可燃物处理对大兴安岭地区主要林型火行为的影响

doi:10.11707/j.1001-7488.20210214

Abstract

Abstract:

Objective: The aim of this paper is to provide scientific reference on fuel management by analyzing the effect of the fuel treatments on fire behavior of the main forest types in Daxing'anling. Method: In this study, three 20 m×20 m plots were set in each forest type during fire season of 2019, and four 10 m×10 m sub-plots were further divided in each plot. The forest types included natural forests of Larix gmelinii (Larch natural forest), Betula platyphylla (Birch natural forest), and coniferous and broad-leaf mixed forest (Larch and birch natural mixed forest), and plantations of L. gmelinii (Larch plantation) and Pinus sylvestris var. mongolica (Mongolian Scots pine plantation). The forest structure of each plot was investigated, and then four sub-plots were treated with combustible materials, including cutting dead shrubs and herbs, clearing dead branches and surface litter. The combustible materials in sub-plot were treated with four intensities (untreated, low, mid, and high intensive treatment) respectively. After low intensity treatment, there were no inflammable and dead shrubs and grass in the forest and large combustible materials on the surface (> 10 h). After medium intensity treatment, all fallen trees, shrubs and small trees were removed. After high intensity treatment, the combustible materials on the surface would not support the continuous combustion and spreading of fire. The Fuel Characteristic Classification System (FCCS) was used to simulate fire behaviors for each plot under the ordinary weather scenario and drought scenario. Result: The simulation results showed that the surface fire spread decreased by 51.6% and 42.8% for Larch natural forest and plantation under the ordinary weather scenario after fuel treatments in low intensity, respectively. The flame length dropped by 33.6% and 39.4%, and the fire intensity decreased by 33.6% and 39.4%. However, the surface fire behavior did not change significantly after the low intensity treatment in larch and birch natural mixed forest, birch natural forest, and Mongolian Scots pine plantation. The surface fire spread rate decreased by 29.4%, 37.1%, 79.1%, 83.3%, and 19.7% after mid intensity treatment in mixed forest, birch forest, larch natural forest, larch plantation, and Mongolian Scots pine plantation, respectively, and flame length decreased by 33.3%, 29.8%, 67.2%, 69.7% and 38.1%. The surface fire spread rate decreased by 95.3%, 97.6%, 85.7%, 88.9%, and 77.6% after high intensity treatment in larch natural forest, larch plantation, larch and birch natural mixed forest, birch natural forest, and Mongolian Scots pine plantation, and flame length dropped by 93.1%, 93.9%, 92.6%, 87.6%, and 87.3%, respectively. The surface fire behavior under the drought scenario in all forest types decreased significantly with the increasing intensity of fuel treatment (P < 0.01). The crown fire behavior under the drought scenario decreased significantly after fuel treatments for larch natural forest and plantation, larch and birch natural mixed forest, and Mongolian Scots pine plantation (P < 0.01). Conclusion: The surface fire spread rate is less than 1 m·min^-1, and flame length below 1 m under ordinary weather scenario after mid-intensity treatment in mixed forest, birch forest, larch natural forest, and Mongolian Scots pine plantation. The surface fire spread rate and flame length are less than 0.1 m·min^-1 and 0.1 m in larch plantation, respectively. Those fires can be suppressed directly. Crown fires may drop by more than 20% and fire spread rate decreases more than 40% under drought scenario after mid-intensity treatment in mixed forest, Mongolian Scots pine plantation, larch natural forest, and larch plantation. High intensity treatment might affect the forest structure and environment. We recommend the mid-intensity treatment on fuel management for the region.

Key words: fuel characteristic classification system, fuel treatment, fire behavior

CLC Number:

Xuezheng Zong,Xiaorui Tian. Impacts of Fuel Treatment on Potential Fire Behavior of Main Forest Types in Daxing'anling[J]. Scientia Silvae Sinicae, 2021, 57(2): 139-149.

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References 0

	陈百灵, 朱玉杰, 董希斌, 等. 抚育强度对大兴安岭落叶松林枯落物持水能力及水质的影响. 东北林业大学学报, 2017, 43 (8): 46- 49, 70.
	Chen B L , Zhu Y J , Dong X B , et al. Water conservation under different fostering intensity in timber forest of Daxing'an Mountains. Journal of Northeast Forestry University, 2017, 43 (8): 46- 49, 70.
	陈宏伟, 常禹, 胡远满, 等. 大兴安岭呼中林区森林死可燃物载量及其影响因子. 生态学杂志, 2008, (1): 50- 55.
	Chen H W , Chang Y , Hu Y M , et al. Load of forest surface dead fuel in Huzhong area of Daxing'anling Mountains and relevant affecting factors. Chinese Journal of Ecology, 2008, (1): 50- 55.
	陈宏伟, 胡远满, 常禹, 等. 呼中林区不同森林采伐方式对林火的长期影响模拟. 北京林业大学学报, 2011, 33 (5): 13- 19.
	Chen H W , Hu Y M , Chang Y , et al. Simulating long-term effects of different harvesting modes on forest fire in Huzhong Forest Region, northeastern China. Journal of Beijing Forestry University, 2011, 33 (5): 13- 19.
	高仲亮, 李岩泉, 张明远. 大兴安岭南部草甸计划烧除的防火效果评估. 林业机械与木工设备, 2015, 43 (8): 19- 21. doi: 10.3969/j.issn.2095-2953.2015.08.004
	Gao Z L , Li Y Q , Zhang M Y . Evaluation of fire prevention effect of planned burning of meadow in southern Daxing'anling. Forestry Machinery and Woodworking Equipment, 2015, 43 (8): 19- 21. doi: 10.3969/j.issn.2095-2953.2015.08.004
	胡海清, 罗斯生, 罗碧珍, 等. 森林可燃物含水率及其预测模型研究进展. 世界林业研究, 2017, 30 (3): 64- 69.
	Hu H Q , Luo S S , Luo B Z , et al. Forest fuel moisture content and its prediction model. World Forestry Research, 2017, 30 (3): 64- 69.
	黄小荣, 侯远瑞, 庞世龙, 等. 南宁老虎岭马尾松林间伐前后的火行为. 东北林业大学学报, 2015, 43 (7): 92- 96. doi: 10.3969/j.issn.1000-5382.2015.07.021
	Huang X R , Hou Y R , Pang S L , et al. Fire behavior of Pinus massoniana forest pre-thinning and post-thinning in Tiger Mountain, Nanning. Journal of Northeast Forestry University, 2015, 43 (7): 92- 96. doi: 10.3969/j.issn.1000-5382.2015.07.021
	黄小荣, 申文辉, 庞世龙, 等. 南宁老虎岭松栎公益林的火潜势评估. 生态学杂志, 2014, 33 (3): 602- 610.
	Huang X R , Shen W H , Pang S L , et al. Evaluating fire potential of non-commercial pine-beech forests in Tiger Mountain, Nanning. Chinese Journal of Ecology, 2014, 33 (3): 602- 610.
	李红振, 李凤日, 贾炜玮. 大兴安岭不同类型白桦落叶松混交林枯落物水源涵养功能. 东北林业大学学报, 2014, 42 (6): 43- 46, 52. doi: 10.3969/j.issn.1000-5382.2014.06.010
	Li H Z , Li F R , Jia W W . Water conservation of litterfall in different mixed forest types of white birch and larch in Daxing'an Mountain. Journal of Northeast Forestry University, 2014, 42 (6): 43- 46, 52. doi: 10.3969/j.issn.1000-5382.2014.06.010
	梁瀛, 李吉玫, 赵凤君, 等. 天山中部天山云杉林地表可燃物载量及其影响因素. 林业科学, 2017, 53 (12): 153- 160. doi: 10.11707/j.1001-7488.20171218
	Liang Y , Li J M , Zhao F J , et al. Surface fuel loads of Tianshan spruce forests in the Central Tianshan Mountains and the impact factors. Scientia Silvae Sinicae, 2017, 53 (12): 153- 160. doi: 10.11707/j.1001-7488.20171218
	刘志华, 常禹, 贺红士, 等. 模拟不同森林可燃物处理对大兴安岭潜在林火状况的影响. 生态学杂志, 2009, 28 (8): 1462- 1469.
	Liu Z H , Chang Y , He H S , et al. Effects of different forest fuel treatments on potential forest fire regimes in Great Xing'an Mountains: a simulation study. Chinese Journal of Ecology, 2009, 28 (8): 1462- 1469.
	马振宇, 陈博伟, 庞勇, 等. 基于林火特征分类模型的森林火情等级制图. 国土资源遥感, 2020, 32 (1): 43- 50.
	Ma Z Y , Chen B W , Pang Y , et al. Forest fire potential forecast based on FCCS model. Remote Sensing for Land and Resources, 2020, 32 (1): 43- 50.
	田晓瑞, 舒立福, 王明玉. 林火动态变化对我国东北地区森林生态系统的影响. 森林防火, 2005, (1): 21- 25. doi: 10.3969/j.issn.1002-2511.2005.01.010
	Tian X R , Shu L F , Wang M Y . Influences of fire regime changes on the forest ecosystem in northeast China. Forest Fire Prevention, 2005, (1): 21- 25. doi: 10.3969/j.issn.1002-2511.2005.01.010
	吴志伟, 贺红士, 梁宇, 等. 丰林自然保护区森林可燃物模型的建立. 应用生态学报, 2012, 23 (6): 1503- 1510.
	Wu Z W , He H S , Liang Y . Establishment of standard forest fuel models for Fenglin Natural Reserve, Heilongjiang Province, China. Chinese Journal of Applied Ecology, 2012, 23 (6): 1503- 1510.
	徐化成. 中国大兴安岭森林. 北京: 科学出版社, 1998.
	Xu H C . The forest of Daxing'anling. Beijing: Science Press, 1998.
	张思玉, 兰海涛. 针叶幼林树冠火发生的内在机制. 东北林业大学学报, 1998, (5): 78- 81.
	Zhang S Y , Lan H T . The internal cause of occurencing crown fire in young coniferous forest. Journal of Northeast Forestry University, 1998, (5): 78- 81.
	赵彬清, 胡同欣, 李飞, 等. 计划火烧对阿里河兴安落叶松林土壤呼吸影响. 森林工程, 2018, 34 (4): 21- 26. doi: 10.3969/j.issn.1006-8023.2018.04.004
	Zhao B Q , Hu T X , Li F , et al. Effects of soil respiration of Larix gmelinii forest and the response to prescribed fire in the Greater Xing'an Mountains. Forest Engineering, 2018, 34 (4): 21- 26. doi: 10.3969/j.issn.1006-8023.2018.04.004
	赵凤君, 王明玉, 舒立福. 森林火灾中的树冠火研究. 世界林业研究, 2010, 23 (1): 39- 43.
	Zhao F J , Wang M Y , Shu L F . A review of crown fire research. World Forestry Research, 2010, 23 (1): 39- 43.
	周道玮, 张正祥, 靳英华, 等. 东北植被区划及其分布格局. 植物生态学报, 2010, 34 (12): 1359- 1368.
	Zhou D W , Zhang Z X , Jin Y H , et al. Regionalization and distribution pattern of vegetation of Northeast China. Chinese Journal of Plant Ecology, 2010, 34 (12): 1359- 1368.
	Agee J K , Skinner C N . Basic principles of forest fuel reduction treatments. Forest Ecology and Management, 2005, 211 (1/2): 83- 96.
	Anderson H E . Forest fuel ignitibility. Fire Technology, 1970, 6 (4): 312- 319. doi: 10.1007/BF02588932
	Arroyo L A , Pascual C , Manzanera J A . Fire models and methods to map fuel types: the role of remote sensing. Forest Ecology and Management, 2008, 256 (6): 1239- 1252. doi: 10.1016/j.foreco.2008.06.048
	Barnett K , Parks S , Miller C , et al. Beyond fuel treatment effectiveness: characterizing interactions between fire and treatments in the US. Forests, 2016, 7 (10): 237.
	Bradstock R A , Bedward M , Cohn J S . The modelled effects of differing fire management strategies on the conifer Callitris verrucosa within semi-arid mallee vegetation in Australia. Journal of Applied Ecology, 2006, 43 (2): 281- 292. doi: 10.1111/j.1365-2664.2006.01142.x
	Bradstock R A , Hammill K A , Collins L , et al. Effects of weather, fuel and terrain on fire severity in topographically diverse landscapes of south-eastern Australia. Landscape Ecology, 2010, 25 (4): 607- 619.
	Chang Y , He H S , Bishop I , et al. Long-term forest landscape responses to fire exclusion in the Great Xing'an Mountains, China. International Journal of Wildland Fire, 2007, 16 (1): 34- 44.
	Chiono L A , Fry D L , Collins B M , et al. Landscape-scale fuel treatment and wildfire impacts on carbon stocks and fire hazard in California spotted owl habitat. Ecosphere, 2017, 8 (1): e01648.
	Fang L , Yang J , Zu J X , et al. Quantifying influences and relative importance of fire weather, topography, and vegetation on fire size and fire severity in a Chinese boreal forest landscape. Forest Ecology and Management, 2015, 356, 2- 12.
	Hollingsworth L W T , Kurth L L , Parresol B R , et al. A comparison of geospatially modeled fire behavior and fire management utility of three data sources in the southeastern United States. Forest Ecology and Management, 2012, 273, 43- 49.
	Keane R E , Gray K , Bacciu V , et al. Spatial scaling of wildland fuels for six forest and rangeland ecosystems of the northern Rocky Mountains, USA. Landscape Ecology, 2012, 27 (8): 1213- 1234.
	McGinnis T W , Keeley J E , Stephens S L , et al. Fuel buildup and potential fire behavior after stand-replacing fires, logging fire-killed trees and herbicide shrub removal in Sierra Nevada forests. Forest Ecology and Management, 2010, 260 (1): 22- 35.
	Moghaddas J J , Collins B M , Menning K , et al. Fuel treatment effects on modeled landscape-level fire behavior in the northern Sierra Nevada. Canadian Journal of Forest Research, 2010, 40 (9): 1751- 1765.
	Ottmar R D , Blake J I , Crolly W T . Using fine-scale fuel measurements to assess wildland fuels, potential fire behavior and hazard mitigation treatments in the southeastern USA. Forest Ecology and Management, 2012, 273, 1- 3.
	Ottmar R D , Sandberg D V , Riccardi C L , et al. An overview of the fuel characteristic classification system-quantifying, classifying, and creating fuelbeds for resource planning. Canadian Journal of Forest Research, 2007, 37 (12): 2383- 2393.
	Parresol B R , Blake J I , Thompson A J . Effects of overstory composition and prescribed fire on fuel loading across a heterogeneous managed landscape in the southeastern USA. Forest Ecology and Management, 2012, 273, 29- 42.
	Pettinari M L , Chuvieco E . Generation of a global fuel data set using the Fuel Characteristic Classification System. Biogeosciences, 2016, 12 (20): 2061- 2076.
	Pollet J , Omi P N . Effect of thinning and prescribed burning on crown fire severity in ponderosa pine forests. International Journal of Wildland Fire, 2002, 11 (1): 1- 10.
	Prichard S J , Ottmar R D , Sandberg D V , et al. FCCS User's Guide Version 2. 0. Pacific Wildland Fire Sciences Laboratory, 2011, 1- 121.
	Riccardi C L , Prichard S J , Sandberg D V , et al. Quantifying physical characteristics of wildland fuels using the Fuel Characteristic Classification System. Canadian Journal of Forest Research, 2007, 37 (12): 2413- 2420.
	Rothermel R C. 1972. A mathematical model for predicting fire spread in wildland fuels. USDA, Forest Service Research Paper, INR-115.
	Salis M , Laconi M , Ager A A , et al. Evaluating alternative fuel treatment strategies to reduce wildfire losses in a Mediterranean area. Forest Ecology and Management, 2016, 368, 207- 221.
	Sandberg D V , Riccardi C L , Schaaf M D . Fire potential rating for wildland fuelbeds using the Fuel Characteristic Classification System. Canadian Journal of Forest Research, 2007, 37 (12): 2456- 2463.
	Tian X R , Cui W B , Shu L F . Evaluating fire suppression effectiveness with a burn probability model in Daxing'anling, China. Canadian Journal of Forest Research, 2020, 50, 670- 679.
	Tian X R , Shu L F , Zhao F J , et al. Future impacts of climate change on forest fire danger in northeastern China. Journal of Forestry Research, 2011, 22 (3): 437. doi: 10.1007/s11676-011-0185-5
	Wu Z , He H S , Liu Z , et al. Comparing fuel reduction treatments for reducing wildfire size and intensity in a boreal forest landscape of northeastern China. Science of the Total Environment, 2013, 454, 30- 39.

年份 Year	火发生次数 Fire number	森林过火面积 Burned area/hm²
2000	94	19 698.2
2001	18	93.7
2002	87	121.5
2003	71	251 373.4
2004	22	18 829.1
2005	58	21 992.1
2006	17	81 121.1
2007	100	817.0
2008	84	4 187.4
2009	54	2 606.1
2010	30	1 539.9
2011	44	58.5
2012	49	235.0
2013	14	11.0
2014	33	140.9
2015	94	157.7
2016	29	42.5
2017	97	238.7
2018	44	2 411.6
合计Total	1 039	405 675.4

样地 Plot	林分起源 Forest types	树种组成^① Tree species composition	林龄 Stand age/a	郁闭度 Canopy density	树高 Average height/ m	胸径 Average DBH/cm	密度 Density/(hm^-2)	可燃物梯Ladder fuels		海拔 Altitude/m	坡向 Aspect	坡度 Slope(%)
样地 Plot	林分起源 Forest types	树种组成^① Tree species composition	林龄 Stand age/a	郁闭度 Canopy density	树高 Average height/ m	胸径 Average DBH/cm	密度 Density/(hm^-2)	最低 Min. height/m	最高 Max. height/m	海拔 Altitude/m	坡向 Aspect	坡度 Slope(%)
1	天然林 Natural forest	8Lg 2Bp	Lg24 Bp20	0.90	12.4/9.4	10.4/12.5	2 940/735	0.3	9.0	517.8	阳坡 Sunny	12
2			Lg24 Bp20	0.90	11.8/10.4	10.2/12.2	3 140/785	0.3	9.0	509.1		12
3			Lg24 Bp20	0.90	11.6/10.7	10.2/11.4	2 800/700	0.3	9.0	523.4		12
4		Bp	30	0.90	13.9	10.5	2 225	8.5	11.5	631.1	阳坡 Sunny	8
5			30	0.87	13.6	11.5	2 175	8.5	11.7	629.2		8
6			30	0.90	13.7	10.2	2 400	8.0	12.5	625.7		7
7		Lg	25	0.90	12.6	11.1	2 450	0.2	10.7	544.9	阳坡 Sunny	8
8			25	0.90	11.2	10.1	3 200	0.2	11.0	538.4		8
9			25	0.90	12.3	10.9	3 425	0.2	11.0	533.6		8
10	人工林 Plantation	Lg	33	0.84	15.1	13.2	2 600	2.7	13.4	352.7	阳坡 Sunny	7
11			33	0.85	15.7	14.2	2 525	2.5	13.5	354.6		7
12			33	0.85	15.4	14.6	2 200	2.5	13.0	351.5		7
13		Ps	35	0.80	11.7	12.3	2 250	1.3	9.5	381.1	阳坡 Sunny	4
14			35	0.80	11.3	12.4	2 150	1.2	9.7	385.3		3
15			35	0.80	11.3	12.2	2 200	1.2	9.5	384.5		3

	类型Types	描述Description
潜在地表火行为 Surface fire behavior potential(SFBP)	潜在火强度Fire intensity potential(RP)	单位面积每分钟释放能量 Energy release per unit area per unit time
	潜在蔓延速度Spread potential(SP)	与蔓延速度呈比例(单位时间蔓延距离) Proportional to the spread(Distance per unit time)
	潜在火焰长度 Flame length potential(FP)	火焰最高点与燃烧区中部位置的距离 Distance between the flame tip and the middle of the flaming zone at the base of the fire
潜在树冠火行为 Crown fire behavior potential(CFBP)	潜在树冠火发生指数 Crown fire initiation potential(Ic)	地表火转化为树冠火危险性 Likelihood that surface fire will propagate into crown fires
	潜在树冠火蔓延指数 Crown-to-crown transmissivity potential(Tc)	火在树冠蔓延的危险性 Likelihood of fire through forest canopy
	潜在蔓延速度指数 Crown fire spread rate potential(Rc)	潜在树冠火蔓延速度的相对指标 Relative index of crown fire spread potential

[1]	Miao Qinglin, Tian Xiaorui. Assessment of Burn Probability Assessment in Daxing'anling under Multi-Climatic Scenarios [J]. Scientia Silvae Sinicae, 2016, 52(10): 109-116.
[2]	Tian Xiaorui;Wang Mingyu;Yin Li;Shu Lifu. Fire Behavior and Consumption of Fuel Loadings in Spring Season in Southern Daxing'an Mountains [J]. Scientia Silvae Sinicae, 2009, 12(3): 90-95.
[3]	Gao Baojia;Zhang Guijuan;Zhou Guona;Zhang Hongjun;Yu Zhiyong;Li Lixue;Chi Baoli. Estimation to Dead Surface Combustible Parameters and Evaluation of Potential Surface Fire Behavior of Artificial Coniferous Forests in Chengde County [J]. Scientia Silvae Sinicae, 2009, 12(10): 163-167.
[4]	Wang Qiuhua Shu Lifu Dai Xing'an Wang Mingyu Tian Xiaorui. Effects of Snow and Ice Disasters on Forest Fuel and Fire Behaviors in the Southern China [J]. Scientia Silvae Sinicae, 2008, 44(11): 171-176.
[5]	Jin Sen. Fire Boundary Extracting Technique in Automatic Measurement of Rate of Spread of Forest Fire by Analyzing Series of Images [J]. Scientia Silvae Sinicae, 2007, 43(9): 44-47.
[6]	Shu Lifu;Wang Mingyu;Tian Xiaorui;Zhang Xiaoluo;Dai Xing’an. Calculation and Description of Forest Fire Behavior Characters [J]. Scientia Silvae Sinicae, 2004, 40(3): 179-183.
[7]	Zhang Jingqun;Kang Yongxiang;Wu Kuanrang;Zhou Xinghua. STUDIES ON THE QUANTITATIVE CLASSIFICATION AND DIVIDING INDICES OF POTENTIAL FIRE BEHAVIOR OF FOREST IN QINLING [J]. Scientia Silvae Sinicae, 2001, 37(1): 101-106.

Impacts of Fuel Treatment on Potential Fire Behavior of Main Forest Types in Daxing'anling

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样地Plot	类型Types	活草本含水率 Live herb moisture	活灌木含水率 Live shrub moisture	活冠层含水率 Live crown moisture	不同时滞可燃物含水率			坡度 Slope
样地Plot	类型Types	活草本含水率 Live herb moisture	活灌木含水率 Live shrub moisture	活冠层含水率 Live crown moisture	1 h	10 h	100 h	坡度 Slope
1	兴安落叶松白桦混交林 Larch and birch natural mixed forest	63	78	58	12	14	19	12
2		62	77	58	11	15	19	12
3		63	77	57	12	14	20	12
4	白桦林 Birch natural forest	62	73	59	11	13	19	8
5		60	75	57	9	14	21	8
6		62	73	57	11	14	19	7
7	兴安落叶松天然林 Larch natural forest	63	78	60	11	15	18	8
8		63	78	61	9	16	18	8
9		63	77	60	9	16	17	8
10	兴安落叶松人工林 Larch plantation	60	77	63	8	11	17	7
11		61	77	62	8	12	16	7
12		60	76	62	7	11	17	7
13	樟子松人工林 Mongolian Scots pine plantation	70	80	74	13	16	19	4
14		70	80	73	12	16	22	3
15		70	81	71	12	14	20	3