氮磷钾运筹模式对北疆滴灌棉花生长发育和产量的影响

doi:10.3864/j.issn.0578-1752.2021.16.010

中国农业科学 ›› 2021, Vol. 54 ›› Issue (16): 3473-3487.doi: 10.3864/j.issn.0578-1752.2021.16.010

• 土壤肥料·节水灌溉·农业生态环境 • 上一篇下一篇

氮磷钾运筹模式对北疆滴灌棉花生长发育和产量的影响

文明^1,²(),李明华^1,²,蒋家乐¹,马学花¹,李容望¹,赵文青³,崔静^1,²,刘扬^1,²(),马富裕^1,²()

¹石河子大学农学院/新疆兵团绿洲生态农业重点实验室,新疆石河子 832003
²现代农业生产信息化管理与应用技术国家地方联合工程研究中心（新疆兵团）,新疆石河子 8320003
³南京农业大学农学院,南京 210095

收稿日期:2020-09-25 接受日期:2020-11-25 出版日期:2021-08-16 发布日期:2021-08-24
通讯作者: 刘扬,马富裕
作者简介:文明,E-mail： wmalaer@qq.com。
基金资助:
国家重点研发计划(2017YFD0201900);国家自然科学基金-地区基金(31860346);兵团财政科技计划(2020AB017);石河子大学高层次人才科研启动项目(RCSX2018B09);石河子大学新疆生产建设兵团绿洲生态重点实验室开放课题发展基金(201802)

Effects of Nitrogen, Phosphorus and Potassium on Drip-Irrigated Cotton Growth and Yield in Northern Xinjiang

WEN Ming^1,²(),LI MingHua^1,²,JIANG JiaLe¹,MA XueHua¹,LI RongWang¹,ZHAO WenQing³,CUI Jing^1,²,LIU Yang^1,²(),MA FuYu^1,²()

¹School of Agriculture, Shihezi University/The Key Laboratory of Oasis Eco-Agriculture, Xinjiang Production and Construction Corps, Shihezi 832003, Xinjiang
²National & Local Joint Engineering Research Center of Information Management and Application Technology for Modern Agricultural Production ( XPCC), Shihezi 832003, Xinjiang
³College of Agronomy, Nanjing Agricultural University, Nanjing 210095

Received:2020-09-25 Accepted:2020-11-25 Online:2021-08-16 Published:2021-08-24
Contact: Yang LIU,FuYu MA

摘要/Abstract

摘要：

【目的】明确北疆滴灌棉花干物质积累及产量形成对氮磷钾综合运筹的响应特征,为节省氮肥成本提供依据。【方法】以鲁棉研24号为材料,在4种施氮量（506、402.5、299和195.5 kg·hm^-2,分别用N1、N2、N3和N4表示）和蕾期、花铃期4种不同磷钾肥运筹方式（100%+0,25%+75%,50%+50%和75%+25%,分别用PK-M1,PK-M2,PK-M3和PK-M4表示）下进行田间试验。试验期间测定棉花叶面积指数（LAI）、干物质积累、蕾花铃数量及产量等指标。【结果】在相同磷钾运筹方式下,随着施氮量的降低,LAI的Logistic模型K’值表现为先上升后下降趋势,N3比N2处理高5.1%—16.5%,快速增长起始期（t₁）和快速增长结束期（t₂）均为N3处理最晚,且N3处理快速增长期持续时间最长,N3处理比N2处理多2—12 d;N3处理生长特征值GT最高,N2处理次之,N3比N2处理高5.2%—16.7%;干物质积累量在生长前期表现为N1>N2>N3>N4处理,在生长后期表现为N2>N1>N3>N4处理;蕾花铃数在全生育期表现为N2>N3>N1>N4处理;产量相对值在各施氮处理下表现为N2处理最高,N3处理次之,N2处理比N3处理高3.6%—6.5%。在相同施氮量下,LAI的Logistic模型K’值最高为PK-M3处理,最低为PK-M1处理,PK-M3处理比PK-M1处理高20.5%—27.4%;快速增长起始期t₁(2019年除外)和快速增长结束期t₂均为PK-M3最晚,且PK-M3处理快速增长期持续时间（T）最长;PK-M3处理生长特征值（GT）最高,PK-M2处理次之,PK-M3处理比PK-M2处理高13.0%—24.5%;干物质积累量在生长前期表现为PK-M2处理>PK-M3处理>PK-M4处理>PK-M1处理,生长后期表现为PK-M3>PK-M2>PK-M4>PK-M1处理;蕾花铃数在生长前期表现PK-M4>PK-M3>PK-M>PK-M2处理,生长后期表现为PK-M3>PK-M2>PK-M4>PK-M1处理;产量相对值表现为PK-M3处理最高,比其他磷钾处理高5.2%—18.2%。所有处理中,N3PK-M3处理下LAI Logistic模型K’值和GT值最大,T最长,在吐絮期干物质积累量、相对产量值和后期蕾花铃数仅次于N2PK-M3处理,生殖器官干物质分配比例高于其他处理。相关分析表明,LAI在2018年播种后109 d以后和2019年播种后120 d以后与生殖器官干物质、干物质总量和相对产量呈极显著正相关,全生育期生殖器官个数、总干物质积累量、生殖器官干物质与相对产量均为显著或极显著正相关。所有处理中N2PK-M3产量最高,N3PK-M3处理次之,N3PK-M3相对产量仅比N2PK-M3处理降低1.5%。【结论】N3PK-M3处理与农户常规施氮量相比,减少25%的氮肥施用量仍能获得较高产量,可能是由于推迟了棉花后期LAI到达峰值的时期,延缓了LAI下降速率,提高棉花群体干物质生产能力,并促使其向生殖器官转运,且降低蕾铃脱落,保证后期铃数,为产量的形成提供物质基础。因此,本研究认为在蕾期和花铃期各分施50%磷钾肥的条件下,氮肥的施用量可以降低至299 kg·hm^-2,这比农户常规施氮降低25%,以达到减氮稳产、节本增效的目的。

关键词: 棉花, 减量施氮, 磷钾运筹, 产量, 叶面积指数, 滴灌, 北疆

Abstract:

【Objective】The aim of this study was to clarify the response of reduced nitrogen (N) application with different phosphorus (P) and potassium (K) managements (PK-M) on drip-irrigated cotton growth, dry matter accumulation and yield formation in Northern Xinjiang, so as to provide a theroe base for reduced N application with cost saving. 【Method】Field experiments were conducted by using Lumianyan 24 under four N application rates (506, 402.5, 299 and 195.5 kg·hm^-2 designated as N1, N2, N3 and N4, respectively), and four different PK-Ms during squaring stage and bloom-bolling stage (100%+0, 25%+75%, 50%+50% and 75%+25% designated as PK-M1, PK-M2, PK-M3 and PK-M4, respectively). The leaf area index (LAI), dry matter accumulation and distribution, reproductive organs dynamic changes and yield were assayed during experiment period. 【Result】Under the same PK-M treatment, the K’ value of LAI’s Logistic model showed a trend of first increasing and then decreasing with the decrease of nitrogen application rate; the K’ value under N3 was 5.1%-16.5% higher than that under N2, and which in the fast accumulation period in initiated (t₁) and terminated (t₂) days were the latest under N3; which in the duration of fast accumulation period (T) was the longest, and N3 was 2-12 days longer than N2. The growth characteristic value (GT) under N3 was the highest, followed by N2, and N3 was 5.2%-16.7% higher than that under N2. The dry matter accumulation in the early growth period was N1>N2>N3>N4 treatment, and in the late period was N2>N1>N3>N4 treatment. The number of reproductive organs was N2>N3>N1>N4 treatment during the growth period. The relative yield value under N2 was the highest, followed by N3 treatment, which under N2 was 3.6%-6.5% higher than that under N3. Under the same N application rate, the K’ value of LAI logistic model under PK-M3 was the highest and PK-M1 was the lowest, and PK-M3 was 20.5%-27.4% higher than PK-M1; the fast accumulation period in initiated (t1) (except in 2019) and terminated (t₂) days were both the latest under PK-M3. The growth characteristic value (GT) under PK-M3 was the highest, followed by PK-M2, and PK-M3 was 13.0-24.5% higher than PK-M2. The dry matter accumulation in the growth period was PK-M2>PK-M3>PK-M4>PK-M1 treatment, and it was PK-M3>PK-M2>PK-M4>PK-M1 treatment in the late growth period; the number of squares and bolls in the early growth period was PK-M4>PK-M3>PK-M1>PK-M2 treatment, while it was PK-M3>PK-M2>PK-M4>PK-M1 treatment in the late growth period; the relative yield value was the highest in PK-M3, which was 5.2%-18.2% higher than PK-Ms. Among all the treatments, the K’ value and GT value of the LAI Logistic model under N3PK-M3 was the largest, and T was the longest. The plant dry matter, relative yield value and the number of squares and bolls in the late period were second only to N2PK-M3, and the reproductive organs dry distribution ratio was higher than other treatments. Correlation analysis showed that LAI had a significant positive correlation with reproductive organ dry matter, plant dry matter and relative yield value at the late growth period, however, the number of reproductive organs, plant dry matter and reproductive organs were significant positive correlation with relative yield throughout the growth period. Among all treatments, the yield under N2PK-M3was the highest, followed by N3PK-M3, and the relative yield value in N3PK-M3 treatment was 1.5% lower than N2PK-M3 without significant difference. 【Conclusion】The N3PK-M3 could obtain higher yield by reducing 25% N application compared with the conventional N application rate of farmers, which might due to delaying the peak of LAI at the later growth period, delaying the decline rate of LAI, increasing the dry matter production capacity of cotton population, improving cotton production capacity of dry matter, promoting assimilates transfer to reproductive organs, and reducing the shedding of squares and bolls, which provided the material basis for the formation of cotton yield.

Key words: cotton, reduced application of nitrogen, operation of phosphorus and potassium, yield, leaf area index (LAI), drip-irrigation, Northern Xinjiang

文明, 李明华, 蒋家乐, 马学花, 李容望, 赵文青, 崔静, 刘扬, 马富裕. 氮磷钾运筹模式对北疆滴灌棉花生长发育和产量的影响[J]. 中国农业科学, 2021, 54(16): 3473-3487.

WEN Ming, LI MingHua, JIANG JiaLe, MA XueHua, LI RongWang, ZHAO WenQing, CUI Jing, LIU Yang, MA FuYu. Effects of Nitrogen, Phosphorus and Potassium on Drip-Irrigated Cotton Growth and Yield in Northern Xinjiang[J]. Scientia Agricultura Sinica, 2021, 54(16): 3473-3487.

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链接本文: https://www.chinaagrisci.com/CN/10.3864/j.issn.0578-1752.2021.16.010

https://www.chinaagrisci.com/CN/Y2021/V54/I16/3473

图/表 9

表1

表2

图1

图2

图3

表3

氮磷钾综合运筹模式对不同时期生殖器官变化的影响（2018）"

氮素处理 N treatment	磷钾处理 PK treatment	播种后58 d 58 days after sowing	播种后78 d 78 days after sowing			播种后99 d 99 days after sowing			播种后109 d 109 days after sowing
氮素处理 N treatment	磷钾处理 PK treatment	蕾数Square (×10³·hm^-2)	蕾数Square (×10³·hm^-2)	花数Bloom (×10³·hm^-2)	铃数Boll (×10³·hm^-2)	蕾数Square (×10³·hm^-2)	花数Bloom (×10³·hm^-2)	铃数Boll (×10³·hm^-2)	蕾数Square (×10³·hm^-2)	花数Bloom (×10³·hm^-2)	铃数Boll (×10³·hm^-2)
N1	PK-M1	807.79bcd	1352.58bcde	272.95efgh	383.45cd	117.14hi	44.20abc	1429.93cd	113.82fgh	-	1137.10bc
	PK-M2	592.31e	1319.43cde	219.90gh	334.83fg	218.80ef	118.24ab	1605.64bcd	213.27d	7.74a	1285.17ab
	PK-M3	858.62abc	1406.73bcd	356.93cdef	398.92bcd	281.79cd	36.47bc	1769.19bc	274.05c	7.74a	1326.06ab
	PK-M4	876.30abc	1474.14abc	404.45bcd	419.92abc	135.92ghi	51.94abc	1548.18bcd	131.50efg	-	1228.82bc
N2	PK-M1	868.57abc	1467.51abcd	358.04cdef	397.82bcd	159.13gh	88.40abc	1540.44bcd	154.71ef	14.37a	1194.56bc
	PK-M2	797.85bcd	1418.88bcd	296.15defgh	348.09ef	394.50b	74.04abc	1858.69ab	383.45b	14.37a	1389.05ab
	PK-M3	908.35ab	1490.71abc	423.23bc	418.81abc	561.37a	51.94abc	2091.86a	544.79a	14.37a	1553.70a
	PK-M4	949.24a	1617.79a	614.41a	436.49a	235.38de	132.61a	1636.58bcd	228.75d	22.10a	1312.80ab
N3	PK-M1	836.52abcd	1419.99bcd	311.62defg	391.19bcd	132.61ghi	66.30abc	1499.55bcd	129.29efg	7.74a	1183.51bc
	PK-M2	740.38d	1383.52bcde	257.48fgh	342.57efg	236.48de	22.10c	1650.94bcd	229.85d	14.37a	1297.33ab
	PK-M3	877.41abc	1433.25abcd	392.29bcd	404.45abcd	302.78c	96.14abc	1859.80ab	293.94c	-	1417.78ab
	PK-M4	900.62ab	1519.44ab	478.49b	424.34ab	159.13gh	80.67abc	1580.22bcd	154.71ef	14.37a	1264.18b
N4	PK-M1	761.38cd	1274.12de	265.21fgh	373.51de	64.09j	66.30abc	1289.59d	62.99i	14.37a	972.44c
	PK-M2	438.70f	1196.77e	190.07h	309.41g	104.98ij	58.57abc	1565.86bcd	101.66ghj	-	1258.65bc
	PK-M3	804.48bcd	1313.90cde	296.15defgh	392.29bcd	174.60fg	88.40abc	1720.56bc	169.07e	7.74a	1305.06ab
	PK-M4	832.10bcd	1362.53bcde	379.03bcde	414.39abc	83.98ij	58.57abc	1524.97bcd	81.77hi	7.74a	1173.56bc
N		18.00**	9.80**	13.72**	4.52**	137.90**	0.68	3.63*	169.52**	1.20	3.43*
PK-M		40.27**	5.75**	35.04**	48.36**	135.14**	0.28	9.45**	166.13**	0.09	7.72**
N×PK-M		2.79**	0.11	0.97	0.19	12.84**	1.78	0.27	15.78**	0.02	0.27

表3

表4

氮磷钾综合运筹模式对不同时期生殖器官变化的影响（2019）"

氮素处理 N treatment	磷钾处理 PK treatment	播种后65 d 65 days after sowing	播种后88 d 88 days after sowing			播种后107 d 107 days after sowing			播种后120 d 120 days after sowing
氮素处理 N treatment	磷钾处理 PK treatment	蕾数Square (×10³·hm^-2)	蕾数Square (×10³·hm^-2)	花数Bloom (×10³·hm^-2)	铃数Boll (×10³·hm^-2)	蕾数Square (×10³·hm^-2)	花数Bloom (×10³·hm^-2)	铃数Boll (×10³·hm^-2)	蕾数Square (×10³·hm^-2)	花数Bloom (×10³·hm^-2)	铃数Boll (×10³·hm^-2)
N1	PK-M1	1261.98defg	3251.26bcd	150.55fgh	231.36ef	150.55f	68.63ij	1505.52de	22.14a	58.67ab	1432.46cd
	PK-M2	1151.28fg	2967.87cd	344.28ij	106.27h	344.28cd	224.72efg	1750.17abcd	-	-	1608.47bcd
	PK-M3	1436.89bcdef	3450.52abcd	410.70defgh	273.43de	410.70bc	357.56cd	1927.29abc	-	14.39b	1772.31abc
	PK-M4	1596.29abc	3722.84abc	238.01bcd	349.81bc	238.01ef	159.41fghij	1626.18bcde	14.39a	58.67ab	1550.91bcd
N2	PK-M1	1413.64bcdef	3497.01abcd	231.36cde	292.25cde	231.36ef	174.91efghi	1588.55cde	7.75a	22.14ab	1543.16bcd
	PK-M2	1273.05cdefg	3359.75abcd	448.34defgh	251.29ef	448.34b	448.34bc	1808.84abcd	74.17a	44.28ab	1861.97ab
	PK-M3	1566.41abcd	3688.52abc	599.99bc	326.57bcd	599.99a	607.74a	2090.02a	-	-	2095.55a
	PK-M4	1856.44a	4057.16a	273.43a	432.84a	273.43de	273.43de	1710.32bcde	-	14.39	1639.47bcd
N3	PK-M1	1341.68cdefg	3321.00abcd	195.94defgh	254.61ef	195.94ef	106.27hij	1535.41de	-	96.31a	1502.20bcd
	PK-M2	1197.77efg	3170.45bcd	378.59hij	193.73fg	378.59bc	281.18de	1771.20abcd	7.75a	-	1653.86bcd
	PK-M3	1509.95bcde	3582.25abc	468.26cdef	296.68cde	468.26b	501.47b	1966.03ab	7.75a	66.42ab	1863.08ab
	PK-M4	1699.25ab	3929.85ab	245.75b	371.95ab	245.75ef	182.66efgh	1670.46bcde	88.56a	14.39b	1583.01bcd
N4	PK-M1	1216.59efg	3073.03cd	47.60hij	101.84h	47.60g	53.14j	1376.00e	52.03a	22.14ab	1291.87d
	PK-M2	1026.19g	2781.89d	273.43j	76.38h	273.43de	198.15efgh	1718.06bcde	29.89a	52.03ab	1568.62bcd
	PK-M3	1322.87cdefg	3271.19bcd	378.59efgh	111.81h	378.59bc	257.93def	1838.73abcd	66.42a	14.39b	1723.60bc
	PK-M4	1524.34bcde	3511.40abcd	192.62cdefg	137.27gh	192.62ef	129.52ghij	1588.55cde	80.81a	14.39b	1527.66bcd
N		4.82**	3.42*	28.94**	78.79**	19.85**	30.66**	1.75	1.27	0.80	3.63**
PK-M		19.19**	7.59**	41.76**	42.40**	76.07**	69.69**	12.90**	0.48	1.18	9.45**
N×PK-M		0.10	0.04	0.71	2.64**	1.13	2.23**	0.10	0.75	1.81	0.27

表4

图4

表5

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时间 Time		次序 Order	N1	N2	N3	N4	PK-M1		PK-M2		PK-M3		PK-M4
时间 Time		次序 Order	N1	N2	N3	N4	P	K	P	K	P	K	P	K
2018	6月20日	1	12.50	12.50	12.50	12.50	50.00	50.00	12.50	12.50	25.00	25.00	37.50	37.50
	7月3日	2	12.50	12.50	12.50	12.50	50.00	50.00	12.50	12.50	25.00	25.00	37.50	37.50
	7月13日	3	12.50	12.50	12.50	12.50	-	-	12.50	12.50	8.33	8.33	4.17	4.17
	7月20日	4	12.50	12.50	12.50	12.50	-	-	12.50	12.50	8.33	8.33	4.17	4.17
	7月30日	5	12.50	12.50	12.50	12.50	-	-	12.50	12.50	8.33	8.33	4.17	4.17
	8月8日	6	12.50	12.50	12.50	12.50	-	-	12.50	12.50	8.33	8.33	4.17	4.17
	8月17日	7	12.50	12.50	12.50	12.50	-	-	12.50	12.50	8.33	8.33	4.17	4.17
	8月24日	8	12.50	12.50	12.50	12.50	-	-	12.50	12.50	8.33	8.33	4.17	4.17
	合计 Total		100	100	100	100	100	100	100	100	100	100	100	100
2019	6月14日	1	11.11	11.11	11.11	11.11	33.33	33.33	8.33	8.33	16.67	16.67	25.00	25.00
	6月22日	2	11.11	11.11	11.11	11.11	33.33	33.33	8.33	8.33	16.67	16.67	25.00	25.00
	6月30日	3	11.11	11.11	11.11	11.11	33.33	33.33	8.33	8.33	16.67	16.67	25.00	25.00
	7月9日	4	11.11	11.11	11.11	11.11	-	-	12.50	12.50	8.33	8.33	4.17	4.17
	7月18日	5	11.11	11.11	11.11	11.11	-	-	12.50	12.50	8.33	8.33	4.17	4.17
	7月25日	6	11.11	11.11	11.11	11.11	-	-	12.50	12.50	8.33	8.33	4.17	4.17
	8月3日	7	11.11	11.11	11.11	11.11	-	-	12.50	12.50	8.33	8.33	4.17	4.17
	8月12日	8	11.11	11.11	11.11	11.11	-	-	12.50	12.50	8.33	8.33	4.17	4.17
	8月18日	9	11.11	11.11	11.11	11.11	-	-	12.50	12.50	8.33	8.33	4.17	4.17
	合计 Total		100	100	100	100	100	100	100	100	100	100	100	100

	相对产量 Relative yield
	2018年播种后天数 Days after sowing in 2018 (d)					2019 年播种后天数 Days after sowing in 2019 (d)
	58	78	99	109	119	65	88	107	120	156
叶面积指数 Leaf area index	0.41	0.46	0.50^*	0.80^**	0.91^**	0.4	0.42	0.45	0.81^**	0.62^**
蕾数 Square number	0.45	0.67^**	0.85^**	0.85^**	-	0.42	0.50^*	0.81^**	-0.37	-
花数 Bloom number	-	0.48	0.22	0.39	-	-	0.81^**	0.84^**	-0.13	-
铃数 Boll number	-	0.25	0.80^**	0.81^**	-	-	0.64^**	0.76^**	0.83^**	-
生殖器官个数 Reproductive organ number	0.45	0.55^*	0.84^**	0.86^**	-	0.42	0.73^**	0.81^**	0.78^**	-
生殖器官干物质 Dry matter of reproductive organs	0.88^**	0.85^**	0.91^**	0.97^**	0.91^**	0.87^**	0.81^**	0.86^**	0.89^**	0.82^**
叶片干物质 Leaf dry matter	0.43	0.43	0.44	0.3	0.34	0.64^**	0.46	0.50^*	0.51^*	0.49^*
茎秆干物质 Stem dry matter	0.53^*	0.41	0.4	0.38	0.42	0.58^*	0.48^*	0.45	0.64^**	0.48
干物质总量 Aboveground dry matter	0.55^*	0.53^*	0.65^**	0.79^**	0.78^**	0.62^**	0.59^*	0.76^**	0.82^**	0.83^**

氮磷钾运筹模式对北疆滴灌棉花生长发育和产量的影响

Effects of Nitrogen, Phosphorus and Potassium on Drip-Irrigated Cotton Growth and Yield in Northern Xinjiang

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处理 Treatment		2018						2019
处理 Treatment		K’ (m²·m^-2)	t₁ (d)	t₂ (d)	V_max (m²·m^-2·d^-1)	T (d)	GT	K’ (m²·m^-2)	t₁(d)	t₂ (d)	V_max (m²·m^-2·d^-1)	T (d)	GT
N1	PK-M1	3.38	60	76	0.14	16	2.23	3.33	54	83	0.08	29	2.19
	PK-M2	3.90	58	73	0.17	15	2.57	4.03	56	72	0.16	17	2.66
	PK-M3	4.04	59	78	0.15	18	2.66	4.07	51	84	0.08	34	2.68
	PK-M4	3.61	60	76	0.15	16	2.38	3.66	53	82	0.08	29	2.41
	Average	3.73	59	76	0.15	16	2.46	3.77	53	80	0.10	27	2.49
N2	PK-M1	3.50	61	79	0.12	19	2.31	3.55	54	92	0.06	38	2.34
	PK-M2	4.01	59	77	0.15	18	2.64	4.00	53	78	0.11	25	2.63
	PK-M3	4.23	60	82	0.13	22	2.78	4.25	50	91	0.07	42	2.80
	PK-M4	3.75	61	79	0.13	19	2.47	3.74	53	88	0.07	35	2.46
	Average	3.87	60	79	0.13	19	2.55	3.89	52	87	0.08	35	2.56
N3	PK-M1	3.65	61	82	0.12	21	2.41	4.18	56	110	0.05	53	2.76
	PK-M2	4.18	61	80	0.14	19	2.75	4.28	54	86	0.09	33	2.82
	PK-M3	4.52	62	86	0.12	24	2.98	5.31	58	111	0.07	53	3.50
	PK-M4	3.93	61	82	0.13	20	2.59	4.34	53	104	0.06	50	2.86
	Average	4.07	62	83	0.13	21	2.68	4.53	55	103	0.07	47	2.99
N4	PK-M1	3.11	61	79	0.12	18	2.05	2.74	54	82	0.06	28	1.80
	PK-M2	3.55	60	76	0.14	16	2.34	3.78	55	80	0.10	25	2.49
	PK-M3	3.65	62	79	0.14	17	2.40	3.95	54	91	0.07	37	2.60
	PK-M4	3.33	60	78	0.13	17	2.19	3.38	54	87	0.07	33	2.23
	Average	3.41	61	78	0.13	17	2.25	3.46	54	85	0.08	31	2.28

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