GIS database development to analyze fire history in southern Arizona and beyond: an example from Saguaro National Park

One of the keystone tree species in subalpine forests of the western United States â whitebark pine (Pinus albicaulis, hereafter whitebark pine) â is experiencing a significant mortality event (Millar et al. 2012). Whitebark pine occupies a relatively restricted range in the high-elevation ecosystems in the northern Rockies and its future is uncertain. The current decline of whitebark pine populations has been attributed to pine beetle infestations, blister rust infections, anthropogenic fire suppression, and climate change (Millar et al. 2012). Despite the knowledge that whitebark pine is severely threatened by multiple stressors, little is known about the historic capacity of this species to handle these stressors. More specifically, it is unknown how whitebark pine has dealt with past climatic variability, particularly variation in the type of precipitation (rain vs. snow) available for soil moisture, and how differences in quantity of precipitation have influenced the establishment and growth of modern stands. We propose to study the past responses of whitebark pine to paleoclimatic conditions, which would be useful to park ecologists in developing new conservation and regeneration plans to prevent the extinction of this already severely threatened high-elevation resource. The purpose of this study is to determine in great temporal and spatial detail the demographics of the current stand of whitebark pine trees in the watershed surrounding an unnamed, high-altitude pond (known informally as Whitebark Pine Moraine Pond) located approximately 3.06 miles NW of Jenny Lake in Grand Teton National Park (GTNP). The main objectives of this study were: 1.) To obtain the precise GPS locations of the current stand of whitebark pine trees in the watershed to generate a GIS map detailing their locations. 2.) To obtain increment cores of a subset of the trees in the watershed to estimate age and date of establishment for the current stand of whitebark pines, with particular attention to fire history. 3.) To analyze ring widths from core samples to identify climatic indicators that may influence the regeneration and survival of whitebark pine.

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FIRE HISTORY OF MIXED-CONIFER FORESTS ON THE NORTH RIM, GRAND CANYON NATIONAL PARK, ARIZONA

Physical Geography ◽

10.1080/02723646.1998.10642637 ◽

1998 ◽

Vol 19 (1) ◽

pp. 1-14 ◽

Cited By ~ 19

Author(s):

Joy J. Wolf ◽

Joy Nystrom Mast

Keyword(s):

National Park ◽

Fire History ◽

Grand Canyon ◽

Conifer Forests ◽

Mixed Conifer ◽

Grand Canyon National Park ◽

The North ◽

Mixed Conifer Forests ◽

History Of ◽

North Rim

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Spatial Dynamics of Invasive Para Grass on a Monsoonal Floodplain, Kakadu National Park, Northern Australia

Remote Sensing ◽

10.3390/rs11182090 ◽

2019 ◽

Vol 11 (18) ◽

pp. 2090

Author(s):

Boyden ◽

Wurm ◽

Joyce ◽

Boggs

Keyword(s):

Satellite Imagery ◽

Wild Rice ◽

National Park ◽

Fire History ◽

Spatial Dynamics ◽

Gradient Boosting ◽

Native Vegetation ◽

Northern Australia ◽

Stochastic Gradient Boosting ◽

The World

African para grass (Urochloa mutica) is an invasive weed that has become prevalent across many important freshwater wetlands of the world. In northern Australia, including the World Heritage landscape of Kakadu National Park (KNP), its dense cover can displace ecologically, genetically and culturally significant species, such as the Australian native rice (Oryza spp.). In regions under management for biodiversity conservation para grass is often beyond eradication. However, its targeted control is also necessary to manage and preserve site-specific wetland values. This requires an understanding of para grass spread-patterns and its potential impacts on valuable native vegetation. We apply a multi-scale approach to examine the spatial dynamics and impact of para grass cover across a 181 km2 floodplain of KNP. First, we measure the overall displacement of different native vegetation communities across the floodplain from 1986 to 2006. Using high spatial resolution satellite imagery in conjunction with historical aerial-photo mapping, we then measure finer-scale, inter-annual, changes between successive dry seasons from 1990 to 2010 (for a 48 km2 focus area); Para grass presence-absence maps from satellite imagery (2002 to 2010) were produced with an object-based machine-learning approach (stochastic gradient boosting). Changes, over time, in mapped para grass areas were then related to maps of depth-habitat and inter-annual fire histories. Para grass invasion and establishment patterns varied greatly in time and space. Wild rice communities were the most frequently invaded, but the establishment and persistence of para grass fluctuated greatly between years, even within previously invaded communities. However, these different patterns were also shown to vary with different depth-habitat and recent fire history. These dynamics have not been previously documented and this understanding presents opportunities for intensive para grass management in areas of high conservation value, such as those occupied by wild rice.

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Visualizing When, Where, and How Fires Happen in U.S. Parks and Protected Areas

ISPRS International Journal of Geo-Information ◽

10.3390/ijgi9050333 ◽

2020 ◽

Vol 9 (5) ◽

pp. 333

Author(s):

Nicole C. Inglis ◽

Jelena Vukomanovic

Keyword(s):

Decision Making ◽

Protected Areas ◽

National Park ◽

Fire History ◽

National Park Service ◽

Fire Management ◽

Fire Regime ◽

Fire Regimes ◽

The United States ◽

Park Service

Fire management in protected areas faces mounting obstacles as climate change alters disturbance regimes, resources are diverted to fighting wildfires, and more people live along the boundaries of parks. Evidence-based prescribed fire management and improved communication with stakeholders is vital to reducing fire risk while maintaining public trust. Numerous national fire databases document when and where natural, prescribed, and human-caused fires have occurred on public lands in the United States. However, these databases are incongruous and non-standardized, making it difficult to visualize spatiotemporal patterns of fire and engage stakeholders in decision-making. We created interactive decision analytics (“VISTAFiRe”) that transform fire history data into clear visualizations of the spatial and temporal dimensions of fire and its management. We demonstrate the utility of our approach using Big Cypress National Preserve and Everglades National Park as examples of protected areas experiencing fire regime change between 1980 and 2017. Our open source visualizations may be applied to any data from the National Park Service Wildland Fire Events Geodatabase, with flexibility to communicate shifts in fire regimes over time, such as the type of ignition, duration and magnitude, and changes in seasonal occurrence. Application of the tool to Everglades and Big Cypress revealed that natural wildfires are occurring earlier in the wildfire season, while human-caused and prescribed wildfires are becoming less and more common, respectively. These new avenues of stakeholder communication are allowing the National Park Service to devise research plans to prepare for environmental change, guide resource allocation, and support decision-making in a clear and timely manner.

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Multi-Millennial Fire History of the Giant Forest, Sequoia National Park, California, USA

Fire Ecology ◽

10.4996/fireecology.0503120 ◽

2009 ◽

Vol 5 (3) ◽

pp. 120-150 ◽

Cited By ~ 48

Author(s):

Thomas W. Swetnam ◽

Christopher H. Baisan ◽

Anthony C. Caprio ◽

Peter M. Brown ◽

Ramzi Touchan ◽

...

Keyword(s):

National Park ◽

Fire History ◽

Sequoia National Park ◽

History Of

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What was burning in the past? Charcoal identifications supplement an early-Holocene fire-history reconstruction in Yellowstone National Park, USA

Quaternary International ◽

10.1016/j.quaint.2020.09.033 ◽

2020 ◽

Author(s):

Dominique Marguerie ◽

Teresa R. Krause ◽

Cathy Whitlock

Keyword(s):

Yellowstone National Park ◽

National Park ◽

Fire History ◽

Early Holocene ◽

The Past

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Fire history and climate-growth response of Abies spectabilis : A case from Langtang National Park, Nepal Himalaya

Banko Janakari ◽

10.3126/banko.v29i2.28093 ◽

2019 ◽

Vol 29 (2) ◽

pp. 3-12

Author(s):

S. Basnet ◽

N. P. Gaire ◽

P. K. Chhetri

Keyword(s):

Tree Ring ◽

Radial Growth ◽

National Park ◽

Fire History ◽

Ring Width ◽

Negative Influence ◽

Himalayan Region ◽

Fire Scars ◽

Fire Event ◽

Abies Spectabilis

This study presents the potential of a conifer species (Abies spectabilis D. Don) to reconstruct fire history by using dendro chronological technique along with thedendroclimatic response in Langtang National Park, Central Himalaya of Nepal. For the fire history reconstruction, altogether eight cross-sections samples from fire affected eight trees and another 20 tree-cores from 10 trees with visible fire scars were taken. In the case of dendroclimatic study, 24 healthy cores of A. spectabilis were selected from the 40 cores extracted from 19 trees. The standard dendro chronological methodology was used for sample preparation and analysis. A 199-year long ring-width chronology of A. spectabilis spanning from 1818 to 2016 AD was developed. In spite of visible fire burn in near bark-surface, no potential fire scars are seen in inner parts in the cross-section samples. However, 12 cores showed that three fire burns occurred simultaneously in the forest area in the years 1917−1918, 1969−1970 and 2009−2010, respectively. Tree-ring-based fire event-record is found to be concurrent to the local people's perceptions/experience about the past fire history in the area. Tree growth climate relationship showed sensitive responses to both growing and non-growing season’s temperature and precipitation variability. Summer temperature had positive influence on growth of the species. Precipitation of monsoon and autumn were found to have negative influence on radial growth whereas pre-monsoon precipitation had positive association with tree radial-growth. This preliminary assessment shows that there is a huge potential of tree-ring research for long-term fire history in the region and helps us to better understand the role of fire in the ecology and management in the Himalayan region. The study can also be replicated in other fire-affected areas of the Himalayan region by using fire sensitive species in the sampling.

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Changes in forest fire frequency in Kootenay National Park, Canadian Rockies

Canadian Journal of Botany ◽

10.1139/b90-227 ◽

1990 ◽

Vol 68 (8) ◽

pp. 1763-1767 ◽

Cited By ~ 57

Author(s):

Alan M. Masters

Keyword(s):

Forest Fire ◽

Rocky Mountains ◽

National Park ◽

Fire History ◽

Fire Suppression ◽

Fire Frequency ◽

Ice Age ◽

Distribution Analysis ◽

Fire Cycle ◽

Time Since Fire

Time-since-fire distribution analysis is used to estimate forest fire frequency for the 1400 km2 Kootenay National Park, British Columbia, located on the west slope of the Rocky Mountains. The time-since-fire distribution indicates three periods of different fire frequency: 1988 to 1928, 1928 to 1788, and before 1788. The fire cycle for the park was > 2700 years for 1988 to 1928, 130 years between 1928 and 1788, and 60 years between 1778 and 1508. Longer fire cycles after 1788 and 1928 may be due, respectively, to cool climate associated with the Little Ice Age and a recent period of higher precipitation. Contrary to some fire history investigations in the region, neither a fire suppression policy since park establishment in 1919, nor the completion of the Windermere Highway through the park in 1923 appear to have changed the fire frequency from levels during pre-European occupation. Spatial partitioning of the time-since-fire distribution was unsuccessful. No relationship was found between elevation or aspect and fire frequency. Key words: fire cycle, Rocky Mountains, climate change.

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Fire history and age structure in red fir forests of Sequoia National Park, California

Canadian Journal of Forest Research ◽

10.1139/x87-098 ◽

1987 ◽

Vol 17 (7) ◽

pp. 582-587 ◽

Cited By ~ 21

Author(s):

Donald C. Pitcher

Keyword(s):

Age Structure ◽

National Park ◽

Fire History ◽

Fire Behavior ◽

White Pine ◽

Sequoia National Park ◽

Fire Scar ◽

Forest Age Structure ◽

Negative Exponential ◽

In Fire

The relationship between historical fires and age structure was examined on three plots in red fir (Abiesmagnifica var. shastensis Lemm.) forests within Sequoia National Park, California, U.S.A. All trees greater than 0.1 m in height were mapped and aged. Fire history was determined from 16 fire-scar sections. Red fir trees are more shade tolerant, longer lived, larger, and slower growing than western white pine (Pinusmonticola Dougl.) on the plots. No fires have occurred since 1886, but prior to that time the average fire-free interval was 65 years. Most of the trees on two of the plots originated after fires, but on the third plot red fir regeneration was delayed for at least 60 years following the last fire. Structural differences between the plots were linked to variations in fire behavior. The decrease in fire frequencies in this century may have led to a decrease in red fir establishment. Excluding the most recent period, the forest age structure is in something of a steady state that approximates a negative exponential age-class distribution.

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