氮沉降和降水增加对榆树幼苗不同器官碳氮磷分配格局的影响

doi:10.11707/j.1001-7488.20200318

摘要/Abstract

摘要：

目的: 研究榆树幼苗C、N、P分配格局对氮沉降和降水增加的响应特征，为明确榆树对水氮环境变化的适应策略、培育高质量苗木提供参考。方法: 2015年4月末，将榆树幼苗(株高37.76 cm，茎粗0.44 cm)盆栽于风沙土(全C、N、P含量分别为4.52、0.31和0.11 g·kg^-1)中。采用两因素(氮素和水分)随机区组设计，设置4个施氮处理梯度(施不施氮及添加5、10和15 g N·m^-2a^-1)以及3个水分处理水平(自然降水、自然降水增加50%和增加100%)，分析不同水氮处理下榆树幼苗叶、枝、茎、粗根和细根的C、N、P含量及计量比变化特征，探讨C、N、P元素含量的稳定性及其异速生长关系。结果: 施氮和增加降水对榆树幼苗不同器官N、P含量及比值均具有显著交互作用。随着施氮量增加，叶和细根C含量增加，枝、茎和粗根C含量保持稳定；各器官N含量及N：P升高，C：N降低；叶和茎P含量降低，叶、茎和细根C：P增加。随着降水增加，叶和细根C含量下降，枝、茎和粗根C含量保持稳定；枝和茎P含量下降，C：P和N：P上升。而在不同氮沉降水平下，降水增加对各元素分配影响不同。当不施氮时，随着降水增加，叶N含量及N：P增加，C：N下降；叶、粗根和细根P含量先增加后减少，C：P先降低后升高；细根N：P先增加后降低。当施氮量为15 g N·m^-2a^-1时，随着降水增加，叶N含量下降，C：N增加，N：P无显著变化；叶、粗根和细根P含量下降，C：P增加；细根N：P逐渐增加。水氮添加处理下，幼苗C含量顺序为茎、枝和粗根>叶和细根，N和P含量顺序为叶>细根>枝、茎和粗根。各器官元素含量及比值的变异系数不同，C含量变异系数为叶和细根>枝、茎和粗根；N含量变异系数在叶和粗根中最大，在细根中最小；P含量变异系数在茎中最大，在叶中最小；C：N变异系数为粗根>叶、枝和茎>细根，C：P和N：P变异系数为茎>粗根和细根>叶和枝；且各器官N：P变异系数均高于N、P含量变异系数。幼苗叶、枝、粗根和细根中C与N含量具有显著异速生长关系，C与P含量在叶和粗根中呈显著负相关。各器官N与P含量间均呈显著负相关，异速生长指数在-0.534~-1.224之间。结论: 氮沉降可提高榆树幼苗叶和细根C含量、各器官N含量及N：P、叶、茎和细根C：P，降低叶和茎P含量、各器官C：N。降水增加可提高枝和茎C：P和N：P，降低叶和细根C含量、枝和茎P含量，同时N利用效率降低，P利用效率提高。N含量稳定性在细根中最强，P含量和N：P稳定性在叶中最强，N和P含量稳定性在各器官中均高于N：P。

关键词: 水氮交互, 异速生长关系, 化学计量, 养分限制, C:N:P

Abstract:

Objective: To provide theoretical guidance for construction of Ulmus pumila shelterbelt, the adaptive mechanisms of C, N, P allocation of U. pumila seedlings in response to nitrogen deposition and increasing precipitation were studied. Method: A full factorial experimental design of two factors (nitrogen and water), was applied, i.e., four N fertilization levels (0, 5, 10 and 15 g N·m^-2a^-1) and three water treatments (natural precipitation, natural precipitation increased by 50% and 100%) with randomized block design. The C, N, and P contents in leaf, branch, stem, coarse root and fine root of U. pumila seedlings under the different water and nitrogen treatments were measured and their ratios were calculated, and the stability of C, N, and P and their relationships with allometric growth were explored. Result: There were significant interactions between nitrogen addition and increasing precipitation on N content, P content and their ratios in different organs of U. pumila seedlings. With the increase of N addition, C content increased in leaf and fine root, while it was unchanged in branch, stem and coarse root. Meanwhile, N content and N:P ratio increased in all organs, whereas C:N ratio decreased. P content declined in leaf and stem while C:P ratio elevated in leaf, stem and fine root. With the increasing of precipitation, C content reduced in leaf and fine root, while it remained unchanged in branch, stem and coarse root, and P content decreased and C:P and N:P ratios increased in branch and stem. The effects of precipitation increase on the element allocation were various under different nitrogen deposition levels. With the increasing of precipitation, under no N addition condition, N content and N:P ratio in leaf increased whereas C:N ratio decreased, and P content firstly increased and then decreased in leaf, coarse root and fine root whereas C:P firstly reduced and then elevated. Meanwhile, N:P ratio firstly increased and then declined in fine root. However, under 15 g N·m^-2a^-1 nitrogen addition condition, N content decreased, C:N ratio increased and N:P ratio remained unchanged in leaf, while P content declined and C:P ratio enhanced in leaf, coarse root and fine root, N:P ratio gradually elevated in fine root with the increasing of precipitation. C content of different organs followed the following order:stem > coarse root > leaf and fine root, while N and P content followed the order:leaf > fine root > branch, stem, and coarse root. Meanwhile, the coefficient of variation for C content followed the order:branch, stem, and coarse root < leaf and fine root. The variation coefficient of N content was the largest in leaf and coarse root, and the smallest in fine root. The variation coefficient of P content was the largest in stem and the smallest in leaf. The variation coefficient for C:N ratio followed the order:coarse root > leaf, branch, and stem > fine root, whereas the variation coefficients for C:P and N:P ratios followed the order:stem > coarse root > fine root > leaf and branch. The variation coefficient for N:P ratio was greater than those for N and P content. There were significant allometric growth relationships with C and N content in leaf, branch, coarse root and fine root of U. pumila seedlings. C content was negatively related to P content in leaf and coarse root. Furthermore, N content was negatively related to P content in each organ, and the index of allometric growth ranged from -0.534 to -1.224. Conclusion: With the increasing nitrogen deposition and precipitation, N limitation for the growth of U. pumila seedlings changed into N and P joint limitation. Meanwhile, N use efficiency decreased, but P use efficiency enhanced. The stability of N content was the strongest in fine root, while P content and N:P ratio stability were the strongest in leaf. The stability of N and P content were stronger than that of N:P ratio in each organ.

Key words: water and nitrogen coupling, allometric growth relationships, stoichiometry, nutrient limitation, C:N:P

中图分类号:

S718.43

王凯,张大鹏,宋立宁,吕林有,刘建华. 氮沉降和降水增加对榆树幼苗不同器官碳氮磷分配格局的影响[J]. 林业科学, 2020, 56(3): 172-183.

Kai Wang,Dapeng Zhang,Lining Song,Linyou Lü,Jianhua Liu. Effects of Increasing Nitrogen Deposition and Precipitation on Carbon, Nitrogen, and Phosphorus Allocation in Different Organs of Ulmus pumila Seedlings[J]. Scientia Silvae Sinicae, 2020, 56(3): 172-183.

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	C	N	P	C:N	C:P	N:P
N	146.97^**	427.72^**	326.65^**	190.43^**	443.22^**	3 044.98^**
W	21.86^**	67.13^**	596.49^**	125.36^**	779.31^**	1 483.32^**
O	312.06^**	2 291.80^**	456.88^**	1 342.31^**	655.44^**	1 832.96^**
N×W	0.81	19.18^**	16.34^**	12.65^**	17.73^**	33.26^**
N×O	16.97^**	42.98^**	11.49^**	29.52^**	9.39^**	82.11^**
W×O	9.39^**	4.10^**	36.42^**	11.99^**	127.62^**	207.23^**
N×W×O	1.86^*	6.05^**	10.39^**	3.09^**	6.22^**	31.81^**

元素 Element	器官 Organ	最小值 Min./(g·kg^-1)	最大值 Max./(g·kg^-1)	平均数 Mean/(g·kg^-1)	标准差 Standard deviation/(g·kg^-1)	变异系数 Coefficient of variation(%)
C	叶Leaf	460.24	554.20	518.29c	29.02	5.60
	枝Branch	542.73	575.46	560.98ab	10.96	1.95
	茎Stem	555.38	577.34	565.76a	6.88	1.22
	粗根Coarse root	529.70	557.22	545.69b	8.22	1.51
	细根Fine root	468.38	555.92	510.77c	25.91	5.07
N	叶Leaf	10.11	19.57	13.88a	3.12	22.50
	枝Branch	5.18	8.16	6.58c	1.14	17.26
	茎Stem	3.53	6.70	4.73d	0.94	19.96
	粗根Coarse root	3.38	6.75	5.17cd	1.20	23.14
	细根Fine root	8.00	11.99	9.73b	1.44	14.78
P	叶Leaf	1.17	1.80	1.43a	0.21	14.44
	枝Branch	0.75	1.33	1.00c	0.18	18.18
	茎Stem	0.51	1.29	0.93c	0.26	28.23
	粗根Coarse root	0.69	1.48	1.09bc	0.25	23.15
	细根Fine root	0.80	1.64	1.23b	0.27	21.67
C:N	叶Leaf	28.32	49.84	38.88d	7.32	18.83
	枝Branch	69.22	108.80	88.13b	14.51	16.46
	茎Stem	85.25	163.18	124.79a	23.46	18.80
	粗根Coarse root	81.60	159.43	111.95a	26.79	23.93
	细根Fine root	43.70	61.51	53.49c	6.10	11.40
C:P	叶Leaf	268.26	458.00	372.97d	68.21	18.29
	枝Branch	409.45	775.77	582.76ab	107.52	18.45
	茎Stem	430.54	1116.06	669.39a	221.78	33.13
	粗根Coarse root	369.64	816.96	531.78bc	137.40	25.84
	细根Fine root	308.82	659.98	439.58cd	112.26	25.54
N:P	叶Leaf	5.67	14.63	10.11a	3.27	32.37
	枝Branch	3.90	10.24	6.93bc	2.18	31.48
	茎Stem	2.94	13.10	5.83c	3.02	51.82
	粗根Coarse root	2.69	9.57	5.12c	2.08	40.66
	细根Fine root	5.24	13.94	8.51ab	3.08	36.22

log Y vs. log X	器官Organs	b	95%CI	n	R²	P
log N vs. log C	叶Leaf	2.612	[0.575, 4.648]	12	0.449	0.017^*
	枝Branch	5.420	[0.424, 10.416]	12	0.369	0.036^*
	茎Stem	1.411	[-0.972, 12.565]	12	0.008	0.784
	粗根Coarse root	10.303	[1.738, 18.868]	12	0.418	0.023^*
	细根Fine root	1.916	[0.433, 3.400]	12	0.453	0.016^*
log P vs. log C	叶Leaf	-1.692	[-3.004, -0.379]	12	0.452	0.017^*
	枝Branch	-2.482	[-8.707, 3.743]	12	0.073	0.395
	茎Stem	4.788	[-12.899, 22.475]	12	0.035	0.560
	粗根Coarse root	-9.369	[-18.346, -0.393]	12	0.351	0.042^*
	细根Fine root	-1.528	[-4.439, 1.383]	12	0.120	0.269
log P vs. log N	叶Leaf	-0.534	[-0.790, -0.278]	12	0.683	0.001^**
	枝Branch	-0.712	[-1.235, -0.189]	12	0.479	0.013^*
	茎Stem	-1.224	[-1.959, -0.488]	12	0.579	0.004^**
	粗根Coarse root	-0.581	[-1.148, -0.014]	12	0.343	0.045^*
	细根Fine root	-1.217	[-1.890, -0.544]	12	0.619	0.002^**

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