Abstract
The objective of this study is to investigate the effects of climate change (i.e. change in
rainfall, maximum temperature, minimum temperature, number of rainy days) on mangosteen
production in Phatthalung province, Thailand. The trend of rainfall maximum temperature
minimum temperature and average temperature increase but the number of rainy days decreases
during the 30 years. A change in the distribution of rainfall affects the phenological of flowering,
productivity and quality of fruit each year is different. The mangosteen flowered in in-season and
off-season when there was a period of drought before the flowering season but in 2010 found high
rainfall and the drought period not enough in July and August. The mangosteens are no inducing
flowering and have flushing. The pattern of distribution of rainfall in the year 2009 is suitable for
flowering and fruit quality. Carbohydrate intake is non significant difference, but an increasing
trend in the growth prior to flowering of plants. The mangosteen has been used in the growth of the
flower and development fruit. Nitrogen is different in a statistically significant and tends to
decrease when the flowering and flushing. The ratio between carbohydrates and nitrogen is
indicative of the growth and during the flowering stage. The ratio of the two will decrease as the
plants in the flowering. Quality productivity and production yields increases or decreases are
consistent with the drought period before flowering of mangosteen and distribution of rainfall.
3. F
F (
ʾ) F F ʾ 2551 2552 ˈ
F F ʾ 2553 F F F
F F F
30 ʾ
F F
F ʾ F F
F F ʾ 2553 F
F F F F
F F F
ʾ . . 2552 F F
F F F F F F
F F
F F F F
F F F F F F
F F F F F F
F F F
F
4. Abstract
The objective of this study is to investigate the effects of climate change (i.e. change in
rainfall, maximum temperature, minimum temperature, number of rainy days) on mangosteen
production in Phatthalung province, Thailand. The trend of rainfall maximum temperature
minimum temperature and average temperature increase but the number of rainy days decreases
during the 30 years. A change in the distribution of rainfall affects the phenological of flowering,
productivity and quality of fruit each year is different. The mangosteen flowered in in-season and
off-season when there was a period of drought before the flowering season but in 2010 found high
rainfall and the drought period not enough in July and August. The mangosteens are no inducing
flowering and have flushing. The pattern of distribution of rainfall in the year 2009 is suitable for
flowering and fruit quality. Carbohydrate intake is non significant difference, but an increasing
trend in the growth prior to flowering of plants. The mangosteen has been used in the growth of the
flower and development fruit. Nitrogen is different in a statistically significant and tends to
decrease when the flowering and flushing. The ratio between carbohydrates and nitrogen is
indicative of the growth and during the flowering stage. The ratio of the two will decrease as the
plants in the flowering. Quality productivity and production yields increases or decreases are
consistent with the drought period before flowering of mangosteen and distribution of rainfall.
6. F
1 F F F ʾ . . 2552-2553 16
2 F , , F, 24
F, F
ʾ . . 2551-2553
3 25
4 F F F 28
ʾ . . 2553
5 F F 29
ʾ . . 2553
6 C:N F F 30
ʾ . . 2553
7. F
1 F 30 ʾ 13
2 F 14
30 ʾ
3 F 3 ʾ (2551 , 15
2552 2553 )
4 F 17
5 F F F F 18
0.125 F
6 F F A, I O 18
ʾ . . 2552 ʾ . . 2553
7 F F 19
8 A, I O ʾ . . 2552 19
ʾ . . 2553
9 F 20
2553
10 F F , F F F 21
F F (
ʾ 2553)
11 F F F F 23
F 13
12 F F F 23
F ʾ 2553
8. ( F )
13 F F 23
ʾ 2553
14 ˈ F F F 24
F
15 F ( F F ) F ʾ . . 2551 - 25
2553
16 F F F F F 26
F F F F F
F ʾ . . 2553
17 F F 26
F ʾ . . 2553
18 F F F 27
ʾ . . 2553
19 F F 29
ʾ . . 2553
20 33
9. F
1 ʾ ʾ . . 2551 -
ʾ . . 2553
42
2 ʾ . . 2551 - ʾ . .
2553
42
3 F F F
A, I O ʾ . . 2552 ʾ . . 2553
43
4 F F 43
1 F 45
2 F 45
3 F 45
4 ˆ F 45
5 ˆ F 45
6 F F 46
7 F 46
8 F F C:N ratio 46
10. 1
(Garcinia mangostana L.) ˈ F F F
F F ˈ
F ( , 2552; F , 2549)
ʾ . . 2552 487,405 F
F 399,438 F F ˈ F 194,792 F
F 157,218 F F 112,184 F F F 714
F F 287,589 F F 242,220 F F 158,370
F F F 654 ( , 2552) F
F F F F ˁ F F
F F
F F ʾ . . 2553 119,263 ˈ F
1,928,806 ( F F , 2553) F
F F F F
F 0 % ˁ F F F F F
F ˈ F F F F F F
F ˆ F ʾ F F F
F ( 80 F F F
F F ) ( F
F , 2550) ˆ F F F ʾ F
F F F F F F
F F ˆ F ʾ
( F , 2544)
F F F F F
ˈ ˆ F F F
ʾ F F
F F F (Evans, 1996)
F
F F ˆ 2 ˆ ˆ ˆ
F ˆ F F F F F F
11. 2
ˈ ˆ ˆ
ˆ F F F F ˆ F F
F F F
F F
F ˈ F F
The World Bank (2010) F
ˈ
F F
F F F
ʾ F F F F F F ˈ ˆ F
F F F ˈ F
F F F F ˆ ˆ
F ʾ F ʾ F F
F F F ˈ
F ˈ F ˈ
F F
12. 3
1.
ˈ F F F F F ˈ
ʽ ( F F, 2540) F F
F F
F ( , 2541) F 9-25
F 4.5-10 F ˈ F F F
( , 2541) F F F F F F
F F F ˈ F ˈ F
F F ˈ F F F ˈ
(terminal bud) ˈ F F F F
3.4-7.5 6-10 F F
F ˈ 4-8 F 80-150 ( ,
2545) F F 13-14 F
18 F
0.49 F F ( F, 2533) ˈ F
F F ˈ F
ˈ F F F ( ,
2545) ˆ F F
F 80 F F 25-35 1,270
F ʾ (Yaacob and Tindall, 1995) F
70 F F F
ˈ F F 5.5-6.5 ( F , 2544)
2. F
ˆ F F F
ˆ
F F F F
F F F F F
F
13. 4
F F
F F F ˈ ˆ
F F
(Chinvanno and Snidvongs, 2007)
F (2552) F F F
F F F
F 1.5-2.5 F F F
F F 20-30 F F F F 10
ˈ F 40 3-4 F F
F 3-30 F F F
F F
F F 35 1-2 F
F F F ʾ F
ˆ 2 F 1 F F
F 1 20 ʾ
F F F
F ˆˉ
F ˈ F F
F F F F ˆˉ F
F ˆˉ
F ˈ
F F F F F
F F F F F F F
F F F ʾ F ʾ ( , 2536; , 2548)
F (2531) F F F F F F
F F F F 10 20 F ˈ
F 2-3 F ( F , 2544)
F ˆ ˈ ˆ ˈ F
F F F F 2550 ˈ
ˈ ˆ F F
F F ( F , 2544)
14. 5
F ˆ F F F
ʾ F Salakpetch (2005) F ʾ 2549 F
F F F F ʾ 2548 F F
F F F ( , 2549)
F (alternate bearing) ˈ ˆ
F F (Hoad, 1984 Salakpetch, 2006)
F F F (Bangerth, 2006) F
F ˆ F F F F F (Hoad, 1984) ˆ
F ˆ F F F
(2540) F ˄ F
F F F
F F F F F F 15
F F 9.8 F F ˈ F
F F F (2541) F
F
F ʾ ʾ . . 2535 2538 F F
F F F F F
F F
F ʾ . . 2536 2537 F F
F F 47.25 F F 40.55 F F
F F ʾ . . 2538
100.53 F F F F
F F (2541) F F
F F F F
F F F F F F F
F F F F
(2541) F 2 6 F
F F F F
F F F 2 F F F
F F F ˀˊ F F F F F
F F F F F F
F F (2539) F
15. 6
F ˈ F F ˀˊ F
F F ˆ F F F
ˆ F F
( , 2529 Salakpetch, 2005) F F
F 21
( , 2538) F
F 16 ( F, 2545) F F F F
F 7-15 F F ( F
, 2542)
3. ˆ F F
F F
F ˆ F F
F F F F
( , 2545)
F F F F F
F F F F F
F F F
F F F
F F F F F F
F F F F ˈ F F F
( 2540)
F ˆ
F F ʾ / F F F ˆ
F F
ˆ ˆ F F F F
ˆ F ʾ F
F F F
ˈ F F F F F F
F F F
ˈ F F ˈ F
16. 7
ˆ F F
F F F F F
ˈ F F F F F F (
F 5 , 2552) F
14,471 F F F ʾ 15.79 F F
21.68 F 12.80 F
( F ) 41.71 F ( , 2550) F
F F F ˈ F F F F
F F F ˆ F F
F
1. F F F
ˈ F F F
F F F F F
ˆ F F F F F
: 2553 2554
ˆ F F F
(Latitude 7° 35' 14.4'' Longitude 99° 59' 56.9'' Altitude 44
above the sea level)
17. 8
F F
F 17-18 ʾ 10 x 8
5-6 129 F ˈ F F
15.85 F F F 16.59 F F 67.58 F F F
F
F F
F F F F F F F F F F
2553 2553 1 ʾ F
ʾ . . 2552 F ˈ F ˈ
F F F Completely Randomized Design: CRD 3
10 (1 F / ) F F
1 F ʾ 2552 (I)
2 F ʾ 2552 (O)
3 F F ʾ ʾ 2552 (A)
F
1 F ʾ
1.1 F
1. F F F F
F
2. F ʾ 2553 F
F F F
F ˈ F F F
3. F F F F F F 1-14
2553 ˈ F F
18. 9
F F F 14 F F
F
4. F F F 2 F
F
4.1 F F F (Pressure chamber) F
3 / F / F F F F F F
F ʽ F F F
F F F 2 F F 10.00 . 12.00 .
14.00 . F F F ˈ F
4.2 F F 3 / F / F
F F F F 2 F F
10.00 . 12.00 . 14.00 . F F F ˈ
F
4.3 F Moisture meter F Delta-T Devices F
HH2 F Profile Probe type PR2
F F 100 F ˆ F ʽ F F F
F ˆ F 10, 20, 30, 40, 60 100 F
F
5. F F F F F F
(Cubic frame) 0.125 F ( F 0.50 x 0.50 x 0.50 )
F F 4 / F / F F F
F F F
F F = x 100
F F F +
6. F F F F
F F F
F F 20 F F F
10 / F / F
6.1 F F F ( ) F F F F F
F F F F
19. 10
6.2 ( ) F ˂ 2
F F F F F
6.3 ( ) F F F
F F F
F F F F
6.4 F ( ) F F F F F
F F F F F F
6.5 F (total soluble solid) F F F
F F F
F F F ˈ F (°Brix) F F F F
6.6 F (titratable acidity) F
NaOH F F 0.1 N F phenolphthalein F F 0.1 F F ˈ indicator
F F F
F F F = N base x . Base x meg.wt. x 100
. F
: N base = F F (normality) F
. Base = F
Meg.wt. = 0.06404
F F F F
6.7 F F F
80 ˈ 4 F F F
F F = F x 100
F F F F
6.8 F F F
80 ˈ 4 F
F F
F F = F x 100
F F F F
20. 11
6.9 F F F
F F F F F F
7. F F F F
F F
F F F
8. F F F Confocal Laser Scanning Microscope
(CLSM) ˈ 3 F F F F IX70, Olympus (Inverted
microscope) Eyepiece10x, Objectives UPLAPO 20x, Filter BA510IF F F
F F
9. F F F Least
Significant Difference Duncan s Multiple Range Test
2 F F
ʾ
F F
F
F F F F
F F 2553 2553 1 ʾ F
ʾ . . 2552 F ˈ F ˈ
F F F Completely Randomized Design:
CRD 3 10 (1 F / ) F F
1 F ʾ 2552 (I)
2 F ʾ 2552 (O)
3 F F ʾ ʾ 2552 (A)
1. F F F 2
ʾ 2552 ˈ F F 1 F
ˈ F 8 F F F F F
21. 12
2. F F Kjeldahl F F ʽ
F F F
3. F F (TNC) Manual Clegg Antrone ( )
F F
TNC = mg glucose equivalent x vol make
wt. of sample x vol take
4. F F F Least
Significant Difference Duncan s Multiple Range Test
22. 13
1 F ʾ
1. F 30 ʾ ( ʾ . . 2523-2553)
F ˆ F ʾ
F F F IPCC ( , 2551)
F F - F
F F
F F F F
30 ʾ F F F
F F
1 F (A) (B) 30 ʾ ( ʾ . . 2523-
2553)
The number of rainy days
Rainfall (A)
RainfallAnomaly(mm)NumberofrainydayAnomaly(d)
(B)
Year
23. 14
2 F (A) (B) (C)
30 ʾ ( ʾ . . 2523-2553)
2. F 2 ʾ ( ʾ . . 2551-2552) F ( ʾ . . 2553)
ʾ . . 2553 F F F F ʾ . .
2551 2552 ( F .) F F
F F F ʾ . . 2551 -
2553 F ʾ . . 2551 698.9
63.2
124.31 54.30
33.3 23.5
F ʾ . . 2552 732.4
(A)
(B)
(C)
TemperatureAnomaly(°C)
Year
Year
24. 15
26.1 F
141 72
36.4 21.5
F F ʾ . . 2553 806.90
10.10 F 153
56.4
35.7 23.87
F 3 ʾ F F F F
F F F F F
F F F F F (
- ) F (2538) F F
F F
ˈ F F F F F F
F ʾ . . 2553 ( - )
3 F 3 ʾ (2551 (A), 2552 (B)
2553 (C)) ( indicated water deficit period, F = Flowering, LFS
= Leaf flushing, H = Harvest)
(A)
(B)
(C)
1st
F 1st
H
2nd
H 2nd
F 2nd
H
1st
F 1st
H
2nd
F
1st
F 1st
H
1st
LFS 2nd
LFS 3rd
LFS
2nd
LFS1st
LFS
Month
Precipitationandevaporation(mm)
2nd
LFS
25. 16
3. ʾ
3.1 F F F - F F F
ʾ . . 2552-2553 F F F ʾ . . 2552
F F 62.03 ʾ . . 2553 F F
63.65 F ʾ . . 2552 F 5.92 ʾ . . 2553 F
F 6.04
1 F F ( ) 50
F ( ) ʾ . . 2552-2553
ʾ . . F F ( ) F ( )
2552 62.03 5.92
2553 63.65 6.04
3.2 F - F
F F F F F
F F
ʾ ʾ . . 2551 15
11 23
F 27 31
4 9 17
19 26
F
4 ʾ . . 2552 23 F
20 29
F 13 13
4 18 30
10
4 ʾ
. . 2553 8 17 27
9
F 30 7 4
26. 17
3.3 F - F 2 ʾ . . 2551
. . 2550 . . 2551 F 2 F
. . 2551 . . 2551 ʾ . . 2552 F F
. . 2551 . . 2552 F 2
. . 2552 F . . 2552 ʾ . . 2553 F
. . 2553 . . 2553 F 2 (2 ) 1 F
2 F
4 F ( ) ( )
3.4 F - F F (cubic frame) ʾ
. . 2553 ˈ F F
ˈ F F F F F (0.5 x 0.5 x 0.5 )
0.125 F F F ( 6 F ) F
F F 15 F 17
12 F F F F 11
3.5 F F F F F F
1 - 14 ʾ . . 2553 F (I), (O)
(A) F F F F F F
F F F ˈ F F
F F ˈ F F F F
( ) ( )
27. 18
F F F (O) F
F F (I) F (A) F
F F 7 F (O) F F
199.66 F F F F (I) (A) 118.66 90 F F
5 F F F F 0.125 F
0
50
100
150
200
250
1 2 3 4 5 6 7 8 9 10 11 12 13 14
A I O
6 F F ʾ . . 2553
A= F F ʾ ʾ 2552, I= F ʾ 2552 O= F ʾ 2552
FF()
F ( )
28. 19
7 F F ( ) ( )
3.6 ʾ . . 2553
F 1 - 14 F (I), (O) (A) F
F F 1-14 F
F F F 1-7 F
F F 8 ˈ F F F ʾ
. . 2552 ʾ . . 2553 (A) 52.26
F 14 F ʾ . . 2552
ʾ . . 2553 (I) F ʾ . . 2552 ʾ 2553 (O) (50.63
49.35 )
20
25
30
35
40
45
50
55
1 2 3 4 5 6 7 8 9 10 11 12 13 14
A I O
8 A= F F ʾ ʾ 2552, I= F
ʾ 2552 O= F ʾ 2552
0
()
( ) ( )
29. 20
0
5
10
15
20
25
30
35
40
1
6
11
16
21
26
5
10
15
20
25
30
3
8
13
18
23
28
2
7
12
17
22
27
( )
()
9 F
. . 2553
4. F F
4.1 F - F F F 10.00 14.00 . F
F F (I), (O) (A) F
F F F ( F 1-2
) F A F -1.48
MPa I O F F -1.35 -1.17 MPa F
F F F F F A F
I O ˈ F F
F F F F F F F F
4.2 F - F F F 10.00 14.00
. F F F (I), (O)
(A) F F F (A) F
3.884 µmolCO2 m-2
s-1
F (I) (O) 3.653 3.594 µmolCO2 m-2
s-1
F
F F F F F F F F F
400-600 µmol m-2
s-1
F F
30. 21
4.3 - F F
(I), (O) (A) 10, 20, 30, 40, 60 100 F
20-30 30-40
100
60
F F
F F (A)
F (I) (O) F
-1.6
-1.4
-1.2
-1
-0.8
-0.6
-0.4
-0.2
0
10 12 14 10 12 14 10 12 14 10 12 14 10 12 14 10 12 14 10 12 14
A I O
10 F F ( ) F F F
( ) F F ( ʾ
. . 2553) A= F F ʾ ʾ 2552, I= F ʾ 2552 O= F ʾ
2552
10.00
12.00
14.00
F ( )
F
FF(MPa)
( )
( )
10.00
12.00
14.00
10.00
12.00
14.00
10.00
12.00
14.00
10.00
12.00
14.00
10.00
12.00
14.00
10.00
12.00
14.00
0
0.5
1
1.5
2
2.5
3
3.5
4
10.00
12.00
14.00
10.00
12.00
14.00
10.00
12.00
14.00
10.00
12.00
14.00
10.00
12.00
14.00
10.00
12.00
14.00
10.00.
12.00.
14.00.
FFF
(µmolCO2m-2
s-1))
10.00
12.00
14.00
10.00
12.00
14.00
10.00
12.00
14.00
10.00
12.00
14.00
10.00
12.00
14.00
10.00
12.00
14.00
10.00
12.00
14.00
10.00
12.00
14.00
F
F ( )
31. 22
5.
5.1 F F - F F F
F (I), (O) (A) F 13 F F F F
F F (A) F F 40.85 F F F
F F F (I) F F 38.25 F F F F
F F (O) 38.84 F F
5.2 F F F F
(I), (O) (A) F F F F (A)
F F 24.10 F (I)
(O) 15.73 16.17
5.3 F
F F F F
F A 71.00
F F F I (64.00 ) F
O 61.00
F ʾ 2552 8.53
F F ʾ 2553 (8.13 ) F F (A)
8.34 F F F (I) (8.32 ) F F
F F O (7.85 )
F F 3 ʾ F F
ʾ 2553 F F (I) F F 18.12 F
F F F (A) (O) F 17.87 17.04
F
F F ʾ 2551 F F
F 0.66 % F F
ʾ 2552 2553 ʾ 2553 F (A) (I) F F 0.76 %
F (O) F 0.72 %
32. 23
40.85
38.25 38.84
25
30
35
40
45
A I O
(FF)
11 F F F F F 13
(A= F F ʾ ʾ 2552, I= F ʾ 2552 O= F
ʾ 2552)
24.10
15.73 16.17
0
5
10
15
20
25
30
A I O
(FF)
12 F F F F
ʾ 2553 (A= F F ʾ ʾ 2552, I= F ʾ 2552 O= F
ʾ 2552)
71.00
64.00
61.40
40
50
60
70
A I O
()
13 F F ʾ
2553 (A= F F ʾ ʾ 2552, I= F ʾ 2552 O= F ʾ 2552)
: F F F F DMRT
0
a ab b
0
()
33. 24
5.4 ˈ F F
ˈ F 3 ʾ F F ʾ . . 2553
F
F F F F F F
F (I) F F F
( ) F F F ( F )
2 F ( ), ( ), F
(°brix), F (%), F (%) (%)
ʾ . . 2551-2553
Year Season
Fruit Quality
Fruit Weight
(g fruit-1
)
Peel thickness
(mm)
Total soluble solids
(TSS)(°brix)
Titratable
acidity (TA) (%)
Fruit disorder (%)
TFD GB
2008
In-season 58.90 e 7.36 c 17.00 0.66 b 14.35 c 18.25 d
Off-season 88.10 b 7.20 c 17.84 0.77 a 18.95 b 16.66 e
2009
In-season 105.77 a 8.53 a 17.38 0.82 a 12.94 e 19.82 b
Off-season 83.27 c 7.54 c 17.61 0.76 a 21.36 a 23.72 a
2010 In-season 74.67 d 8.13 b 17.67 0.74 a 13.33 d 19.33 c
5% LSD ** ** ns * ** **
CV (%) 2.36 2.56 2.47 6.36 0.64 0.72
* = Means with different letter are significant difference (p≥0.05) by DMRT
**= Means with different letter are significant difference (p≥0.01) by DMRT
ns = non significant difference
0
5
10
15
20
25
A I O
(FF)
14 ˈ F F F
F ʾ . . 2553
34. 25
5.5 3 ʾ F F F
ʾ 2552 F F 105.77 F F
ʾ 2551 F F 58.90 F F ʾ
2553 F 388.70 F F 65.47 F
18.67 F F (I) F 371.60 F F 64.00
F , F (O) F 343.50 F F 61.40 F F
(A) F 451.00 F F 71.00 F F
F (A) F 24.10 F F F (I) F 15.73 F F F
(O) F 16.17 F F F F
15 F ( F F ) F ʾ . .
2551 - 2553
**Bars with different letter are significant difference (p≤0.01) by DMRT
3 ʾ . . 2553
( F F ) ( F ) ( F F )
A 451.00 a 71.00 a 24.10
I 371.60 ab 64.00 b 15.73
O 343.50 b 61.40 b 16.17
F-test ** * ns
C.V. (%) 18.30 4.76 27.96
: F F F F F
* F P≤ 0.05
** F P≤ 0.01
ns F F
0
10
20
30
40
50
60
In-season Off-season In-season Off-season In-season
2008 2009 2010
d**
b
a
c bc
Averagefruityield(kgtree-1
)
35. 26
5.6 F Confocal Laser Scanning Microscope (CLSM) -
ˈ F F F F F F 3
F F F
F F F F ˈ
ˈ F F
( F ) ˈ F ˈ F
F ˈ F F F F F
F F F F F F F
F F F F ˈ F
F F F
16 F F F F ( ) F
F F F F ( ) F
F ʾ . . 2553
F
17 F F F
ʾ . . 2553
( ) F
F F
F F
( )
36. 27
2 F F
ʾ
1. F
F F ʾ . . 2553 F
F (A= F F ʾ ʾ 2552, I= F ʾ 2552 O= F ʾ
2552) F F F F F
F F F
F F
F F F
F F F (O) F
21.487 F F (O) F F
17.369 F
10
12
14
16
18
20
22
24
A I O
18 F F F
(A= F F ʾ ʾ 2552, I= F ʾ 2552 O=
F ʾ 2552) ʾ . . 2553
0
F(F)
37. 28
4 F F F
(A= F F ʾ ʾ 2552, I= F ʾ 2552 O=
F ʾ 2552) ʾ . . 2553
F
F ( F )
A 21.2709 19.4661 18.7824 17.6565 18.2237 18.0672
I 20.8013 19.0024 20.8928 17.6966 17.5783 20.5058
O 21.2397 19.6449 20.0345 17.3690 18.3770 20.0145
5% LSD ns ns ns ns ns ns
CV (%) 4.34 5.68 6.02 3.21 3.41 6.29
( F )
F ( F )
A 18.7628 20.3149 20.2543 20.8597 20.6292 21.0755
I 19.1913 19.1930 19.8903 21.0843 20.2431 20.7136
O 18.9408 19.4437 20.0179 21.4195 21.4873 20.7431
5% LSD ns ns ns ns ns ns
CV (%) 1.93 2.86 3.37 2.62 3.70 3.47
: ns F F
2.
F ʾ 2553 F
F (A= F F ʾ ʾ 2552, I= F ʾ 2552 O= F ʾ 2552)
F F , F, ,
, , , F
F F F F
F F F F F F
F F
F F F ˈ
F ʾ 2553 F F F
F F (I) F 1.219
38. 29
F F F (O) F F 0.922
F F
0.6
0.8
1
1.2
1.4
F
%
A I O
19 F F
(A= F F ʾ ʾ 2552, I= F ʾ 2552 O= F
ʾ 2552) ʾ 2553
3. F F
F F ʾ . . 2553 F
F F F F
F , F, , , ,
F F F F
(A) F 2.25 F (I) F
F 1.495
5 F F
(A= F F ʾ ʾ 2552, I= F ʾ 2552 O=
F ʾ 2552) ʾ 2553
F
(%)
A 1.071 c 1.022 b 1.051 a 1.101 b 1.108 ab 1.119
I 1.219 a 1.135 a 1.109 a 1.184 a 1.153 a 1.075
O 1.146 b 1.154 a 1.080 a 1.124 ab 1.083 b 1.095
5% LSD ** ** ns * * ns
CV (%) 2.54 2.02 2.77 2.66 2.44 3.10
0
39. 30
( F )
(%)
A 1.069 1.006 ab 0.931 b 0.925 b 1.032 1.143 ab
I 1.093 1.055 a 1.020 a 1.077 a 1.085 1.108 b
O 1.081 0.968 b 0.922 b 0.951 b 1.050 1.164 a
5% LSD ns ** ** ** ns **
CV (%) 2.07 2.64 4.43 2.74 3.02 1.84
: * F P≤ 0.05
** F P≤ 0.01
ns F F
6 C:N F F
(A= F F ʾ ʾ 2552, I= F ʾ 2552 O= F
ʾ 2552) ʾ . . 2553
F
F C : N
A 1.939 a 1.904 a 1.787 1.603 1.645 ab 1.614
I 1.707 b 1.674 b 1.882 1.495 1.525 b 1.907
O 1.853 ab 1.703 ab 1.855 1.546 1.697 a 1.828
5% LSD ** ** ns ns ** ns
CV (%) 5.66 5.87 6.90 4.33 5.06 8.35
( F )
F C : N
A 1.755 2.019 a 2.175 a 2.255 a 1.999 1.844
I 1.756 1.819 b 1.949 b 1.958 b 1.866 1.870
O 1.752 2.008 a 2.172 a 2.253 a 2.047 1.781
5% LSD ns ** ** ** ns ns
CV (%) 2.24 0.50 3.13 3.89 4.60 4.57
: * F P≤ 0.05
** F P≤ 0.01
ns F F
40. 31
F
1.
F F ʾ . . 2551 ʾ . . 2553 F
F F F
F F
F F F Boonklong (2005); Boonklong et al (2006)
F F F F
F F
( 20) F F
F ʾ (Osman
Milan, 2006) F F F
F F ˆ F F
F 1-2 F
F F ˈ F F
21-30 F F F
F F
F Salakpetch (2006) F
F F F F ˀ (Salakpetch et al.,
1990), (Salakpetch et al., 1992) (Poonnachit et al., 1996) F F F F
F F F F
ʾ ʾ . . 2551 F
F
F F F F
. .
2551 . . 2552 ʾ . . 2552 F
F F
F
F F
F ʾ . . 2553
ʾ . . 2553 F (
41. 32
1) 2 (2 )
F F ʾ . . 2553
F F ʾ . . 2551 ʾ . . 2553 F
F F ʾ . . 2551 . . 2553 ˈ ʾ
F
F ʾ . . 2552 ʾ . . 2551 F F F
ˈ F ˈ F F
F F F F
ʾ . . 2551 58.90 F
F 88.10 F ˈ F F F F F
ʾ . . 2552 F 105.77 F ( ) 83.27 F
( ) F F F F ʾ . . 2552 ˈ ʾ
F F F
F F F F F ʾ
. . 2553 F F F F
F F
F F ˈ F F
F (2541) F F F F F
F F F F F 2-6
F ˈ F F
F 2 F F
F F F ˀˊ F F F 2-
6 F F F F F
(2539) F F F
F F F F
F F F F F
F (2548) F F F
F F F F F F F F
F F F ʾ
F F F
F F F F F
42. 33
F F F
F Manakasem (1995) F F
F F F F
F F F
20
: http://en.wikipedia.org/wiki/File:Asia_Koppen_Map.png
2. F
F ʾ
. . 2553 F F F
ˈ F F F F ˈ F F
43. 34
F F F F F
F F F
F F
F F F (
) F F F F F F F F
F ( ) F F F
F F F F F
F F ˈ ˆ F
F
F (I) (O) F F F
F F F F F F
F F F F F F
F F F F
F F F
F Burke et al (1992) F F
F F F F Chaitrakulsup (1981)
total nitrogen (TN) F F TN
F 9 F F Menzel and Simpson (1994) Menzel et
al. (1998) F F F
F F F F
F F C : N F F F F
F F F F
F F F F C : N F
F ( )
F F F F C : N ( ʾ
F ) F F
44. 35
F F
F F ʾ . .
2551 2552 F 2 F ʾ . . 2553 F F
ʾ . . 2553 F
F F F F ʾ . . 2553 F
F F F F F F
F F
F F F F F F
F F F F F F F
F F F F F
45. 36
F
F . 2544. . : F.
F . 2547. F . . F 1: 20-24.
F , 2553 F F http://www.doae.go.th/plant/mungkud.htm F
10 2553
F , 2553) F F http://www.doae.go.th/LIBRARY/html/
detail/hormone/hormone2.htm F 10 2553
. 2552. F . F F http://www.tmd.go.th
F 21 2553
F . 2545. 1. (Garcinia mangostana Linn.) 2.
(Garcinia mangostana
Linn.) F F.
F. 2548. F F
F F.
. 2536. F
F F.
F . 2533. F . F
F.
F . 2545. . : .
. 2529. F F F F .
: F F.
. 2549. F ʾ .
F F.
. 2538. F F
. . 2: 15-20.
F. 2541. F F. : F F F .
F . 2541. F . :
. .
46. 37
F. 2539. F F ˆ
F F (Garcinia mangostana Linn.). F
F F.
F . 2542. F .
: .
. 2532. :
F. . 2552. F F http://www.nfi.or.th/mangosteen/th/
MangosteenClusterBackground.asp. F 21 2553
F F . 2540. F ˄
F F .
F
15 F F 12 14 F 2541.
F . 2541. F F .
: F F.
F , F , F, F F.
2544. F :
F F.
F . 2547. F
F F . F
: F F.
F . 2551. (Hevea
brasiliensis Muell. Arg.) F . F . 26(1):
50-60.
. 2550. F F http://www.mof.or.th/fruit/mangosteen
/mangosteen-ex4749.xls F 21 2553
F. 2552. F F :
http://www.oae.go.th/ewt_news.php?nid=4650. F 19 F 2553
F 5 . 2552. F F :
http://sdoae.doae.go.th/mangosteen.php. F 19 F 2553
F F. 2545. F F. :
F F.
47. 38
F 5 . 2552. F
F. F F http://www.mof.or.th/fruit/mangosteen/mangosteen-
ex4749.xls. F 21 2553
F . 2549. F F F .
F F : http://share.psu.ac.th/blog/surachart-ag001/14215. F 21
2553
. 2541. F . : F
.
F F . 2540. F F F. :
F .
F, F , , , F ,
, F F . 2531.
: F
F.
F F . 2549. F
. F F
F . 2552. . F F : http://www.nidambe11.net/ekonomiz
/2009q3/2009september24p2.htm. F 21 2553
, , F F. 2535.
F F F
F source sink relationship. : F .
F . 2539.
F . :
F . .
. 2548. F ˄ F
(Garcinia Mangostana Linn.) . F
F.
Bangerth, F., D. Naphrom, P. Sruamsiri and P. Manochai. 2006. Control of flower induction
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52. 43
3 F F F A, I
O ʾ . . 2552 ʾ . . 2553
F ( )
1 2 3 4 5 6 7
A 4.33 12.66 18.00 32.66 41.66 116.33 90.00
I 8.66 12.33 20.00 36.66 45.66 136.66 118.66
O 12.33 14.33 20.66 44.66 82.66 143.33 199.66
F-Test ** * ns * ** ns **
C.V.(%) 6.83 6.22 11.93 9.48 10.97 8.54 6.62
( F )
F ( )
8 9 10 11 12 13
A 118.00 135.00 52.33 18.66 9.00 2.66
I 117.66 83.66 53.00 22.66 10.00 2.33
O 134.00 164.66 79.66 26.33 14.33 2.33
F-Test ns ns * ns ns ns
C.V.(%) 22.53 26.00 17.80 36.37 28.61 40.90
: * F P≤ 0.05
** F P≤ 0.01
ns F F
4 F F
1. F 52 % F F 70 % F 740
260 F F F F
2. ʽ F F 14 M F F 18.03 M F 760
240 F F F F
3. Antrone 0.1 % F ʽ F ˈ ( F F
F )
4. F F 1,000 F 1
ˈ 1
5. F F 0, 10, 20, 30, 40, 100 200
F F F F 1,000 F 0, 1, 2, 3, 4, 10
53. 44
20 F 52 % 1.3 F F ˈ 100
1. F 0.1 F
2. 1 F 52 % 1.3
3. F 20
4. F F F F
5. F F 5 F F 10 F
F ˈ 100 F
F
1. F F 1 F
2. Antrone 0.1 % 5
3. F F 80 ˈ 10 14
4. F F F F
F
1. F F F F F
F 630 ˈ F
2. F F
F F F
F F
F F F
F F F F
F F