush Steppe Treatment Evaluation Project (SageSTEP) is an integrated long-term study that evaluates ecological effects of alternative treatments designed to reduce woody fuels and to stimulate the herbaceous understory of sagebrush steppe communities of the Intermountain West. This synopsis summarizes results through 3 yr posttreatment. Woody vegetation reduction by prescribed fire, mechanical treatments, or herbicides initiated a cascade of effects, beginning with increased availability of nitrogen and soil water, followed by increased growth of herbaceous vegetation. Response of butterflies and magnitudes of runoff and erosion closely followed herbaceous vegetation recovery. Effects on shrubs, biological soil crust, tree cover, surface woody fuel loads, and sagebrush-obligate bird communities will take longer to be fully expressed. In the short term, cool wet sites were more resilient than warm dry sites, and resistance was mostly dependent on pretreatment herbaceous cover. At least 10 yr of posttreatment time will likely be necessary to determine outcomes for most sites. Mechanical treatments did not serve as surrogates for prescribed fire in how each influenced the fuel bed, the soil, erosion, and sage-obligate bird communities. Woody vegetation reduction by any means resulted in increased availability of soil water, higher herbaceous cover, and greater butterfly numbers. We identified several trade-offs (desirable outcomes for some variables, undesirable for others), involving most components of the study system. Trade-offs are inevitable when managing complex natural systems, and they underline the importance of asking questions about the whole system when developing management objectives. Substantial spatial and temporal heterogeneity in sagebrush steppe ecosystems emphasizes the point that there will rarely be a “recipe” for choosing management actions on any specific area. Use of a consistent evaluation process linked to monitoring may be the best chance managers have for arresting woodland expansion and cheatgrass invasion that may accelerate in a future warming climate.

Published

2014

23. Cover Estimations Using Object-Based Image Analysis Rule Sets Developed Across Multiple Scales in Pinyon-Juniper Woodlands

Author

April Hulet, Bruce A. Roundy, Ryan R. Jensen, Stephen C. Bunting, and Steven L. Petersen

Subjects

Ecology, biology, Land management, Plant community, Understory, Woodland, Land cover, Vegetation, Management, Monitoring, Policy and Law, biology.organism_classification, Radiance, Environmental science, Animal Science and Zoology, Juniper, Cartography, Nature and Landscape Conservation

Abstract

Numerous studies have been conducted that evaluate the utility of remote sensing for monitoring and assessing vegetation and ground cover to support land management decisions and complement ground measurements. However, few comparisons have been made that evaluate the utility of object-based image analysis (OBIA) to accurately classify a landscape where rule sets (models) have been developed at various scales. In this study, OBIA rule sets used to estimate land cover from high–spatial resolution imagery (0.06-m pixel) on Pinus L. (pinyon) and Juniperus L. (juniper) woodlands were developed using eCognition Developer at four scales with varying grains—1) individual plot, 2) individual sites, 3) regions (western juniper vs. Utah juniper sites), and 4) pinyon-juniper woodland network (all plots)—that were within the same study extent. Color-infrared imagery was acquired over five sites in Oregon, California, Nevada, and Utah with a Vexcel UltraCamX digital camera in June 2009. Ground cover measurements were also collected at study sites in 2009 on 80 0.1-ha plots. Correlations between OBIA and ground measurements were relatively high for individual plot and site rule sets (ranging from r¼0.52 to r¼0.98). Correlations for regional and network rule sets were lower (ranging from r¼0.24 to r¼0.63), which was expected due to radiance differences between the images as well as vegetation differences found at each site. All site and plot OBIA average cover percentage estimates for live trees, shrubs, perennial herbaceous vegetation, litter, and bare ground were within 5% of the ground measurements, and all region and network OBIA average cover percentage estimates were within 10%. The trade-off for decreased accuracy over a larger area (region and network rule sets) may be useful to prioritize management strategies but will unlikely capture subtle shifts in understory plant communities that site and plot rule sets often capture.

Published

2014

24. Assessing the Relationship between Ground Measurements and Object-Based Image Analysis of Land Cover Classes in Pinyon and Juniper Woodlands

Author

April Hulet, Ryan R. Jensen, Stephen C. Bunting, Steven L. Petersen, and Bruce A. Roundy

Subjects

biology, Agroforestry, Forestry, Woodland, Shrub-steppe, Land cover, biology.organism_classification, Geography, Thematic map, Thematic Mapper, Cover (algebra), Juniper, Computers in Earth Sciences, Scale (map)

Abstract

Land managers need to rapidly assess vegetation composition and bare ground to effectively evaluate and manage shrub steppe communities that have been encroached by pinyon and juniper trees. We used an object-based image analysis (OBIA) approach to estimate land cover classes found in pinyon-juniper woodlands, and evaluated the relationship between ground measurements and OBIA land cover measurements. We acquired high-spatial resolution color-infrared imagery for five sites with a Vexcel UltraCamX digital camera in June 2009. We simultaneously collected ground-based cover measurements within 30 m × 33 m subplots. OBIA mean land cover class differences by site ranged from underestimating litter by 3 percent to overestimating live trees by 1 percent when compared to ground-based measurements. Overall accuracy for thematic maps was 84 percent with a Kappa statistic of 0.80. Although OBIA cover estimates varied slightly from ground cover estimates, methods provide land managers with options for prioritizing management practices and enabling monitoring at an operational scale.

Published

2013

25. Vegetation Response to Piñon and Juniper Tree Shredding

Author

Dennis L. Eggett, April Hulet, Kert Young, Bruce A. Roundy, Darrell B. Roundy, Zachary T. Aanderud, Jordan Bybee, Nathan L. Cline, Leann Crook, and Society for Range Management

Subjects

0106 biological sciences, infilling, Climax, Steppe, ved/biology.organism_classification_rank.species, mastication, Management, Monitoring, Policy and Law, 010603 evolutionary biology, 01 natural sciences, Shrub, resistance, expansion, Dominance (ecology), resilience, Nature and Landscape Conservation, geography, geography.geographical_feature_category, Ecology, biology, ved/biology, Plant Sciences, fuel control, Understory, Herbaceous plant, biology.organism_classification, 010601 ecology, Agronomy, Environmental science, Animal Science and Zoology, Juniper, Weed, sagebrush, encroachment

Abstract

Piñon (Pinus spp.) and juniper (Juniperus spp.) expansion and infilling in sagebrush (Artemisia L.) steppe communities can lead to high-severity fire and annual weed dominance. To determine vegetation response to fuel reduction by tree mastication (shredding) or seeding and then shredding, we measured cover for shrub and herbaceous functional groups on shredded and adjacent untreated areas on 44 sites in Utah. We used mixed model analysis of covariance to determine significant differences among ecological site type (expansion and tree climax) and treatments across a range of pretreatment tree cover as the covariate. Although expansion and tree climax sites differed in cover values for some functional groups, decreasing understory cover with increasing tree cover and increased understory cover with tree reduction was similar for both ecological site types. Shrub cover decreased by 50% when tree cover exceeded 20%. Shredding trees at ≤ 20% cover maintained a mixed shrub (18.6% cover)−perennial herbaceous (17.6% cover) community. Perennial herbaceous cover decreased by 50% when tree cover exceeded 40% but exceeded untreated cover by 11% (20.1% cover) when trees were shredded at 15−90% tree cover. Cheatgrass (Bromus tectorum L.) cover also increased after tree shredding or seeding and then shredding but was much less dominant (< 10% cover) where perennial herbaceous cover exceeded 42%. Sites with high cheatgrass cover on untreated plots had high cheatgrass cover on shredded and seeded-shredded plots. Seeding and then shredding decreased cheatgrass cover compared with shredding alone when implemented at tree cover ≥ 50%. Vegetation responses to shredding on expansion sites were generally similar to those for tree cutting treatments in the SageSTEP study. Shredding or seeding and then shredding should facilitate wildfire suppression, increase resistance to weed dominance, and lead toward greater resilience to disturbance by increasing perennial herbaceous cover.

Published

2016

26. Crested Wheatgrass Control and Native Plant Establishment in Utah

Author

Bruce A. Roundy, Brad Jessop, and April Hulet

Subjects

Ecology, Randomized block design, Introduced species, Management, Monitoring, Policy and Law, Native plant, Biology, biology.organism_classification, Weed control, Agropyron cristatum, Agronomy, Dominance (ecology), Animal Science and Zoology, Rangeland, Weed, Nature and Landscape Conservation

Abstract

Effective control methods need to be developed to reduce crested wheatgrass (Agropyron cristatum [L.] Gaertner) monocultures and promote the establishment of native species. This research was designed to determine effective ways to reduce crested wheatgrass and establish native species while minimizing weed invasion. We mechanically (single- or double-pass disking) and chemically (1.1 L ? ha 21 or 3.2 L ? ha 21 glyphosate–Roundup Original Max) treated two crested wheatgrass sites in northern Utah followed by seeding native species in 2005 and 2006. The study was conducted at each site as a randomized block split plot design with five blocks. Following wheatgrass-reduction treatments, plots were divided into 0.2-ha subplots that were either unseeded or seeded with native plant species using a Truax Rough Rider rangeland drill. Double-pass disking in 2005 best initially controlled wheatgrass and decreased cover from 14% to 6% at Lookout Pass and from 14% to 4% at Skull Valley in 2006. However, crested wheatgrass recovered to similar cover percentages as untreated plots 2–3 yr after wheatgrass-reduction treatments. At the Skull Valley site, cheatgrass cover decreased by 14% on herbicide-treated plots compared to an increase of 33% on mechanical-treated plots. Cheatgrass cover was also similar on undisturbed and treated plots 2 yr and 3 yr after wheatgrass-reduction treatments, indicating that wheatgrass recovery minimized any increases in weed dominance as a result of disturbance. Native grasses had high emergence after seeding, but lack of survival was associated with short periods of soil moisture availability in spring 2007. Effective wheatgrass control may require secondary treatments to reduce the seed bank and open stands to dominance by seeded native species. Manipulation of crested wheatgrass stands to restore native species carries the risk of weed invasion if secondary treatments effectively control the wheatgrass and native species have limited survival due to drought.

Published

2010

27. Utilizing National Agriculture Imagery Program Data to Estimate Tree Cover and Biomass of Piñon and Juniper Woodlands

Author

Ryan R. Jensen, April Hulet, Stephen C. Bunting, Steven L. Petersen, Darrell B. Roundy, Bruce A. Roundy, and Society for Range Management

Subjects

Canopy, eCognition® Developer, Steppe, Woodland, Management, Monitoring, Policy and Law, remote sensing, National Agriculture Imagery Program, Nature and Landscape Conservation, Tree canopy, Biomass (ecology), geography, geography.geographical_feature_category, biology, Ecology, biomass, Agroforestry, Plant Sciences, Forestry, biology.organism_classification, Pinus, Juniperus, object-based image analysis, Environmental science, Animal Science and Zoology, Juniper, Rangeland

Abstract

With the encroachment of piñon (Pinus ssp.) and juniper (Juniperus ssp.) woodlands onto sagebrush steppe rangelands, there is an increasing interest in rapid, accurate, and inexpensive quantification methods to estimate tree canopy cover and aboveground biomass. The objectives of this study were 1) to evaluate the relationship and agreement of piñon and juniper (P-J) canopy cover estimates, using object-based image analysis (OBIA) techniques and National Agriculture Imagery Program (NAIP, 1-m pixel resolution) imagery with ground measurements, and 2) to investigate the relationship between remotely-sensed P-J canopy cover and ground-measured aboveground biomass. For the OBIA, we used eCognition® Developer 8.8 software to extract tree canopy cover from NAIP imagery across 12 P-J woodlands within the Sagebrush Steppe Treatment Evaluation Project (SageSTEP) network. The P-J woodlands were categorized based on the dominant tree species found at the individual sites for the analysis (western juniper, Utah juniper, and mixed P-J community). Following tree canopy cover extractions, relationships were assessed between remotely-sensed canopy cover and ground-measured aboveground biomass. Our OBIA estimates for P-J canopy cover were highly correlated with ground-measured tree canopy cover (averaged across all regions r = 0.92). However, differences between methods occurred for western and Utah juniper sites (P 40%. There were high degrees of correlation between predicted aboveground biomass estimates with the use of remotely-sensed tree canopy cover and ground-measured aboveground biomass (averaged across all regions r = 0.89). Our results suggest that OBIA methods combined with NAIP imagery can provide land managers with quantitative data that can be used to evaluate P-J woodland cover and aboveground biomass rapidly, on broad scales. Although some accuracy and precision may be lost when utilizing aerial imagery to identify P-J canopy cover and aboveground biomass, it is a reasonable alternative to ground monitoring and inventory practices.

Published

2015

28. Winter grazing can reduce wildfire size, intensity and behaviour in a shrub-grassland

Author

April Hulet, Kirk W. Davies, Chad S. Boyd, and Jon D. Bates

Subjects

0106 biological sciences, Wildfire suppression, geography, geography.geographical_feature_category, 010504 meteorology & atmospheric sciences, Ecology, Fire regime, ved/biology, ved/biology.organism_classification_rank.species, Forestry, Vegetation, 010603 evolutionary biology, 01 natural sciences, Shrub, Grassland, Boreal, Agronomy, Grazing, Environmental science, Rangeland, 0105 earth and related environmental sciences

Abstract

An increase in mega-fires and wildfires is a global issue that is expected to become worse with climate change. Fuel treatments are often recommended to moderate behaviour and decrease severity of wildfires; however, the extensive nature of rangelands limits the use of many treatments. Dormant-season grazing has been suggested as a rangeland fuel treatment, but its effects on fire characteristics are generally unknown. We investigated the influence of dormant-season (winter) grazing by cattle (Bos taurus) on fuel characteristics, fire behaviour and area burned in Wyoming big sagebrush (Artemisia tridentata subsp. wyomingensis) shrub-grassland communities in south-eastern Oregon, USA. Winter grazing was applied for 5 years before burning and compared with ungrazed areas. Winter grazing decreased fine fuels and increased fine fuel moisture, which reduced flame height and depth, rate of spread and area burned. Winter-grazed areas also had lower maximum temperature and heat loading during fires than ungrazed areas, and thereby decreased risk of fire-induced mortality of important herbaceous functional groups. These results suggest that winter grazing may be a fuel management treatment that can be applied across vast shrub-grasslands to decrease wildfire risk and fire intensity to mediate climate change effects on wildfire activity.

Published

2016

29. Winter grazing decreases the probability of fire-induced mortality of bunchgrasses and may reduce wildfire size: a response to Smith et al. (this issue)

Author

April Hulet, Kirk W. Davies, Chad S. Boyd, and Jon D. Bates

Subjects

040101 forestry, 0106 biological sciences, Ecology, Fire regime, Perennial plant, Tussock, Forestry, 04 agricultural and veterinary sciences, Vegetation, 010603 evolutionary biology, 01 natural sciences, El Niño Southern Oscillation, Increased risk, Geography, Boreal, Grazing, 0401 agriculture, forestry, and fisheries

Abstract

A recent commentary by Smith et al. (2016) argues that our study (Davies et al. 2016) contained methodological errors and lacked data necessary to support our conclusions, in particular that winter grazing may reduce the probability of fire-induced mortality of bunchgrasses. Carefully reading Davies et al. (2016) and relevant literature provides strong evidence that the comments of Smith et al. are unfounded. Most notably, Smith et al. (2016) state that thermocouples placed in the air have no correlation to temperatures experienced by vegetation. However, in our study, thermocouples were placed inside the centre of meristematic crowns of bunchgrasses, as was clearly stated in the methods. Nowhere in the manuscript does it say that thermocouples were placed in the air. Duration of elevated temperatures has been repeatedly linked to an increased risk of fire-induced mortality of vegetation in the literature, contrary to claims by Smith et al. (2016) that no evidence of a relationship exists. The conclusion that winter grazing may decrease the likelihood of perennial bunchgrass mortality was not based solely on data collected in this experiment, but also Davies et al. (2009), where post-fire bunchgrass density and production in ungrazed areas were less than half those of grazed areas.

Published

2016

30. An object-based image analysis of pinyon and juniper woodlands treated to reduce fuels

Author

Bruce A. Roundy, Steven L. Petersen, Ryan R. Jensen, Stephen C. Bunting, and April Hulet

Subjects

Conservation of Natural Resources, Steppe, Forest management, Geographic Mapping, Woodland, Land cover, Forests, Fires, Oregon, Image Processing, Computer-Assisted, Southwestern United States, Global and Planetary Change, geography, geography.geographical_feature_category, Ecology, biology, Prescribed burn, Forestry, biology.organism_classification, Pinus, Pollution, Thematic Mapper, Juniperus, Remote Sensing Technology, Environmental science, Juniper, Rangeland

Abstract

Mechanical and prescribed fire treatments are commonly used to reduce fuel loads and maintain or restore sagebrush steppe rangelands across the Great Basin where pinyon (Pinus) and juniper (Juniperus) trees are encroaching and infilling. Geospatial technologies, particularly remote sensing, could potentially be used in these ecosystems to (1) evaluate the longevity of fuel reduction treatments, (2) provide data for planning and designing future fuel-reduction treatments, and (3) assess the spatial distribution of horizontal fuel structure following fuel-reduction treatments. High-spatial resolution color-infrared imagery (0.06-m pixels) was acquired for pinyon and juniper woodland plots where fuels were reduced by either prescribed fire, tree cutting, or mastication at five sites in Oregon, California, Nevada, and Utah. Imagery was taken with a Vexcel UltraCam X digital camera in June 2009. Within each treatment plot, ground cover was measured as part of the Sagebrush Steppe Treatment Evaluation Project. Trimble eCognition Developer was used to classify land cover classes using object-based image analysis (OBIA) techniques. Differences between cover estimates using OBIA and ground-measurements were not consistently higher or lower for any land cover class and when evaluated for individual sites, were within ±5 % of each other. The overall accuracy and the K hat statistic for classified thematic maps for each treatment were: prescribed burn 85 % and 0.81; cut and fell 82 % and 0.77, and mastication 84 % and 0.80. Although cover assessments from OBIA differed somewhat from ground measurements, they are sufficiently accurate to evaluate treatment success and for supporting a broad range of management concerns.

Published

2012

31. Dormant season grazing may decrease wildfire probability by increasing fuel moisture and reducing fuel amount and continuity

Author

Jon D. Bates, Chad S. Boyd, April Hulet, and Kirk W. Davies

Subjects

Wildfire suppression, Biomass (ecology), Ecology, Fire regime, Agronomy, Perennial plant, Agroforestry, Tussock, Grazing, Fire protection, Environmental science, Forestry, Rangeland

Abstract

Mega-fires and unprecedented expenditures on fire suppression over the past decade have resulted in a renewed focus on presuppression management. Dormant season grazing may be a treatment to reduce fuels in rangeland, but its effects have not been evaluated. In the present study, we evaluated the effect of dormant season grazing (winter grazing in this ecosystem) by cattle on fuel characteristics in sagebrush (Artemisia L.) communities at five sites in south- eastern Oregon. Winter grazing reduced herbaceous fuel cover, continuity, height and biomass without increasing exotic annual grass biomass or reducing bunchgrass basal area or production. Fuel moisture in winter-grazed areas was high enough that burning was unlikely until late August; in contrast, fuels in ungrazed areas were dry enough to burn in late June. Fuel biomasson perennial bunchgrasses was decreased by 60% with winter grazing, whichmayreduce the potential for fire-induced mortality. The cumulative effect of winter grazing from altering multiple fuel characteristics may reduce the likelihood of fire and the potential severity in sagebrush communities with an understorey dominated by herbaceous perennials. Dormant season grazing has the potential to reduce wildfire suppression expenditures in many rangelands where herbaceous fuels are an issue; however, increasing woody vegetation and extreme fire weather may limit its influence. Additional keywords: fuel management, sagebrush, sage-grouse habitat, wildfire suppression, winter grazing.

Published

2015

32. Predicting fire-based perennial bunchgrass mortality in big sagebrush plant communities

Author

Chad S. Boyd, April Hulet, and Kirk W. Davies

Subjects

Ecology, Perennial plant, Fire regime, Tussock, ved/biology, ved/biology.organism_classification_rank.species, food and beverages, Forestry, Plant community, Vegetation, Shrub, Basal area, Boreal, Environmental science

Abstract

Maintenance and post-fire rehabilitation of perennial bunchgrasses is important for reducing the spread of exotic annual grass species in big sagebrush plant communities. Post-fire rehabilitation decisions are hampered by a lack of tools for determining extent of fire-induced perennial grass mortality. Our objective was to correlate post-fire characteristics with perennial bunchgrass mortality at the plant and plant community scales. We recorded basal area, percent char, depth of burn and soil colour for 174 bunchgrasses across four ecological sites after a 65 000 ha wildfire in south-east Oregon and assessed plant mortality. Mortality was correlated with post-fire soil colour and ecological site; soil colours (black and grey) associated with pre-fire shrub presence had up to five-fold higher mortality than brown soils typical of interspace locations. Models incorporating depth of burn and soil colour correctly predicted mortality for 90% of individual plants; cover of brown soil explained 88% of the variation in bunchgrass mortality at the plant community scale. Our results indicate that soil colour and depth of burn are accurate predictors of bunchgrass mortality at individual plant and plant community scales and could be used to spatially allocate post-fire bunchgrass rehabilitation resources.

Published

2015