西藏“一江两河”中部流域人工造林对土壤养分和肥力的影响

doi:10.11707/j.1001-7488.LYKX20220015

Abstract

Abstract:

Objective: To provide theoretical reference for afforestation and its stand management in key regions of Tibet, we investigated the difference and changing trends of soil physicochemical properties between planted region and its adjacent area where without planting in the mid-watershed of “One River and Two Tributaries”, Tibet. And the understanding of soil fertility for artificial afforestation was improved systematically to there. Method: In the July to November of 2016, soil samples from four layers (0?20, 20?40, 40?60, 60?80 cm) at the depth of 0?80 cm were surveyed for 54 couples of plots which contained artificial forest (planted region) and its control plot (adjacent to artificial forest, with the same initial conditions, CK). And the soil physicochemical properties such as soil organic matter(SOM), total nitrogen(TN), total phosphorus(TP), total potassium(TK), alkaline nitrogen(AN), available phosphorus(AP), available potassium(AK), soil density(BD), soil mass water content(MWC), pH, and soil particle-size distribution(PSD) were tested. The methods of Wilcoxon signed-ranks Test, soil nutrient classification, PCA were used to analyze and compare the effects of artificial afforest on soil physicochemical properties. Result: Comparing with CK, the BD, TP, and AP for artificial forests in the 0?80 cm soil layer decreased obviously by 6.0%, 10.5%, and 36.5%, respectively. And MWC, TN, SOM increased obviously by 22.4%, 28.6%, 16.8%, respectively. AP varied largest and TN had the highest increase. pH, AK, TK, AN, and PSD changed insignificantly. More than 63.1% of the plots were in slightly deficient level or more worse levels for nitrogen, phosphorus, potassium, and soil organic matter of the CKs, and TN was in the worst nutrient classification. That percentage became to more than 73% for the artificial forests, and AP was in the worst nutrient classification. The plots’ proportion of AP for transferring from no deficient level to deficient level was also the highest. For CKs and artificial forests, the value of soil nutrient classification were ranked as TP>AK>AP>TK>SOM>AN>TN(the nutrient status is better on the left of ‘>’ than that on the right, the same below), TP>AK>TK>TN>SOM>AN>AP, respectively. The soil fertility changed insignificantly, which was comprehensive influenced by SOM, TN, and sand content. Conclusion: In the mid-watershed of “One River and Two Tributaries”, where is the key region for artificial afforestation in Tibet, the artificial afforestation has a obviously influence on the soil physicochemical properties, such as BD, MWC, TN, TP, AP, and SOM. For the artificial forests, the soil physicochemical conditions with soil density, soil mass water content, soil organic matter, nitrogen become better. While the nutrient condition of phosphorus becomes worse. The soil is mostly lack of AP for artificial forests, and its severest nutrient limitation is phosphorus, which is nitrogen for CK. The improvement of soil fertility is limited by AP. Whether afforestation or not, the soil nutrients are generally deficient in there. The soil fertility management should be strengthened for artificial afforestation in Tibet, especially focusing on enhancement the total level of soil nutrients. To improve the afforestation effect and soil fertility, the use of organic fertilizer can be strengthened before afforestation, and the use of phosphate fertilizer can be highlight in the subsequent management.

Key words: artificial afforestation, soil nutrient, nutrient classification, soil fertility, factor scores

CLC Number:

S158.3
S750

Hong Luo, Pubudunzhu,Hongwei Liu, Gamaqunzong,Jianpu Wu,Hongli Wei. Influence of the Artificial Afforestation on Soil Nutrients and Fertility in the Mid-Watershed of “One River and Two Tributaries”, Tibet[J]. Scientia Silvae Sinicae, 2024, 60(4): 71-78.

Figures/Tables 6

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References 0

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统计项Statistical item	人工林Artificial forest			对照地Control plots
统计项Statistical item	均值 Mean	标准差 Standard deviation	样本数 Sample number	均值 Mean	标准差 Standard deviation	样本数 Sample number
BD/(g·cm^?3)	1.40	0.16	170	1.49	0.14	163
MWC/%	16.35	13.07	201	12.96	9.72	201
pH	7.58	0.44	215	7.54	0.41	214
TN/(g·kg^?1)	0.68	0.48	215	0.53	0.37	214
TP/(g·kg^?1)	0.51	0.22	215	0.57	0.27	214
TK/(g·kg^?1)	10.34	1.45	215	10.37	1.40	214
AN/ (mg·kg^?1)	47.49	36.02	215	43.41	26.08	214
AP/ (mg·kg^?1)	4.17	3.24	215	7.72	7.70	214
AK/ (mg·kg^?1)	83.22	104.38	215	77.20	102.42	214
SOM/ (g·kg^?1)	10.28	8.12	215	8.12	7.10	214
SA/ (g·kg^?1)	787.75	42.98	215	789.70	44.97	214
SI/ (g·kg^?1)	125.36	35.52	215	124.30	33.92	214
SL/ (g·kg^?1)	86.88	30.90	214	86.00	32.05	214

样地类型 Plot type	统计项Statistical item	SOM	TN	TP	TK	AN	AP	AK
人工林 Artificial forest	均值Mean value	4.85	4.82	3.99	4.32	4.95	5.16	4.19
	标准差Standard deviation	1.16	1.38	1.06	0.49	1.10	0.92	1.25
	变异系数Coefficient of variation（%）	23.85	28.58	26.65	11.28	22.15	17.83	29.77
	样本数Sample number	215	215	215	215	215	215	215
对照地 Control plots	均值Mean value	5.05	5.23	3.71	4.32	5.07	4.39	4.29
	标准差Standard deviation	1.01	1.11	1.03	0.48	0.90	1.26	1.15
	变异系数Coefficient of variation（%）	20.02	21.28	27.70	11.04	17.72	28.72	26.82
	样本数Sample number	214	214	214	214	214	214	214
Wilcoxon带符号秩检验Wilcoxon signed-ranks test(P)		0.00**	0.00**	0.00**	0.92	0.19	0.00**	0.34

样地类型 Plot type	养分分级 SNC	丰缺度 Abundant or lack degree (ALD)	SOM	TN	TP	TK	AN	AP	AK
人工林 Artificial forest	1	丰Abundant	0.9	2.3	2.3	0	2.8	0	1.4
	2	稍丰Slightly abundant	3.3	4.2	5.6	0	0.5	0.5	8.8
	3	中等Medium	6.0	14.0	19.1	0.5	6.0	4.2	16.3
	4	稍缺Slightly deficient	28.4	14.9	43.7	67.4	13.5	20.0	34.9
	5	缺Deficient	22.8	18.1	22.3	31.6	43.7	29.3	20.0
	6	极缺Extremely deficient	38.6	46.5	7.0	0.5	33.5	46.0	18.6
对照地 Control plots	1	丰Abundant	0.9	0	3.7	0	0.9	0.9	0.9
	2	稍丰Slightly abundant	0.5	2.8	6.5	0	1.4	6.5	5.1
	3	中等Medium	5.1	10.3	26.6	0	2.3	17.3	17.3
	4	稍缺Slightly deficient	21	5.1	43	68.7	12.1	27.6	34.6
	5	缺Deficient	31.3	24.3	17.8	30.8	51.4	22.9	24.8
	6	极缺Extremely deficient	41.1	57.5	2.3	0.5	31.8	24.8	17.3

指标 Index	主成分1 Principal component 1	主成分2 Principal component 2	主成分3 Principal component 3	主成分4 Principal component 4	主成分5 Principal component 5
TN	0.928	0.079	0.122	0.128	?0.056
SOM	0.917	?0.002	0.011	0.099	?0.111
AN	0.848	0.012	?0.002	0.199	?0.090
MWC	0.681	?0.097	?0.195	?0.051	0.135
TP	0.439	?0.027	0.403	?0.301	0.173
SA	0.010	?0.902	?0.072	0.020	0.138
SI	?0.193	0.781	0.023	0.106	?0.204
CL	0.165	0.769	?0.276	0.154	0.184
AP	0.020	?0.191	0.721	?0.109	?0.476
BD	?0.489	0.234	0.491	?0.052	0.161
TK	?0.068	0.008	0.410	0.805	?0.091
pH	?0.329	?0.391	?0.189	0.586	0.139
AK	0.160	0.122	0.479	0.045	0.746
特征值 Eigen values	3.52	2.291	1.491	1.202	1.003
贡献率 Contribution rate （%）	27.079	17.622	11.466	9.244	7.713
累计贡献率Accumulative contribution rate（%）	27.079	44.701	56.167	65.411	73.124

样地类型 Plot type	因子得分 Factor score					土壤肥力指数 Soil fertility index
样地类型 Plot type	因子1 Factor1	因子2 Factor2	因子3 Factor3	因子4 Factor4	因子5 Factor5	土壤肥力指数 Soil fertility index
人工林Artificial forest	0.2361	0.1752	?0.6018	0.0563	?0.0004	0.0310
对照地Control plots	?0.2409	?0.1788	0.6141	?0.0575	0.0004	?0.0316
Wilcoxon 带符号秩检验 Wilcoxon signed-ranks test（P）	0.000**	0.335	0.000**	0.644	0.862	0.282

Influence of the Artificial Afforestation on Soil Nutrients and Fertility in the Mid-Watershed of “One River and Two Tributaries”, Tibet

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