Agronomic Evaluation of Nutrient Management for Potato in Northwest China

Abstract: In northwest China the lack of knowledge on soil nutrient fertility and no appropriate nutrient management practice has restricted potato production. Field trials were conducted from 2002 to 2007 to determine the main limiting nutrients for potato (Solanum tuberosum L) and to evaluate the nutrient management practice (NMP) based on an Agro Services International (ASI) systematic approach. Results indicated average potato yields in nutrient omission plots was in the order 0-N (22.2 t ha^-1) ≈ 0-P (22.4 t ha^-1) <0-K (31.5 t ha^-1). N deficiency is a general feature of irrigated potato in northwest region, whereas P and K supply are equally limiting factors. The mean agronomic efficiency of N (AE_N), P (AE_P) and K (AE_K) was 34.4 kg tuber kg^-1 N, 32.4 kg tuber kg^-1 P₂O₅ and 41.3 kg tuber kg^-1 K₂O, respectively, and the mean partial factor productivity of N (PFP_N), P (PFP_P) and K (PFP_K) was 220 kg tuber kg^-1 N, 291 kg tuber kg^-1 P₂O₅ and 306 kg tuber kg^-1 K₂O, respectively. There was significant negative relationship between AE or PFP of N, P or K and the respective nutrient rate. The positive relationship between yield of nutrient omission plots and PFP and AE suggests nutrient use efficiency can be affected by soil indigenous productivity. NMP based on ASI systematic approach produced significant higher yield, nutrient use efficiency and economic return than farmer practice (FP).

Keywords: Potato, Nutrient management, Agronomic efficiency, Partial factor productivity


1. Introduction
China is now the world's largest potato (Solanum tuberosum L.) producer and the output reached 74 million tons in 2007. The northwest region of China is the main potato production region with a planting area of 1.8 million ha and a total production of 24.4 million tones, accounting for 40.6% and 37.7% of national total, respectively (MOA, 2007).
The climatic conditions in the northwest region, such as cool temperatures, adequate sunlight, and a large differential between day and night temperatures are favorable for potato production. However, imbalances of nutrient application are partially responsible for the low tuber yields and quality of potato in this region where K and/or P has usually been ignored by farmer’s practice. Thus, nutrient management for N, P and K is important in potato production. However, the indigenous soil productivity and yield response to nutrient application were not clear, and appropriate nutrient management practices for potato are not available in northwest China.
Therefore, the objectives of this study were to: (1) determine the main limiting nutrient and nutrient use efficiency in potato production; (2) evaluate the nutrient management practice based on an Agro Services International (ASI) systematic approach.

2. Materials and methods
2.1 Field trials
Field trials were conducted from 2002 to 2007. Each trial has a treatment of nutrient management practice (NMP) and nutrient omission plots: NMP-N, NMP-P or NMP-K. The amount of N, P₂O₅ and K₂O applied in NMP was determined by the ASI systematic approach (Hunter, 1980; Portch and Hunter, 2002). Each trial had three or four replicates. In selected sites farmer practice (FP) was included to compare with NMP. Potato cultivars used in the experiments were round white and oblong yellows including the Chinese selections in the numbered series Kexin (Su and Lai, 2007), Longshu (Wen et al., 2007) and Qingshu (Zhang et al., 2006).

2.2 ASI systematic approach
ASI systematic approach was developed by Hunter (1980) and revised by Portch and Hunter (2002). Soil organic matter was extracted by 0.2 mol L^-1 NaOH-0.01mol L^-1EDTA-2% methanol and determined by spectrophotometry at 420nm. Soil-available P and K was extracted by 0.25mol L^-1 NaHCO₃-0.01mol L^-1 EDTA-0.01mol L^-1 NH₄F solution, and P was determined colorimetrically, K by atomic absorption. Mineral N including NH₄⁺-N and NO₃^--N were extracted by 1 mol L^-1 KCl, and determined by colorimetry and ultraviolet spectrophotometer, respectively. The amount of N, P and K was recommended using fertilizer recommendation program based on organic matter content/mineral N, available P and available K, respectively. Descriptions of soil testing data are summarized in Table 1.

Table 1 Soil texture, soil pH, soil organic matter, and nutrient concentrations of tested soils prior to trials

Soil parameters	N trials (n=28)		P trials (n=34)		K trials (n=66)
	Mean (SD)	CV (%)	Mean (SD)	CV (%)	Mean (SD)	CV (%)
Soil texture	Sandy loam, loam		Sandy loam, loam		Sandy loam, loam
pH in water (1:2.5)	8.3 (0.3)	3	8.2 (0.2)	3	8.2 (0.2)	3
Soil organic matter (g kg-1)	10.0 (4.5)	44	9.0 (5.0)	59	9.0 (5.0)	62
Mineral N (mg L-1)	28.3 (22.9)	81	24.2 (21.8)	90	21.0 (20.2)	96
Available P (mg L-1)	16.3 (7.6)	47	17.7 (7.6)	43	17.0 (6.8)	40
Available K (mg L-1)	94.2 (34.7)	37	97.2 (31.4)	32	94.5 (30.7)	35

2.3 Data analysis
Yield response and nutrient use efficiency including agronomic efficiency (AE) and partial factor productivity (PFP) was calculated. AE represents crop yield increase per unit nutrient applied and it was usually used to evaluate the yield increase derived from applied nutrient. PFP represents crop yield per unit nutrient applied and usually used to estimate the integrated use efficiency of both indigenous and applied nutrient.
Yield response (%) = (Y-Y₀)/Y₀×100
AE = (Y – Y₀)/F
PFP = Y/F
Where Y = tuber yield of NMP (kg ha^-1), Y₀ = tuber yield (kg ha^-1) of nutrient omission plots, F = nutrient applied (kg ha^-1). AE_N, AE_P and AE_K represent agronomic efficiency of N, P and K, and PFP_N, PFP_P and PFP_K represents partial factor productivity of N, P and K, respectively.
Analysis of variance was completed using SAS statistical software. Plots and relationships were made and analyzed using Microsoft Office Excel 2007.

3. Results and discussion
3.1 Indigenous nutrient fertility and nutrient response
Initial soil analysis using the ASI approach indicated large variation in soil fertility characteristics among sites in N trials, P trials and K trials, respectively (Table 1). Seven- to 9-fold ranges of potato yields in nutrient omission plots were found among sites, with an average coefficient of variation (CV) in 53%, 53% and 43%, respectively for N, P and K (Table 2). Average potato yields in nutrient omission plots was in the order 0-N (22.2 t ha^-1) ≈ 0-P (22.4 t ha^-1) <0-K (31.5 t ha^-1). Twenty-four of 28 N trials, twenty of 34 P trials and forty-two of 66 K trials showed significant (P<0.05) yield increase due to N, P and K application, respectively, indicating that N deficiency is a general feature of irrigated potato in northwest region, whereas P and K supply are equally limiting factors on many soils.
The average tuber yield response to N, P and K application was 20.8%, 14.9%, 16.4%, with the CV in 47%, 81%, 68%, respectively (Table 2). N recommended in this research was 45 to 307 kg N ha^-1 with an average of 135 kg N ha^-1. Studies completed in the Columbia Basin of Washington showed optimal N rates for Russet Burbank ranging from 336 to 448 kg ha^-1 (Roberts et al., 1982; Lauer 1986). As for P, the application rate was 30 to 322 kg P₂O₅ ha^-1 with an average of 124 kg P₂O₅ ha^-1 (Table 2). Grewal and Sud (1990) reported that optimum dose of phosphorus for potato was 90 kg P₂O₅ ha^-1 in northern India. Kumar et al. (2007b) indicated that response to P fertilization was significant with total tuber yield and biomass at the rate of 80 kg P₂O₅ ha^-1, beyond that tuber yield did not further increase in west-central Plains of India. Most studies on K nutrition in potato focused on source, time and application method (Chadha et al., 2006; Sasani et al., 2006; Haase et al., 2007; Kumer et al., 2007c).

Table 2 Yield response and nutrient use efficiency indicators of potato grown in nutrient omission plots at various sites

Measurement	Mean	SD	Min.	Max.	CV (%)
Yield in 0-N plot (t ha-1)	22.2	11.8	7.5	54.6	53
Yield in 0-P plot (t ha-1)	22.4	11.9	5.9	55.7	53
Yield in 0-K plot (t ha-1)	31.5	13.7	8.2	56.0	43
Recommended N	135	58	45	307	43
Recommended P2O5	124	83	30	322	67
Recommended K2O	139	68	30	300	49
Yield response to N (%)	20.8	10.0	3.1	44.0	47
Yield response to P (%)	14.9	12.1	-1.0	62.7	81
Yield response to K (%)	16.4	11.1	2.3	57.1	68
AEN (kg kg-1 N)	34.6	19.0	3.4	80.0	56
AEP (kg kg-1 P2O5)	32.4	27.5	-2.4	117.0	85
AEK (kg kg-1 K2O)	42.6	42.0	6.2	233	98
PFPN (kg kg-1 N)	220	122	67	622	55
PFPP (kg kg-1 P2O5)	291	218	50	934	75
PFPK (kg kg-1 K2O)	312	157	39	643	50

3.2 Nutrient use efficiency
The average AE_N, AE_P and AE_K was 34.4 kg tuber kg^-1 N, 32.4 kg tuber kg^-1 P₂O₅ and 41.3 kg tuber kg^-1 K₂O. The average of PFP_N, PFP_P and PFP_K was 220 kg tuber kg^-1 N, 291 kg tuber kg^-1 P₂O₅ and 306 kg tuber kg^-1 K₂O, respectively (Table 2). Many factors such as potato cultivars (Zebarth et al., 2004) and nutrient application rate can affect the variability of AE and PFP. In the current study there was negative correlation between AE or PFP and the amount of nutrient applied (Fig. 1). Other researchers also observed that AE_N or PFP_N decreased with increase dose of applied N (Zvomuya et al. 2002; Love et al. 2005; Kumar et al, 2007a). Curless et al (2004) showed that when 134 kg N rate ha^-1 was applied, AE_N was 46 kg tuber kg^-1 N and PFP_N was 348 kg tuber kg^-1 N, which was higher than those of our experiment in which the mean AE_N was 35 kg tuber kg^-1 N and PFP_N was 220 kg tuber kg^-1 N when almost the same amount of N (135 kg N ha^-1) was applied. In Canada the AE_N and PFP_N could be 117 kg tuber kg^-1 N and 353 kg tuber kg^-1 N at 100 kg ha^-1 of N (Zebarth et al., 2006). For phosphorus, Kumar et al. (2007b) reported that there was a sharp increase in AE_P or PFP_P when the P dose was increased from 0 to 80 kg P₂O₅ ha^-1 and the sharp decline in AE_P was observed when the P dose was further increased from 80 to 120 kg P₂O₅ ha^-1. The indigenous soil productivity can be expressed by the tuber yield in nutrient omission plots. So, the positive relationship between tuber yield of nutrient omission plots and PFP and AE (Fig. 2) suggest that indigenous soil productivity is another factor influencing nutrient use efficiency in addition to nutrient application rate.

3.3 Agronomic evaluation of NMP
Results indicated that NMP showed advantages in yield, economic returns and nutrient use efficiency (Table 3). The tuber yield of NMP plots increased over FP by 4.0% to 22.1%. Nutrient AE under NMP was greater than that of FP at almost all sites and the benefit from NMP was 20 to 500 US$ ha^-1 more than that from FP. Future work should focus on understanding of nutrient cycling in potato system in order to develop the best nutrient management practice.

Table 3 Comparison between best nutrient management practice (NMP) and farmer’s practices (FP)

Location	Year	Treat.	N kg ha-1	P2O5 kg ha-1	K2O kg ha-1	Yield † kg ha-1	Yield increase kg ha-1 %		AEN kg kg-1N	Benefit‡ US$ ha-1
Jishishan, Gansu	2004	NMP	120	120	150	35350 a	6333	21.8	74	1915
		FP	60	30	0	29017 b			43	1680
Zhangjiachuan, Gansu	2006	NMP	104	72	68	29583 a	5347	22.1	55	3479
		FP	104	0	0	24236 b			22	2978
Wuchuan, IMAR	2006	NMP	125	125	100	14200 a	900	6.8	33	728
		FP	60	18	0	13300 a			40	708
Wuchuan, IMAR	2006	NMP	250	225	200	31500 a	1900	6.4	24	1666
		FP	141	51	0	29600 b			23	1491
Huzhu, Qinghai	2007	NMP	158	75	135	17893 a	696	4.0	3	997
		FP	240	52	90	17197 a			0	944
Xining, Qinghai	2007	NMP	158	75	135	30893 a	3393	12.3	35	1865
		FP	240	52	90	27500 b			9	1631
Huaxian, Shaanxi	2007	NMP	181	322	225	47916 a	2083	4.5	33	2823
		FP	194	504	225	45833 b			20	2583
Mizhi, Shaanxi	2007	NMP	307	322	225	26527 a	4027	17.9	17	1331
		FP	358	0	0	22500 b			15	1312

^†: Means in the same location followed by the same letter are not significantly different at P<0.05.
^‡: Subtract the total cost of N, P, and K fertilizer from the total production value of potato tubers.


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