Sustainability of Wood Productivity of <i>Pinus Taeda</i>Based on Nutrient Export and Stocks in the Biomass and in the Soil

Sixel, Ricardo Michael de Melo; Arthur Junior, José Carlos; Gonçalves, José Leonardo de Moraes; Alvares, Clayton Alcarde; Andrade, Gabriel Ramatis Pugliese; Azevedo, Antonio Carlos; Stahl, James; Moreira, Antônio Maurício

doi:10.1590/01000683rbcs20140297

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SECTION 3 - SOIL USE AND MANAGEMENT • Rev. Bras. Ciênc. Solo 39 (5) • Sep-Oct 2015 • https://doi.org/10.1590/01000683rbcs20140297 copy

Sustainability of Wood Productivity of Pinus TaedaBased on Nutrient Export and Stocks in the Biomass and in the Soil

Sustentabilidade da Produtividade de Madeira de Pinus Taeda com Base na Exportação e no Estoque de Nutrientes na Biomassa e no Solo

Authorship SCIMAGO INSTITUTIONS RANKINGS

ABSTRACT

The impact of intensive management practices on the sustainability of forest production depends on maintenance of soil fertility. The contribution of forest residues and nutrient cycling in this process is critical. A 16-year-old stand of Pinus taeda in a Cambissolo Húmico Alumínico léptico (Humic Endo-lithic Dystrudept) in the south of Brazil was studied. A total of 10 trees were sampled distributed in five diameter classes according to diameter at breast height. The biomass of the needles, twigs, bark, wood, and roots was measured for each tree. In addition to plant biomass, accumulated plant litter was sampled, and soil samples were taken at three increments based on sampling depth: 0.00-0.20, 0.20-0.40, 0.40-0.60, 0.60-1.00, 1.00-1.40, 1.40-1.80, and 1.80-1.90 m. The quantity and concentration of nutrients, as well as mineralogical characteristics, were determined for each soil sample. Three scenarios of harvesting intensities were simulated: wood removal (A), wood and bark removal (B), and wood + bark + canopy removal (C). The sum of all biomass components was 313 Mg ha^-1.The stocks of nutrients in the trees decreased in the order N>Ca>K>S>Mg>P. The mineralogy of the Cambissolo Húmico Alumínico léptico showed the predominance of quartz sand and small traces of vermiculite in the silt fraction. Clay is the main fraction that contributes to soil weathering, due to the transformation of illite-vermiculite, releasing K. The depletion of nutrients from the soil biomass was in the order: P>S>N>K>Mg>Ca. Phosphorus and S were the most limiting in scenario A due to their low stock in the soil. In scenario B, the number of forest rotations was limited by N, K, and S. Scenario C showed the greatest reduction in productivity, allowing only two rotations before P limitation. It is therefore apparent that there may be a difference of up to 30 years in the capacity of the soil to support a scenario such as A, with a low nutrient removal, compared to scenario C, with a high nutrient removal. Hence, the effect of different harvesting intensities on nutrient availability may jeopardize the sustainability of P. taeda in the short-term.

soil fertility; nutrient cycling; forest management

Tree size⁽¹⁾	Height	DBH⁽²⁾	Volume

			Wood	Bark
	m	cm	m³/tree

x - 2s	16.3	13.1	0.080	0.020
x - 1s	16.5	15.8	0.109	0.026
x - 1s	18.1	17.1	0.129	0.026
x -	18.1	21.9	0.248	0.072
x -	20.4	22.6	0.326	0.073
x -	23.0	23.1	0.378	0.078
x -	20.2	23.2	0.291	0.072
x - + 1s	22.9	28.6	0.589	0.100
x - + 1s	21.8	29.4	0.502	0.120
x - + 2s	23.5	33.7	0.827	0.175
x -	20.1	22.9	0.348	0.076
s	2.7	6.5	0.202	0.012
CV (%)⁽³⁾	13.5	28.3	67.902	62.810

Component	Equation	R²	Sxy	p	n
Needle	ŷ = -4.08^* + 203.80^*x	0.87	1.97	<0.0001	10
Live branche	ŷ = -4.56^* + 266.29^*x	0.91	2.10	<0.0001	10
Dead branche	ŷ = -10.4^ns + 576.12^*x	0.90	7.57	<0.0873	9
Bark	ŷ = -1.23^* + 398.59^nsx	0.98	2.30	<0.0001	10
Wood	ŷ = -17.48^ns + 3699.11^*x	0.97	1.97	<0.0001	10
Root	ŷ = -0.22^ns + 811.34^*x	0.93	5.59	<0.0001	10
Volume with bark	ŷ = -0.02^* + 11.75^*x	0.98	0.05	<0.0001	10
Volume without bark	ŷ = -0.08^* + 9.77^*x	0.97	0.05	<0.0001	10

Depth	N	P	K	Ca	Mg	S
m	kg ha^-1

0.00-0.20⁽¹⁾	351.0⁽²⁾	7.3	61.8	89.6	43.4	36.3
0.20-0.40	315.0	5.6	41.2	96.4	40.8	29.7
0.40-0.60	173.0	4.9	36.0	93.6	38.9	38.1
0.60-1.00	134.8	8.0	82.4	182.4	78.7	56.7
1.00-1.40	90.6	4.9	195.6	190.4	75.4	17.6
1.40-1.80	54.8	7.2	308.9	181.6	81.6	14.0
1.80-1.90	18.7	1.1	66.9	45.2	19.1	3.6
Sum	1,138.0	39.1	792.8	879.2	377.9	196.1

Component	Biomass	N	P	K	Ca	Mg	S
	Mg ha^-1	kg ha^-1

Needle	7	116	7	27	15	4	6
Live branche	11	39	2	11	25	3	2
Dead branche	22	70	1	3	16	8	8
Bark	24	72	3	16	21	5	10
Wood	195	210	33	85	91	31	65
Root⁽¹⁾	54	365	10	54	130	30	49
Litterfall	28	300	12	9	27	9	31
Total	341	1,172	68	205	324	90	172

Component	N	P	K	Ca	Mg	S
	kg ha^-1

Initial nutrient stock in the soil (S; 0.00-1.90 m)⁽¹⁾	1,138	39	792	879	377	196
Nutrient stock in biomass (Su)
Needles	116	7	27	15	4	6
Branches (dead and live)	109	3	14	41	11	11
Wood	210	33	85	91	31	65
Bark	72	3	16	21	5	10
Litter	300	12	9	27	9	31
Roots	365	10	54	130	30	49
Sum	1,172	68	205	324	90	172
Nutrient output
By removing wood (W)	210	33	85	91	31	65
By removing bark and wood (B)	282	36	101	112	36	75
By removing wood, bark, needles, and branches (AT)	507	46	142	167	51	92
Nutrient input by rainfall (R)	47	3	55	115	25	0
	Nutrient budget⁽²⁾
Scenario A: (S + Su) - (W) + (R)	2,026	69	742	996	364	263
Scenario B: (S + Su) - (W + B) + (R)	1,954	65	726	975	359	252
Scenario C: (S + Su) - (AT) + (R)	1,729	55	684	919	344	235
Potential number of sixteen-year rotations
Scenario A	>8	3	6	>8	6	4
Scenario B	>8	3	5	>8	5	3
Scenario C	7	2	3	5	3	3

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[1] * Corresponding author. E-mail: sixelr@gmail.com