dasar ilmu tanah

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BAHAN KAJIAN
MK. DASAR ILMU TANAH
FOSFAT TANAH
www.marno.lecture.ub.ac.id
SIKLUS P DALAM TANAH PERTANIAN
Serapan
Tanaman
P- pupuk
pengendapan
imobilisasi
P- mineral
P- larutan
pelarutan
P-organik
mineralisasi
desorpsi
P- terserap
sorpsi
Pencucian & Runoff
diunduh dari:
…..
http://www.biocyclopedia.com/index/plant_nutrition/essential_elements_macronutrients/phosphorus/nature_and_transformations_of
_soil_phosphorus.php
Problematik Fosfor
Jumlah sedikit
yang terdapat
dalam tanah
Adanya fiksasi
fosfor yang
menyolok
Ketidaktersediaan fosfor
yg sdh ada dalam
tanah
HUBUNGAN P-TANAH DAN TANAMAN
* Proses-proses Energi dan reproduksi
* Pertumbuhan dan perkembangan
a Pertumbuhan akar
A Kemasakan (pembentukan
buah, biji dan pembungaan,...)
* Siklus bahan organik sangat menentukan
Senyawa P
dalam tanah
Senyawa P an-organik
1. Senyawa Kalsium
2. Senyawa besi dan aluminium
Senyawa
Fluor-apatit
Karbonato-apatit
Hidroksi-apatit
Oksi-apatit
Trikalsium-fosfat
Dikalsium-fosfat
Monokalsium-fosfat
Senyawa P-organik:
1. Fitin dan derivatifnya
2. Asam Nukleat
3. Fosfolipida
Rumus
3 Ca3(PO4)2.CaF
3 Ca3(PO4)2.CaCO3
3 Ca3(PO4)2.Ca(OH)2
3 Ca3(PO4)2.CaO
Ca3(PO4)2
CaHPO4
Ca(H2PO4)2
Kelarutan
naik
Fosfat dan kualitas perairan
• Memicu terjadinya eutrofikasi
• P memacu pertumbuhan algae
- may promote anoxia and lead to ‘dead’ zones
• P memasuki ke perairan dari sumber titik dan
sumber bukan-titik
Fiksasi Fosfat
* Membatasi ketersediaan P secara biologis
• P bereaksi sangat kuat dengan material tanah
- membatasi ketersediaan fosfat
- membatasi pergerakan fosfat dalam tanah
- pergerakan terjadi melalui erosi tanah
• Menjerap dan mengendapkan fosfat
Reaksi-reaksi Adsorpsi = Penjerapan
Adsorpsi kuat pada tanah-tanah mineral
- adsorpsi pada oksida-oksida Fe- dan Al
- adsorpsi pada tepian patahan mineral liat
silikat (terutama kaolinit)
Senyawa P-anorganik
(mengendap)
Tanah-tanah masam
8 Fe dan Al fosfat
FePO4l2H2O, AlPO4l2H2O
Tanah-tanah Alkaline
4 Ca dan Mg fosfat
Senyawa P-anorganik
Kelarutan menurun
6
pH
8










Ca(H2PO4)2
monocalcium phosphate
CaHPO4
dicalcium phosphate
Ca3(PO4)2
tricalcium phosphate
3Ca3(PO4)2lCa(OH)2
hidroksi-apatit
3Ca3(PO4)2lCaCO3
Apatite karbonat
Tata-nama anion fosfat
H3PO4 = phosphoric acid
H2PO4- = monobasic
HPO4-2 = dibasic
PO4-3 = tribasic
Fosfat paling tersedia pada kisaran pH 6 - 7
Oksida hidrous
P-Organik dalam tanah
* Sekitar 20 - 80 % dari P-total dalam
tanah berupa P-organik
* Kebanyakan berupa fosfat-inositol,
C6H6(OH)6
- sekitar 10 - 50 % dari P-organik
- sebagian asam nukleat dan
fosfolipid
Salah satu bentuk P-organik
dalam tanah adalah inositolhexaphosphate , jumlahnya dapat
mencapay 50 % dari total Porganik dalam tanah.
Siklus : Mekanisme pelepasan lambat
mineralisasi
imobilisasi
P-Organik
(P-tersedia)
HxPO4x-3
Fase fosfat padatan
(tidak-tersedia)
HUBUNGAN SIMBIOSIS :
Fungi dan Tumbuhan
Infeksi mikorhiza akar, kunci penyerapan fosfat
Akar tumbuhan
Hifa fungi
Mikorhiza
Reaksi fosfat pada tanah alkalis pH tinggi
P berubah menjadi bentuk sukar larut
senyawa-senyawa Ca dan Mg
Ca(H2PO4)2 + CaCO3 + H2O  2 CaHPO42H2O + CO2
mudah larut
kurang-larut
6 CaHPO42H2O + 3 CaCO3  3 Ca3(PO4)2 + 3 CO2 + 5 H2O
Kurang larut
3 Ca3(PO4)2 + CaCO3 3Ca3(PO4)2CaCO3
sangat tidak larut
Masalah sangat serius pada tanah-tanah kapur di daerah
iklim kering
Dinamika ion fosfat: Protonasi
acid soils
alkaline
soils
Ketersediaan
P anorganik
dalam tanah
Kemasaman tanah (pH):
Ketersediaan P bagi tanaman tgt pd bentuk anion fosfat,
selanjutnya bentuk anion ini tgt pada pH
+OH-
+ OH-
H2O + HPO4=
H2PO4Paling tersedia
bagi tanaman
H2O + PO4---
larutan tanah
sangat masam
larutan tanah
sangat alkalin
% kepekatan
100
50
H2PO4-
H3PO4
HPO4=
PO3-3
0
0
2
4
6
8
10
12
14
pH larutan
Ketersediaan
P-anorganik
tanah masam
Pengendapan oleh kation Fe, Al, Mn
Al3+ + H2PO4- + H2O
2H+ + Al(OH)2H2PO4
larut
tdk larut
Dlm tanah masam biasanya konsentrasi kation Fe, Al
lebih besar dp anion fosfat, sehingga reaksi berlangsung
ke arah kanan
Pengikatan oleh hidro-oksida: Fiksasi fosfat
OH
OH
Al OH + H2PO4OH- + Al OH
OH
larut
H2PO4 tdk larut
Hidro-oksida Al
Pengikatan oleh liat silikat: Kaolinit, Montmorilonit, Illit
1. Reaksi permukaan antara gugusan OH- yang tersembul di permukaan liat dengan anion fosfat
2. Kation Fe dan Al dibebaskan dari pinggiran kristal silikat yg kemudian bereaksi dengan anion
fosfat menjadi fosfat-hidroksi
[Al]
+ H2PO4- + 2H2O
Dlm kristal silikat
2H+ + Al(OH)2H2PO4
tidak larut
Ketersediaan
P-anorganik
pd pH tinggi
Pengendapan oleh kation Ca++ atau CaCO3
H2PO4- + 2 Ca++
Ca3(PO4)2 + 4H+
larut
tidak larut
H2PO4- + 2 CaCO3
larut
Ca3(PO4)2 yang terbentuk dalam reaksi di
atas, masih dapat berubah menjadi
bentuk-bentuk yang lebih sukar larut,
seperti senyawa hidroksi-, oksi- ,
karbonat-, atau fluor-apatit.
Reaksi-reaksi ini semua terjadi pada
tanah-tanah masam yang dikapur dengan
dosis tinggi (Pengapuran berat)
Ca3(PO4)2 + 2CO2 + 2H2O
tidak larut
Daya ikat P
dari Tanah
Fosfor yang sangat lambat tersedia
Apatit, Fe-, Mn- dan Al-fosfat tua, Fosfat organik yang
mantap
Fosfat yang lambat tersedia
Ca3(PO4)2, Fe-, mn-, dan Al-fosfat yg baru terbentuk, dan fosfat organik
baru (sedang) dimineralisasikan
Fosfat segera / mudah tersedia
Larut air : NH4-fosfat, Ca(H2PO4)2
Tidak larut: CaHPO4 dan Ca3(PO4)2
Hasil-hasil penelitian:
1. Tanah-tanah di jawa Barat:
Rata-rata 18.2 kuintal TSP dg kadar 46% P2O5 diikat oleh tanah setiap hektar lapisan olah.
2. Tanah Latosol mempunyai daya ikat setara dengan 7.8 ton superfosfat dg kadar 20% P2O5.
Kemampuan tanah menjerap
(Daya Jerap) P
Tanah
Latosol Purwokerto
Mineral Liat
Haloisit
Perlakuan
pH Daya Jerap P (*)
Tanpa kapur
Dengan kapur
5.7
5.9
30.110
26.600
LatosolCibodas
Kaolinit
Tanpa kapur
Dengan kapur
5.2
5.6
45.520
40.920
PodsolikGajrug
Smektit
Tanpa kapur
Dengan kapur
4.8
5.3
36.950
33.180
PodsolikSamarinda
Smektit
Kaolinit
Tanpa kapur
Dengan kapur
4.6
5.2
29.280
16.370
GrumusolYogjakarta
Smektit, Kaolinit
Haloisit
Tanpa kapur
6.7
14.960
Andosol Bogor
Alofan, Haloisit
Tanpa kapur
4.6
33.360
Keterangan: (*) setara dengan kg superfosfat 20% P2O5 setiap HLO
Pengapuran setara dengan 0.5 SMP
Sumber: Djokosudardjo (1982)
Pengelolaan P - Tanah
Limbah tanaman
Pupuk kandang
BOT
Tanaman
Pupuk buatan
Mineral tanah
P-tanah Tersedia
Pencucian
Erosi
Pengendalian P-tersedia dalam tanah:
1. Pengapuran
3. Pengendalian fiksasi P-tanah
2. Penempatan pupuk
Fiksasi
Siklus Lambat
P-anorganik
P-mineral
primer
(HCl-Pi)
P-mineral
sekunder
(NaOH-Pi)
(P-residu)
P-terfiksasi
(Sonic-Pi)
(P-residu)
Siklus Cepat
P-anorganik & Organik
P- larutan
tanah
P-terlarut labil
(Resin-P)
Siklus Lambat
P-Organik
P- dalam
tanaman &
jasad tanah
P-terfiksasi labil
(Bikarbonat-Po)
P-organik
terfiksasi secara
kimia dan fisika
(Sonic-Po)
(Residu-Po)
P-terlarut agak
labil
(P-terfiksasi)
(Bikarbonat-Pi)
P-terfiksasi
agak labil
(NaOH-Po)
Siklus Transformasi P-tanah (Hedley et al. 1982)
P- tanah
P-anorganik:
1. Fraksi aktif: Al-P, Fe-P dan Ca-P
2. Fraksi tidak aktif:
P-terjerap (P-absorption)
P-terselimuti (P-occluded)
P-organik
1. Inositol fosfat, Fosfolipid, Asam nukleat, Nukleotida, Gula-fosfat
2. P-organik menyumbang 30-50% dari P-total tanah
3. Senyawa P-organik terdapat dalam humus dan tubuh jasad tanah
4. P-organik dalam tanah berasal dari bahan organik
Penambahan bahan organik ke tanah bertujuan:
1. Meningkatkan kandungan bahan organik tanah
2. Sumber unsur hara N,P,K, dan lainnya
3. Meningkatkan KTK tanah
4. Mengurangi jerapan P melalui pembentukan senyawa kompleks dg oksida amorf
5. Meningkatkan dan memperbaiki agregasi tanah & lengas tanah
6. Membentuk khelate dengan unsur hara mikro
7. Detoksifikasi Al
8. Meningkatkan biodiversitas tanah.
1. No direct practical importance
2. Sering dipakai sbg “Indeks Pelapukan”
3. P-total topsoil menurun dengan intensitas
pelapukan
4. Tanah-tanah tropis mengandung sekitar 200 ppm
5. Ultisol & Alfisol : < 200 ppm P
6. Andepts umumnya 1000 - 3000 ppm P
7. Vertisol umumnya 20 - 90 ppm P
8. Entisol & Inceptisols: beragam p-totalnya
9. Oxisols umumnya < 200 ppm P
10. …..
1.
2.
3.
4.
5.
P-organik = 20-50 % total P-tanah
Oxisols, Ultisols, Alfisols: P-organik = 60-80% P-total
C:P rasio dalam tanah = 240:1 -- 110:1
N:P rasio dlm tanah = 20:1 -- 9:1
Mineralisasi P-organik sukar diukur, karena ion H2PO4yg dilepaskan ke tanah dengan cepat difiksasi menjadi
bentuk-bentuk P-anorganik
6. Pemupukan N dan P mempercepat mineralisasi Porganik
7. P-organik dlm tanah menjadi sumber P yg penting bagi
tanaman kalau tidak ada pemupukan P.
BAHAN
ORGANIK
SUMBER P
Komponen kualitas bahan organik sebagai sumberP:
1. Nisbah C/N (nilai kritisnya 25-30)
2. Nisbah C/P ( < 200: mineralisasi P
> 300 : imobilisasi P)
3. P-total
4. Kandungan lignin dan polifenol
5. Kapasitas polifenol mengikat protein
6. Indeks jangka-pendek pupuk hijau: C/N, kandungan lignin
dan polifenol
1. Kandungan lignin dan polifenol yang rendah mempercepat laju mineralisasi P
2. Bahan organik dengan kandungan P lebih dari 2500 ppm akan terjadi
mineralisasi P dan menurunkan jerapan P-tanah
3. Lignin merupakan senyawa polimer pd jaringan tanaman berkayu, sulit
dirombak oleh mikroba tanah
Polifenol merupakan senyawa aromatik-hidroksil :
a. Polifenol larut air & Polifenol tdk larut air
b. Polifenol berat molekul rendah & berat molekul tinggi …… tanin
Polifenol mampu mengikat protein dan ensim dari jasad dekomposer, sehingga menghambat
laju dekomposisi bahan organik oleh jasad renik tanah
1.
2.
3.
4.
P - ANORGANIK: Fraksi aktif & Fraksi tidak aktif
Fraksi aktif : Ca-P, Al-P dan Fe-P
Fraksi tdak-aktif : Occluded-P dan Reductant-soluble P
Occluded-P : senyawa Fe-P dan Al-P yang dibungkus oleh
selubung inert.
5. Rs-P : Senyawa P yg dibungkus oleh selubung dari bahan
yang dpt larut pd kondisi anaerobik
6. Transformasi bentuk-bentuk P-tanah dikendalikan pH
7. Ca-P lebih mudah larut dp Fe-P dan Al-P
8. Rezim air sgt berpengaruh thd transformasi P-tanah
9. Kondisi AQUIK ---- Akumulasi Al-P
10. Kondisi USTIK ------ Akumulasi Fe-P
Faktor
Retensi P
dalam tanah
TIPE LIAT
Tanah-tanah liat lebih banyak meretensi & memfiksasi ppupuk daripada tanah berpasir
Liat silikat tipe 1:1 mempunyai kemampuan lebih besar
me-”retensi” P dibanding liat tipe 2:1
Tanah yang kaya liat kaolinitik akan “mengikat” lebih
banyak P -pupuk daripada tanah yang kaya liat tipe 2:1
Adanya liat oksida hidrous dari Fe dan Al juga terlibat
dalam retensi P-pupuk
TIME OF REACTION
Semakin lama P-pupuk kontak langsung dengan tanah akan semakin
besar jumlah retensi & fiksasi P
Hal ini dapat terjadi karena adanya proses dehidrasi dan reorientasikristal yg melibatkan hasil fiksasi P
Implikasi penting adalah waktu pemupukan P dan penempatan pupuk P
dalam tanah.
Bgm pd tanah yg mempunyai kapasitas fiksasi P tinggi ? …………..
Bgm pd tanah yg mempunyai kapasitas fiksasi P rendah? …………
Faktor
Retensi P
dalam tanah
pH TANAH
Kisaran pH tanah yg optimum bagi ketersediaan p-tanah adalah
5.5 - 7.0
Pd tanah dg pH rendah, retensi terjadi karena adanya reaksi
fosfat dengan Fe, Al dan oksida hidratnya.
Pd tanah dg pH tinggi, retensi fosfat terjadi karena reaksi fosfat
dengan Ca dan Mg dan karbonatnya
TEMPERATUR
Tanah di daerah iklim panas (warmer) memfiksasi fosfat lebih banyak dp
tanah-tanah di daerah iklim sedang (temperate). Tanah di daerah iklim
panas ini mengandung lebih banyak oksida-oksida hidrat dari Fe dan Al.
BAHAN ORGANIK
Dekomposisi bahan organik menghasilkan CO2; gas ini bersenyawa dg air
menjadi asam karbonat; asam ini mampu men-dekomposisi mineral primer yang
mengandung fosfat.
Ekstrak humus dari tanah mampu meningkatkan kelarutan fosfat, krn:
1. Pembentukan kompleks phosphohumic yg lebih mudah diambil tanaman
2. Penggantian anion fosfat oleh humat
3. Penyelimutan partikel sesquioksida oleh humus, membentuk selimut protektif
sehingga mereduksi kapasitas fiksasi fosfat
…………………………..
Faktor
Retensi P
dalam tanah
BAHAN ORGANIK Lanjutan …….
Dekomposisi bahan organik menghasilkan anion-anion yang mampu
membentuk senyawa kompleks dengan Fe dan Al, sehingga kationkation ini tidak bereaksi dengan fosfat
Anion-anion organik ini juga mampu melepaskan fosfat yang difiksasi
oleh Fe dan Al
Anion-anion yang efektif menggantikan fosfat tsb adalah sitrat,
oksalat, tartrat, malat, dan malonat.
STATUS FOSFOR dalam TANAH
Tingkat kejenuhan fosfat dalam tanah atau jumlah fosfat yg telah difiksasi oleh
tanah sangat menentukan besarnya fiksasi fosfat dari pupuk P.
Rasio R2O3 : P2O5 mrp ukuran jumlah fosfat yg ada dalam tanah terhadap
jumlah oksida Fe dan Al.
Nilai Rasio yang besar, berarti tanah miskin fosfat atau nilai kejenuhan fosfat
rendah; sehingga fiksasi fosfat dari pupuk P sangat besar
Oleh karenanya tanah-tanah yag dipupuk fosfat dosis tinggi selama bertahuntahun kemungkinan akan:
1. Mereduksi dosis pupuk P saat ini
2. Menggunakan lebih banyak fosfat yg ada dalam tanah
3. Kombinasi keduanya
…………………..
Fiksasi P-pupuk , %
100
80
60
40
20
Pasio R2O3 : P2O5
1. Proses yg mengubah ketersediaan P-tanah yg diukur dengan
pertumbuhan tanaman
2. Transformasi monokalsium fosfat (superfosfat) yg soluble
menjadi Ca-P, Fe-P dan Al-P yg kurang soluble
3. Pada tanah alkalis: Ca-P dan Mg-P yg insoluble
4. Pd tnh masam: Fe-P dan Al-P yg insoluble
5. Al+++ + mono-kalsium fosfat ------ Al(OH)2H2PO4
(liming with phosphorus)
6. Kapasitas fiksasi P = F(oksida Fe dan Al; Aldd)
7. Intensitas Fiksasi P:
Oksida > Oksida > Liat 1:1 > Liat 2:1
amorf
kristalin
Tanah
Liat dominan % Liat
Fixed P (ppm)
Adsorpsi Max.
Inceptisol
Ultisol
Oxisol
Andept
Montmorilonit
Kaolinit
Kaolinit
Alofan
Sumber: NCSU, 1973
27
38
36
11
106
480
531
1050
Pd 0.2 ppm P lrt tnh
83
360
395
670
1. H2PO4- dlm larutan tanah < 10 ppm, dlm tanaman 2000 ppm
2. Konsentrasi optimum unt jagung dan buncis:
0.07 ppm pd tnh berliat Ultisol , Oxisol
0.2 ppm pd tnh berpasir
3. Konsentrasi keseimbangan P dlm larutan tnh akibat aplikasi
pupuk fosfat sgt penting ….. “P-fixation isotherm”:
mengevaluasi derajat fiksasi dan pelepasan P pd suatu saat
4. Mineralogi liat tanah sgt menentukan kapasitas fiksasi P
5. Liat oksida & Alofan > Kaolinit > Montmorilonit
6. Uji tanah untuk P : mengekstraks sejumlah P-tersedia dlm
tanah yg berkorelasi dg respon tanmn thd pemupukan P
7. Tingkat kritis hasil uji tanah sekitar 0.07 - 0.2 ppm P dlm
larutan tanah
REAKSI P
tanah
ALKALINE
PRESIPITASI DIKALSIUM FOSFAT
Pada kondisi Ph tanah yang tinggi dan kaya kalsium, terjadi
pengendapan senyawa-senyawa:
1. Kalsium fosfat: Ca3(PO4)2; CaHPO4
2. Hidroksi-apatit
3. Karbonat-apatit
PRESIPITASI PERMUKAAN PADATAN KALSIUM KARBONAT
Ion-ion fosfat yang kontak dengan permukaan padatan kalsium karbonat akan
diendapkan pd permukaan partikel ini. Hasil akhir dari reaksi ini adalah garamgaram tidak larut dari kalsium, fosfat, dan mungkin CO3= atau OHReaksi retensi fosfat oleh liat-liat yang jenuh kalsium: Liat-Ca-H2PO4
Tiga faktor penting:
1. Aktivitas Ca++
2. Jumlah dan ukuran partikel CaCO3 bebas
3. Jumlah liat yang ada dlm tanah
…………………..
P-aded (ppm)
1200
Oxisol, 45% liat
Sumber: Fox, 1974
1000
Andept
800
600
Ultisol , 38% liat
400
200
Tnh Montmorilonit, 40% liat
0.001
0.01
0.05 0.1 0.2
P dlm larutan tanah, ppm
1.0
Tanaman
Hasil, t/ha
P-removal, kg/ha
1. Jagung
Biji
Jerami
Biji
Jerami
: 1.0
: 1.5
: 7.0
: 7.0
6
3
20
14
2. Padi
Biji
Jerami
Biji
Jerami
: 1.5
: 1.5
: 8.0
: 8.0
7
1
32
5
3. Nanas
Buah
: 12.5
4. Tebu 2 th
Above ground: 100
300
Sumber: Sanchez, 1976.
2.3
20
35
Hasil relatif (%)
100
80
Ubijalar: toleran
tanah miskin P
60
40
20
Jagung: intermediate
Lettuce: In-tolerant
0.003 0.006
0.050 0.100 0.200 0.400
P- larutan tanah, ppm
1.600
Tanaman
1.
2.
3.
4.
5.
6.
7.
8.
P-larutan tnh yg menghasilkan 95% hasil maks., ppm
Lettuce
Tomat
Cucumber
Kedelai (vegetable)
Ubijalar
Jagung
Sorghum
Kubis
Sumber: Fox et al. (1974)
0.40
0.25
0.20
0.20
0.10
0.60
0.50
0.04
Tanaman
1.
2.
3.
4.
5.
6.
7.
8.
Internal P Requirement, %P
Stylosanthes humilis
Centrosema pubescens
Desmodium intortum
Digitaria decumbens
Panicum maximum
Pennisetum clandestinum
Paspalum dilatatum
Sumber: Andrew & Robins (1969, 1971)
0.17
0.16
0.22
0.16
0.19
0.22
0.25
TEKNOLOGI PEMUPUKAN FOSFAT :
1. Respon pupuk P sgt tinggi pada Oxisol, Ultisol, andepts, Vertisols
2. Dosis pupuk P = F (jenis tanaman, tanah, cara aplikasi, musim)
3. Dosis Rekomendasi Jagung, kedelai, Tebu: 100 - 150 kg P2O5/ha
4. Kapasistas fiksasi P tanah menentukan cara aplikasi pupuk P:
Disebar, ditugal, digarit, pd lubang tanam, dll
5. Pada tanah yg memfiksasi P ada dua strategi:
1. Dosis medium, digarit, setiap musim tanam
2. Dosis tinggi unt menjenuhi kapasitas fiksasi P-tanah, dan efek
residunya berlangsung beberapa tahun
6. Pupuk P yg baik harus mengandung 40-50 % P dlm bentuk larut air ,
untuk memenuhi kenbutuhan awal pertumbuhan tanaman
7. Aplikasi kapur & silikat mampu menurunkan fiksasi P dlm tanah
8. Pengapuran hingga pH 5.5 - 6.0 umumnya meningkatkan ketersediaan
P dalam tanah, mengurangi fiksasi P
Hasil biomasa , %
100
Dikapur hingga pH = 5.5
80
Tdk dipakur pH= 4.8
60
40
Tingkat kritis
20
0
115
230
Pemupukan P (ppm P)
Sumber: Mendez-Lay (1974), Tnh Oxisol.
460
Kapasitas fiksasi P tanah sngt tinggi, alternatif pengelolaan:
1. Kombinasi cara aplikasi pupuk P: ditugal/digarit dg sebar
2. Batuan-fosfat larut sitrat
3. Aplikasi kapur atau Ca-silikat unt ngurangi fiksasi P
4. Kultivar tanaman yg toleran thd larutan tanah yg miskin
fosfat
5. Pertimbangan biaya pupuk & pemupukan.
PERILAKU
PUPUK P
dalam
TANAH
AMMONIUM FOSFAT
Dalam tanah, senyawa ammonium fosfat akan bergerak ke luar dari
granula pupuk; kalau dalam tanah terdapat banyak Ca++, maka akan
terbentuk dikalsium fosfat.
MAP : Mono ammonium fosfat (larutan jenuh punya pH 4.0)
DAP : Di ammonium fosfat ( larutan jenuhnya punya pH 9.0)
PRESIPITASI PERMUKAAN PADATAN KALSIUM KARBONAT
Ion-ion fosfat yang kontak dengan permukaan padatan kalsium karbonat akan
diendapkan pd permukaan partikel ini. Hasil akhir dari reaksi ini adalah garamgaram tidak larut dari kalsium, fosfat, dan mungkin CO3= atau OHReaksi retensi fosfat oleh liat-liat yang jenuh kalsium: Liat-Ca-H2PO4
Tiga faktor penting:
1. Aktivitas Ca++
2. Jumlah dan ukuran partikel CaCO3 bebas
3. Jumlah liat yang ada dlm tanah
…………………..
Granula Monokalsium fosfat:
MONO
KALSIUM
FOSFAT
H2O
H2O
H2O
Consentrated medium, pH 1.5, dimana CaH2PO4 dan CaHPO4
bergerak ke luar
Melarutkan Fe, Al, dan Mn
Pembentukan besi-fosfat, Al-fosfat, Mn-fosfat yg mengendap
MnPO4
FePO4
AlPO4
NILAI
KOMPARATIF
PUPUK
FOSFAT
1. Bentuk fosfat yang tersedia bagi tanaman ada dua, yaitu Fosfat-LarutAir dan Fosfat-Larut-Sitrat.
Namun demikian respon tanaman
terhadap kedua bentuk fosfat ini sangat beragam.
2. Untuk mendapatkan hasil maksimum bagi tanaman semusim yg sistem
perakarannya terbatas, umumnya diperlukan pupuk P yang banyak
mengandung fosfat-larut-air.
3. Untuk tanaman perennial yang sistem perakarannya luas (ekstensif),
tingginya tingkat kelarutan fosfat dalam air (>60%) tidak menjadi
faktor penting.
4. Untuk tanaman jagung, terutama pada saat awal pertumbuhannya,
memerlukan fosfat yang larut air.
5. Kalau jumlah pupuk fosfat terbatas, respon tanaman paling baik akan
diperoleh kalau pupuk fosfat tsb mudah larut air dan penempatan
pupuk di dekat benih atau bibit. Hal seperti ini sangat penting bagi
tanah-tanah yang miskin fosfat.
6. Pada tanah masam hingga netral, pupuk P granuler yg mudah larut air, biasanya lebih efektif
daripada pupuk P yang berupa bubukan, kalau pupuk dicampur dg tanah. Pada batas-batas
kondisi tertentu, semakin besar ukuran granula pupuk, efektifitasnya semakin baik.
7. Pada tanah netral hingga masam, “band application” bubukan pupuk P yg mudah larut air
akan memberikan hasil yg lebih baik dibandingkan dg pemakaian pupuk yg dicampur
dengan tanah.
NILAI
KOMPARATIF
PUPUK
FOSFAT
8. Pada tanah-tanah berkapur, pupuk fosfat larut air yg
berbentuk granula seringkali memberikan hasil lebih baik.
Pupuk fosfat-nitrat granuler yg kelarutan airnya rendah
(<50%) tidak cocok untuk tanah-tanah berkapur.
9. Hasil terbaik dapat diperoleh dengan bahan-bahan yg
kelarutan airnya rendah, kalau diberikan dalam bentuk
bubukan dan dicampur dengan tanah berkapur
10. Monoammonium fosfat (MAP) umumnya lebih cocok untuk tanahtanah berkapur dibandingkan dengan DAP
11. Pupuk fosfat yg sukar larut air, efektivitasnya menurun dengan
semakin besarnya ukuran partikel (granula) pupuk.
12. Pupuk fosfat proses thermal, kalau ditumbuk halus, dapat menjadi
sumber P yang sesuai untuk banyak tanaman pada tanah masam;
tetapi umumnya tidak berhasil untuk tanah netral dan alkalin.
13. Respon maksimum thd pemupukan P tidak akan terjadi kalau tidak dibarengi dengan
penambahan sejumlah unsur lain (termasuk unsur hara sekunder dan mikro).
Hasil-hasil penelitian menunjukkan bahwa penggunaan P oleh tanaman dapat diperbaiki
oleh adanya sulfat dan ammonium di dalam bahan pupuk.
MEKANISME PENJERAPAN FOSFAT
“Adsorption” terjadi kalau
ion fosfat terusir dari
larutan tanah dan menjadi
terikat pada permukaan
partikel tanah. Kalau ion
fosfat yang terjerap itu
kemudian mengalami
“difusi” ke dalam padatan,
maka ia disebut
“terserap”.
Some authors use the term
“penetrated phosphate” to
avoid confusion between
adsorbed and absorbed;
“sorption”
covers the combined
processes.
Diunduh dari:
……… 27/3/2013
ABSORPSI & OKLUSI P-TANAH
larutan
tanah
Mineral
tanah
Absorpsi Pterjerap ke
dalam mineral
tganah (a)
dan
Selimut
oksida Fe
atau Al
Mineral
tanah
P terjebak
oleh selimut
Diunduh dari:
……… 27/3/2013
Oklusi lebih
lanjut P-terjerap
b)
Dinamika P-tanah, termasuk tranformasi dan perilaku P dari pupuk
fosfat.
Pupuk
kimia
PO4
terjerap
PO4
mengendap
Fe, Al, Ca
Mineral
tanah
Tanaman
Tanaman
Sistem
Tanah
Binatang
Rabuk
Kompos
Humus
PO4 terlarut
Larutan Tanah
BO hidup ----- BO mati
Erosi tanah
Pergerakan P-tanah snagat
terbatas, sehingga
penempatan pupuk P dalam
tanah snagat kritis dalam
mencapai efisiensi
serapannya.
Banded applications of
fertilizer P have proven the
most effective thereby
minimizing surface contact
with the soil which tends to
decrease the solubility of the
applied P.
Faktor lain yg berpengaruh
adalah kesehatan tanaman,
tdk ada penyakit, dan tanah
yg hangat.
Diunduh dari: http://www.extension.org/pages/9873/phosphorus-p ……… 27/3/2013
SIKLUS P DALAM TANAH (Dean Hesterberg, 2010)
Bahan pembenah
(0.8-2.4% Pt
(pupuk, rabuk,
biosolid)
P biomasa tanaman
(0.2-0.6% Pt bagian
di atas tanah)
P-panen
tanaman
P-runoff (<0.15% Pt)
Terlarut dan partikulat
Residu P-organik
(3% dari Pt)
P-humus
(15-60% dari Pt)
P-biomasa
mikroba
(0.4 – 7.5% dari
Pt)
P-mineral
Ca-fosfat
Fe-fosfat
Al-fosfat
P-terjerap
P-teroklusi
PO4-Fe-oksida
PO4-Al-oksida
PO4-Fe Al-BO
Diunduh dari: http://www.sciencedirect.com/science/article/pii/S0166248110340116 ……… 27/3/2013
Bentuk-bentuk P yang ada dalam tanah.
P dalam tanah dapat
dikelompokkan menjadi
tiga “pool” yg berbeda
tingkat ketersediaannya
bagi tanaman.
P-labil
P-larutan
P
Tidak labil
These pools are the
readily available P (soil
solution), the pool of P
that is rapidly released
from the soil to replenish
the soil solution (labile
pool), and the relatively
slowly available P (nonlabile)
Diunduh dari: http://www.grdc.com.au/Research-and-Development/GRDC-Update-Papers/2009/02/THE-SCIENCE-OF-PHOSPHORUSNUTRITION-FORMS-IN-THE-SOIL-PLANT-UPTAKE-AND-PLANT-RESPONSE ……… 27/3/2013
SIKLUS P-TANAH
Panen
Tanaman
Sisa
panen
Aplikasi P
Rabuk
Stabil
Labil
Tanaman
P-larutan
Aplikasi
Pupuk P
Labil
P- Uji Tanah
P-Organik
P-Anorganik
Stabil
(Sumber:
Sharpley and
Sheffield,
Livestock and
Poultry
Environmental
Stewardship
Curriculum)
Diunduh dari: http://passel.unl.edu/pages/informationmodule.php?idinformationmodule=1118084123&topicorder=5&maxto=7 ……… 27/3/2013
Kesetimbangan P dalam tanah
Stabil ---- Labil
P - larutan
P-rabuk sebagian besar P-labil + P-larutan
Stabil ---- Labil
P - larutan
Kalau P diserap
ke dalam tanah
setelah aplikasi
pupuk,
risiko
kehilangan Plarut ke dlaam
runoff akan
semakin
berkurang
(menurun)
dnegan waktu.
P-rabuk bereaksi dnegan bahan organik tanah dan senyawasenyawa Fe, Al dan Ca fosfat menjadi kurang tersedia
Stabil ---- Labil
P - larutan
(Sumber:
Image courtesy
of Charles
Wortmann)
Diunduh dari: http://passel.unl.edu/pages/informationmodule.php?idinformationmodule=1118084123&topicorder=5&maxto=7 ……… 27/3/2013
SIKLUS P DALAM TANAH
Tanaman
Sisa Tanaman
Akar Tanaman
Batuan
fosfat
Porganik
sukar
lapuk
P larut air
Asam
fosfat dg
Ca, Al, Fe
Oksida,
dan asam
fosfat
dalam liat
Reaksi
penjerapan
(adsorpsi) asam
fosfat
Porganik
mudah
lapuk
P-organik
agak
sukar
lapuk
P-organik
stabil
bergabung
dengan
liat
SUMBER : "Kikan Kagaku-sosetsu, 4" (Quaterly Chemistry 4), Science Society of Japan, ed., "Chemisory of
Soil"
Diunduh dari: http://www.env.go.jp/en/wpaper/1995/eae240000000010.html ……… 27/3/2013
Apakah P-tanah itu?
Tanaman
yang
sedang
tumbuh
Pupuk
P-anorganik
(P-terikat pd
mineral)
Kehilangan P
melalui
pencucian
P-larutan:
Rabuk
P-Organik
(Bahan
organik)
Kehilangan P
melalui erosi
tanah
Phosphorus (P), unsur hara
esensial bagi tanaman. Unsur
hara ini sangat kritis karena
konsentrasinya dalam tanah
snagat rendah ( 600 ppm total P)
dan kelarutannya snagat rendah
(rata-rata 0.05 mg P L-1 dalam
larutan tanah).
Soil P exists in inorganic and
organic forms. Inorganic forms
are associated with amorphous
and crystalline aluminium and
iron compounds in acid soils and
calcium compounds in alkaline
soils.
Bentuk-bentuk P-organik
berhubungan dengan bahan
organik dalam tanah.
Diunduh dari: http://www.gnb.ca/0173/30/0173300016-e.asp ……… 27/3/2013
Options for managing soil phosphorus supply
Dr. Ann McNeill
School of Earth & Environmental Sciences, University of Adelaide, South Australia. 21st July
2008
Maintenance of available phosphorus (P) levels in soil is a problem faced
by all producers. There are potential agronomic strategies to assist in
sustainable management of the soil P resource in pasture-based farming
enterprises. Firstly some background information about the P cycle is
provided and the role of soil organic matter and microbes is highlighted.
Tiga alternatif pengelolaan P adalah;
1. Impor P sebagai pupuk, yaitu pupuk mineral atau organik,
2. Praktek untuk meningkatkan siklus P tanah untuk mendorong
sinkronisasi pelepasan dan serapan P-tersedia oleh tanaman
3. Memaksimumkan efisiensi pemanfaatan P oleh tanaman.
Diunduh dari: http://www.grasslands.org.au/resources/Articles/NewsletterArticle1.html ……… 27/3/2013
Options for managing soil phosphorus supply
Dr. Ann McNeill
School of Earth & Environmental Sciences, University of Adelaide, South Australia. 21st July
2008
Soil P cycle - pools and pathways. Modified
from [McLaughlin et al. 1999, 1]
ekskresi akar
CADANGAN LARUTAN TANAH
P -Organik + anorganik
Mineralisasi
Imobilisasi
Penyerapan akar
Cadangan
biomasa
mikroba
Pengendapan
Pertukaran
kontak
Adsorpsi
Desorpsi
Mineralisasi Nonasimilatory
Asimilasi
Pi dapat ditukar
Po Labil
Pi tidak-dapat ditukar
MINERAL
Po tidak-Labil
FASE ORGANIK
Dekomposisi
BO
Diunduh dari: http://www.grasslands.org.au/resources/Articles/NewsletterArticle1.html ……… 27/3/2013
The value of phosphorus in crop stubble
Sarah Noack1, Mike McLaughlin, Ron Smernik, Therese McBeath and Roger Armstrong
1The University of Adelaide
P
dalam
Tanaman
P
dalam
Seresah
sisa panen
P larutan
P tdk tersedia
P mikroba
Phosphorus within the
stubble can be released
directly to soil as
soluble P (where it can
be used immediately
by the crop or
chemically fixed onto
the soil)
atau
Diserap oleh mikroba
dan selanjutnya
dilepaskan kembali ke
tanah dalam waktu
mendatang.
P labil
Diunduh dari: http://www.grdc.com.au/Research-and-Development/GRDC-Update-Papers/2012/02/The-value-of-phosphorus-in-crop-stubble
……… 27/3/2013
KETERSEDIAAN P DALAM TANAH
Fosfat mudah diikat dna menjadi bagian dari senyawa kalsium, besi
dan aluminum dalam tanah:
1. Only 10 - 30% of phosphate fertilizer is used in the year it is
applied
2. 1/3 to 1/2 of the phosphate (P) fertilizer applied may never be
recovered
3. P is most available in soils with a neutral pH (it is quickly tied
up with pHs above or below)
4. Tanah-tanah yg kaya debu atau liat mengikat lebih banyak P
5. Semakin rendah lengas tanah = semakin rendah ketersediaan P
6. Semakin rendah suhu tanah = semakin rendah ketersediaan P
Diunduh dari: http://www.bioag.novozymes.com/en/products/canada/aboutphosphate/soil-phosphate/availability-in-coldsoils/Pages/default.aspx ……… 27/3/2013
KETERSEDIAAN P DALAM TANAH
Ion ortofosfat primer:
H2PO4- (pH<7.0)
Ion ortofosfat sekunder:
HPO4= (pH>7.0)
P-larutan berbentuk
ortofosfat. Molekul
ini terdiri atas atom
P (bulatan kuning)
dikelilingi oleh
empat atom oksigen
(bulatan merah).
P - larutan
Bentuk yg lazim ditentukan oleh pH
tanah, kedua bentuk ion seimbang pd
kondisi netral
Diunduh dari: http://www.bioag.novozymes.com/en/products/canada/aboutphosphate/soil-phosphate/availability-in-coldsoils/Pages/default.aspx ……… 27/3/2013
Hubungan antara serapan P-tanaman dgn P-tersedia dalam tanah
akibat aplikasi TSP dan PR ke tanah masam
When a water-soluble P
fertilizer, e.g. TSP, is applied to
acid soil containing oxides of
iron (Fe) and aluminium (Al),
reaction products in the form of
Fe-Al-P are the sources of
available P through
desorption/dissolution processes
for uptake by the plant.
Kalau jumlah P yg terekstraks
oleh uji tanah (k1’) seimbang
(korelasinya kuat) dengan
jumlah P yg diserap oleh
tanaman (k1) atau hasil
tanaman, maka uji tanah ini
cocok untuk kalibrasi
rekomendasi dosis pupuk
berdasar P-larut air.
Diunduh dari: http://www.fao.org/docrep/007/y5053e/y5053e0b.htm ……… 27/3/2013
IKTISAR
FOSFAT TANAH
1. P dalam tanah berbentuk organik dan an-organik.
Konsentrasi P-anorganik (H2PO4- dan HPO4=) dalam
larutan tanah merupakan faktor sangat penting yg
menentukan ketersediannya bagi tanaman
2. Konsentrasi ion fosfat dlm larutan tanah ditentukan oleh
kecepatan reaksi imobilisasi biologis dan reaksinya dg fraksi
mineral tanah. Tanah berliat (terutama liat tipe 1:1 dan
oksida hidrous Fe an Al) memfiksasi ortofosfat menjadi
bentuk yg tidak tersedia bagi tanaman.
3. Tanah berkapur umumnya mempunyai ketersediaan P rendah. Ion
fosfat dijerap pada permukaan partikel halus kalsium karbonatdan
selanjutnya dikonversi menjadi bentuk apatit yg tidak larut, atau
mengalami proses pengendapan langsung dari larutan tanah menjadi
kalsium fosfat.
4. Ketersediaan pupuk fosfat larut air dapat ditingkatkan dengan jalan menempatkan bahan
pupuk secara “banding” dlm tanah (ditugal atau digarit). Hasil yag serupa dapat diperoleh
dengan jalan granulasi bahan pupuk.
5. Terminologi khusus untuk pupuk fosfat adalah: Larut air, Larut sitrat, Tersedia, dan Total
Fosfat.
IKTISAR
FOSFAT TANAH
6. Pupuk fosfat dapat diklasifikasikan
berdasarkan proses pembuatannya,
menjadi: Heat-processed phosphate, dan
Acid-treated Phosphate.
7.
Reaksi pupuk fosfat larut air dengan berbagai
komponen tanah menghasilkan “produk reaksi pupuk - tanah”.
Kelarutan hasil reaksi inilah yang menentukan ketersediaan
fosfat bagi tanaman
8.
Kandungan air tanah sangat menentukan efektifitas dan
laju ketersediaan pupuk fosfat. Pada kondisi air tanah
kapasitas lapangan sekitar 50-80 % fosfat larut air dapat
bergerak ke luar dari granula pupuk dalam periode 24 jam.
UJI P-TANAH:
PRINSIP DAN ANALISISNYA
Soil Test Phosphorus: Principles and Overview
J. Thomas Sims, University of Delaware
The fundamental goal of soil P testing has always been to identify the
“optimum” soil test P concentration required for plant growth. The need
for additional fertilization or manuring, and the economic return on an
investment in fertilizer P, could then be predicted.
Menurut Sims et al. (1998), tujuan lain dari uji P-tanah adalah :
1. Menentukan “indeks” kapasitas tanah mensuplai P, shg dapat
mengestimasi waktu sebelum melakukan pemupukan fosfat
diperlukan lagi.
2. Mengelompokkan tanah, dalam hal respon ekonomis terhadap pupuk
P, berdasarkan sifat fisika dna kimia tanah,
3. Mengidentifikasi apakah tanah berkelebihan P sehingga menjadi
sumber pencemaran bagi perairan.
Diunduh dari: https://secure.hosting.vt.edu/...vt.../Methods_of_P_Analysis_2000.pd... ……… 27/3/2013
Soil Test Phosphorus: Principles and Overview
J. Thomas Sims, University of Delaware
Menurut Bray (1948), uji P-tanah yg bermanfaat secara agronomis harus
mempunyai karakteristik:
1. Uji tanah harus mampu mengekstraks semua atau sebagian P-tersedia
dalam tanah yang beragam sifat kimia dan mineralogisnya.
2. Uji tanah harus akurat dan cepat.
3. The P extracted by the soil test should be well correlated with plant P
concentration, plant growth, and the response of the plant to added P
in fertilizers or manures.
4. Uji tanah harus dapat secara akurat mendeteksi perbedaan
konsnetrasi P-tanah akibat pemupukan sebelumnya.
Diunduh dari: https://secure.hosting.vt.edu/...vt.../Methods_of_P_Analysis_2000.pd... ……… 27/3/2013
Soil Test Phosphorus: Principles and Overview
J. Thomas Sims, University of Delaware
Komponen mendasar dalam program uji P-tanah.
Komponen Uji
P tanah
Definisi dan pertimbangan umum
Sampling Tanah
Collection of a sample that accurately represents the area of interest is the first
step in an effective soil testing program. Soil samples are normally collected from
the “topsoil” or “plow layer” (0-20 cm depth), although this may vary with type of
crop and intent of the test. In most cases ~20-25 individual soil cores are collected
from a field that is no larger than 10-15 hectares. These cores are then composited
to produce one sample that is submitted to the laboratory for analysis. Soil
sampling patterns should reflect natural differences in soils (e.g., soil series) and
any management practices or historical activities likely to affect soil test results
(e.g., crop rotation, manuring, tillage practice).
Sampel tanah:
Penanganan dan
penyiapannya
Care should be taken during soil sample handling to avoid contamination from
sampling and mixing devices. After collection, soil samples should be submitted
as soon as possible to the laboratory where they are normally air-dried and ground
or crushed to pass a 2mm sieve prior to analysis. Providing as much information
as possible with the sample (e.g., previous fertilizer use, intended management
plans, soil series) helps to ensure an accurate recommendation.
Diunduh dari: https://secure.hosting.vt.edu/...vt.../Methods_of_P_Analysis_2000.pd... ……… 27/3/2013
Soil Test Phosphorus: Principles and Overview
J. Thomas Sims, University of Delaware
Komponen mendasar dalam program uji P-tanah.
Komponen Uji
P tanah
Definisi dan pertimbangan umum
Analisis sampel
tanah
From an agronomic perspective, the purpose of soil analysis is to chemically
“extract” the amount of nutrient from the soil that is proportional to that which
will be available to the crop during the growing season. Since many different soil
testing methods exist, it is vital that the analytical procedures selected are
appropriate to the geographic region of interest and for the intended use of the
soil.
Interpretasi hasil The ultimate goal of soil testing is to provide the user with a recommendation as
to the likelihood that the application of nutrients in fertilizers or manures will
analisis
provide a profitable increase in crop response. Recommendations based on soil
testing results are developed using crop response data that have been obtained
within a state or region with similar soils, cropping systems, and climatic
conditions. Therefore, it is important to submit samples to a laboratory that is
familiar with the crops to be grown and the soils and management practices that
will be used.
Diunduh dari: https://secure.hosting.vt.edu/...vt.../Methods_of_P_Analysis_2000.pd... ……… 27/3/2013
Soil Test Phosphorus: Bray and Kurtz P-1
J. Thomas Sims, University of Delaware
The Bray and Kurtz P-1 soil test phosphorus (P) method was developed by Roger H.
Bray and Touby Kurtz of the Illinois Agricultural Experiment Station in 1945 and is now widely
used in the Midwestern and North Central United States (Bray and Kurtz, 1945; Frank et al.,
1998). Phosphorus extracted by the Bray and Kurtz P-1 method has been shown to be wellcorrelated with crop yield response on most acid and neutral soils in these regions. For acid soils,
the fluoride in the Bray and Kurtz extractant enhances P release from aluminum phosphates by
decreasing Al activity in solution through the formation of various Al-F complexes. Fluoride is
also effective at suppressing the readsorption of solubilized P by soil colloids. The acidic nature
of the extractant (pH 2.6) also contributes to dissolution of available P from Al, Ca, and Fe-bound
forms in most soils.
1.
2.
3.
4.
Uji tanah dnegan metode Bray tidak cocok untuk:
Tanah-tanah liat yang kejenuhan basanya cukup tinggi,
Tanah-tanah lempung-liat-berdebu atau yg lebih halus dengan pH tinggi atgau
tanah berkapur (pH > 6.8) atau kejenuhan basanya tinggi,
Tanah-tanah yang mempunyai kalsium karbonat setara > 7% kejenuhan basa,
Tanah-tanah yang kaya kapur ( > 2% CaCO3).
Diunduh dari: https://secure.hosting.vt.edu/...vt.../Methods_of_P_Analysis_2000.pd... ……… 27/3/2013
Soil Test Phosphorus: Bray and Kurtz P-1
J. Thomas Sims, University of Delaware
In soils such as these, the acidity of the extracting solution can be neutralized unless
the ratio of extractant:soil is increased considerably.
Additionally, CaF2, formed from the reaction of soluble Ca+2 in the soil with F- added
in the extractant, can react with and immobilize soil P.
Both types of reactions reduce the efficiency of P extraction and result in low soil test P
values.
Pengekstraks Bray & Kurtz dapat melarutkan P dari batuan fosfat, sehingga tidak
boleh dipakai pada tanah-tanah yang baru diberi bahan-bahan pembenah ini, karena
akan mengakibatkan over-estimate P-tersedia..
Nilai-nilai P ( Bray & Kurtz P-1) sebesar 25 - 30 mg P/kg tanah seringkali dianggap
optimum bagi pertumbuhan tanaman, meskipun Holford (1980) melaporkan nilai kritis
yg lebih rendah untuk tanah-tanah yg daya buffernya tinggi.
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Soil Test Phosphorus: Bray and Kurtz P-1
J. Thomas Sims, University of Delaware
Peralatan lab:
1.
2.
3.
4.
5.
6.
Ayakan No. 10 (diameter lubang 2 mm)
Standard 1 g and 2 g stainless steel soil scoops
Automatic extractant dispenser, 25 mL capacity
Extraction vessels, such as 50 mL Erlenmeyer flasks, and filter funnels (9 and 11
cm) and racks
Rotating or reciprocating shaker with a capability of 200 excursions per minute
(epm)
Whatman No. 42 or No. 2 (or equivalent) filter paper, 9 to 11 cm. (Acid resistant
filter paper may be needed if using an automated method for determining P
concentration by intensity of color. Bits of filter paper may cause an obstruction in
the injection valves.)
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Soil Test Phosphorus: Bray and Kurtz P-1
J. Thomas Sims, University of Delaware
Reagen = Pereaksi:
Bray and Kurtz P-1 Extracting Solution (0.025 M HCl in 0.03 M
NH4F):
Dissolve 11.11 g of reagent-grade ammonium fluoride (NH4F) in
about 9 L of distilled water. Add 250 mL of previously
standardized 1M HCl and make to 10 L volume with distilled
water.
Dicampur secara merata.
pH larutan yg dihasilkan harus pH 2.6 ± 0.05.
Penyesuaian pH dilakukan dnegan menggunakan HCl atau
NH4OH.
Simpan dalam polyethylene-carboys hingga saatnya digunakan.
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Soil Test Phosphorus: Bray and Kurtz P-1
J. Thomas Sims, University of Delaware
Prosedur kerja :
1.
2.
3.
4.
5.
Scoop or weigh 2 g of soil into a 50 mL Erlenmeyer flask, tapping the scoop on the
funnel or flask to remove all of the soil from the scoop.
Add 20 mL of extracting solution to each flask and shake at 200 or more epm for
five minutes at a room temperature at 24 to 27oC
If it is necessary to obtain a colorless filtrate, add 1 cm3 (~200 mg) of charcoal
(DARCO G60, J. T. Baker, Phillipburg, NJ) to each flask.
Menyaring ekstraks dengan Kertas saring Whatman No. 42. Ulangi kembali
penyaringan kalau filtratnya belum jernih.
Menganalisis P dengan colorimetry atau spectroscopy dengan menggunakan
larutan blanko dan standar yang disiapkan dalam larutan pengekstraks Bray P-1.
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Soil Test Phosphorus: Bray and Kurtz P-1
J. Thomas Sims, University of Delaware
Perhitungan:
P yg terekstraks dnegan metode Bray & Kurtz P-1 dihitung :
P-terekstraks Bray & Kurtz P – 1 (mg P/kg tanah ) =
(CP x [0.020 L ekstraks] ) / 0.002 kg tanah
dimana: CP = Konsentrasi P dalam ekstraks Bray & Kurtz P-1, mg/L .
References:
1. Bray R.H., and L.T. Kurtz. 1945. Determination of total, organic and available forms of phosphorus in soils. Soil
Sci. 59:39-45.
2. Frank, K.D. Beegle, and J. Denning. 1998. Phosphorus. p. 21-30. In J. R. Brown (ed.) Recommended Chemical
Soil Test Procedures for the North Central Region. North Central Reg. Res. Publ. No. 221 (revised).
3. Holford, I.C.R. 1980. Greenhouse evaluation of four phosphorus soil tests in relation to phosphate buffering and
labile phosphate in soils. Soil Sci. Soc. Am. J. 44:555-559.
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Soil Test Phosphorus: Olsen P
J. Thomas Sims, University of Delaware
The “Olsen P” or sodium bicarbonate soil test phosphorus (P) method was developed
by Sterling R. Olsen and co-workers in 1954 (Olsen et al., 1954) to predict crop
response to fertilizer P inputs on calcareous soils. It is primarily used in the North
Central and western United States.
Metode ekstraksi P-Olsen cocok untuk tanah-tanah berkapur, terutama yang
mempunyai > 2% calcium carbonate, tetapi juga cukup efektif untuk tanah-tanah
masam (Fixen and Grove, 1990).
The method is based on the use of the HCO3-, CO3-3 and OH- in the pH 8.5, 0.5M
NaHCO3 solution to decrease the solution concentrations of soluble Ca2 by
precipitation as CaCO3 and soluble Al3+ and Fe+3 by formation of Al and Fe
oxyhydroxides, thus increasing P solubility.
Peningkatan muatan negatif permukaan dan/ atau penurunan jumlah tapak sorpsi pada
permukaan oksida Fe dan Al pada kondisi pH tinggi juga memicu desorpsi P-tersedia
ke dalam larutan.
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Soil Test Phosphorus: Olsen P
J. Thomas Sims, University of Delaware
Nilai P-Olsen sebesar 10 mg P/kg umumnya dianggap optimum bagi
pertumbuhan tanaman.
This is lower than the critical values used for the Bray and Kurtz P-1,
Mehlich 1 and Mehlich 3 soil tests because the Olsen extractant removes
less P from most soils than these acidic extractants.
Kuo (1996) stated that proper interpretation of Olsen P results for soils
with diverse properties requires some information on soil P sorption
capacity.
Menurut Schoenau dan Karamanos (1993), harus hati-hati menggunakan
uji P-olsen ini untuk membandingkan ketersediaan P dalam tanah-tanah
yg beragam kimiawi P nya.
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Soil Test Phosphorus: Olsen P
J. Thomas Sims, University of Delaware
Peralatan Lab:
1.
2.
3.
4.
5.
6.
Ayakan No. 10 (diameter lubang 2 mm)
Standard 1 g and 2 g stainless steel soil scoops
Automatic extractant dispenser, 25 mL capacity
Extraction vessels, such as 50 mL Erlenmeyer flasks, and filter funnels (9 and 11
cm) and racks
Rotating or reciprocating shaker with a capability of 200 excursions per minute
(epm)
Whatman No. 42 or No. 2 (or equivalent) filter paper, 9 to 11 cm. (Acid resistant
filter paper may be needed if using an automated method for determining P
concentration by intensity of color. Bits of filter paper may cause an obstruction in
the injection valves.)
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Soil Test Phosphorus: Olsen P
J. Thomas Sims, University of Delaware
Pereaksi - Reagen:
Olsen P Extracting Solution (0.5M NaHCO3, pH 8.5): Dissolve 420 g
commercial- grade sodium bicarbonate (NaHCO3) in distilled water and
make to a final volume of 10 L.
Note that a magnetic stirrer or electric mixer is needed to dissolve the
NaHCO3. Adjust extracting solution pH to 8.5 with 50% sodium
hydroxide.
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Soil Test Phosphorus: Olsen P
J. Thomas Sims, University of Delaware
Prosedur:
1.
2.
3.
4.
5.
Scoop or weigh 1 g of soil into a 50 mL Erlenmeyer flask, tapping the scoop on the
funnel or flask to remove all of the soil from the scoop.
Add 20 mL of extracting solution to each flask and shake at 200 or more epm for
30 minutes at a room temperature at 24 to 270C
If it is necessary to obtain a colorless filtrate, add 1 cm3 (~200 mg) of charcoal
(DARCO G60, J. T. Baker, Phillipburg, NJ) to each flask.
Filter extracts through Whatman No. 42 filter paper or through a similar grade of
paper. Refilter if extracts are not clear.
Analyze for P by colorimetry or inductively coupled plasma emission spectroscopy
using a blank and standards prepared in the Olsen P extracting solution.
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Soil Test Phosphorus: Olsen P
J. Thomas Sims, University of Delaware
Perhitungan:
P terekstraks Olsen (mg P/kg tanah) =
[Konsentrasi P dalam ekstraks Olsen, mg/L ] x [ 0.020 L ekstrak ÷ 0.001
kg tanah]
References:
1. Fixen, P.E. and J.H. Grove. 1990. Testing soils for phosphorus. p. 141-180. In R.L. Westerman (ed.) Soil
Testing and Plant Analysis. SSSA, Madison, WI.
2. Kuo, S. 1996. Phosphorus. p. 869-919. In D.L. Sparks. (ed.). Methods of Soil Analysis: Part 3- Chemical
Methods. SSSA, Madison, WI.
3. Olsen, S.R., C.V. Cole, F.S. Watanabe, and L.A. Dean. 1954. Estimation of available phosphorus in soils
by extraction with sodium bicarbonate. USDA Circular 939. U.S. Government Printing Office,
Washington D.C.
4. Schoenau, J.J. and R.E. Karamanos. 1993. Sodium bicarbonate extractable P, K, and N. p. 51-58. In M.
R. Carter (ed.) Soil Sampling and Methods of Analysis. Can. Soc. Soil Sci., Ottawa, Ontario.
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Soil Test Phosphorus: Mehlich 1
J. Thomas Sims, University of Delaware
The Mehlich 1 soil test for phosphorus (P), also known as the dilute double acid or North
Carolina extractant, was developed in the early 1950s by Mehlich and his coworkers (Mehlich,
1953; Nelson et al. 1953). In the United States the Mehlich 1 procedure is primarily used in the
southeastern and mid-Atlantic states as a multi-element extractant for P, K, Ca, Mg, Cu, Fe, Mn,
and Zn. The Mehlich 1 extracts P from aluminum, iron, and calcium phosphates and is best suited
to acid soils (pH < 6.5) with low cation exchange capacities (< 10 cmol/kg) and organic matter
contents (< 5%).
Kuo (1996) reported that the Mehlich 1 soil test was unreliable for calcareous or alkaline soils
because it extracts large amounts of nonlabile P in soils with pH > 6.5, soils that have been
recently amended with rock phosphate, and soils with high cation exchange capacity (CEC) or
high base saturation.
Dalam tanah-tanah seperti ini, kemasmaan larutan Mehlich-1 dinetralisir, sehingga
mengurangi kemampuannya mengekstraks P . Penurunan efisiensi ekstraksi P juga
dapat disebabkan oleh liat dan oksida hidrous aluminum dan besi (Nelson et al., 1953;
Lins & Cox, 1989).
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Soil Test Phosphorus: Mehlich 1
J. Thomas Sims, University of Delaware
Nilai P Mehlich-1 sebesar 20 - 25 mg P/kg tanah untuk uji Mehlich-1
umumnya dianggap optimum bagi pertumbuhan tanaman, meskipun
nilai ini beragam di antara tipe-tipe tanah dan sistem pertanaman.
For instance, Kamprath and Watson (1980) stated a Mehlich-1 P of 20 to
25 mg P/kg soil is adequate for plants grown in sandy soils but only 10
mg P/kg soil is required for fine-textured soils, a point supported by the
work of Lins and Cox (1989).
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Soil Test Phosphorus: Mehlich 1
J. Thomas Sims, University of Delaware
Peralatan Lab:
1. No. 10 (2 mm opening) sieve
2. Automatic extractant dispenser, 25 mL capacity (If preferred, pipettes
are acceptable.)
3. Standard 5 cm3 and 1 cm3 stainless steel soil scoops
4. Extraction vessels, such as 50 mL Erlenmeyer flasks, and filter
funnels (9 and 11 cm) and racks
5. Reciprocating or rotary shaker, capable of at least 180 epm
(excursions per minute)
6. Whatman No. 42 or No. 2 (or equivalent) filter paper, 9 to 11 cm.
(Acid resistant filter paper may be needed if using an automated
method for determining P concentration by intensity of color. Bits of
filter paper may cause an obstruction in the injection valves.)
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Soil Test Phosphorus: Mehlich 1
J. Thomas Sims, University of Delaware
Pereaksi - Reagents:
Mehlich 1 Extracting Solution (0.0125 M H2SO4 + 0.05 M HCl). Also
referred to as dilute double acid or the North Carolina Extractant. Using
a graduated cylinder, add 167 mL of concentrated HCl (12M) and 28 mL
of concentrated H2SO4 (18M) to ~35 L of deionized water in a large
polypropylene carboy.
Buatlah volume akhir 40 L dengan menambahkan air bebas ion. Aduklah
dnegan memasukkan gelembung udara ke dalam larutan 3 jam.
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Soil Test Phosphorus: Mehlich 1
J. Thomas Sims, University of Delaware
Prosedur:
1. Timbang 5.0 g (atau ambil 4 cm3) sampel tanah ayakan (< 2 mm), kering udara dan
masukkan ke dalam labu ekstraksi 50 mL.
2. If it is necessary to obtain a colorless filtrate, add 1 cm3 (~200 mg) of charcoal (DARCO
G60, J. T. Baker, Phillipburg, NJ) to each flask.
3. Add 20 mL of the Mehlich 1 extracting solution and shake for five minutes on a reciprocating
shaker set at a minimum of 180 epm at a room temperature at 24 to 27oC.
4. Filter through a medium-porosity filter paper (Whatman No. 2 or equivalent).
5. Analyze for P by colorimetry or inductively coupled plasma emission spectroscopy using a
blank and standards prepared in the Mehlich 1 extracting solution.
PERHITUNGAN:
P terekstraks Mehlich -1 (mg P/kg tanah) =
[Konsentrasi P dalam ekstraks Mehlich -1, mg/L ] x [ 0.020 L ekstrak ÷ 0.005 kg
tanah]
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Soil Test Phosphorus: Mehlich 1
J. Thomas Sims, University of Delaware
References:
1. Kamprath, E.J. and M.E. Watson. 1980. Conventional soil and tissue tests for assessing the
phosphorus status of soils. p. 433-469. In F. E. Khasawneh et al. (ed.) The role of phosphorus
in agriculture. ASA, CSSA, and SSSA, Madison, WI.
2. Kuo, S. 1996. Phosphorus. p. 869-919. In D. L. Sparks. (ed.) Methods of Soil Analysis: Part
3- Chemical Methods. SSSA, Madison, WI.
3. Lins, I.D.G. and F.R. Cox. 1989. Effects of extractant and selected soil properties on
predicting the optimum phosphorus fertilizer rate for growing soybeans under field
conditions. Commun. Soil Sci. Plant Anal. 20:310-333.
4. Mehlich, A. 1953. Determination of P, Ca, Mg, K, Na, and NH4. North Carolina Soil Test
Division (Mimeo). Raleigh, NC.
5. Nelson, W. L., A. Mehlich, and E. Winters. 1953. The development, evaluation, and use of
soil tests for phosphorus availability. Agronomy 4:153-158.
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Soil Test Phosphorus: A Phosphorus Sorption Index
J. Thomas Sims, University of Delaware
Kapasitas sorpsi P suatu tanah dapat ditentukan dengan eksperimen
“batch equilibrium” yg dipakai untuk menghasilkan isotherm sorpsi.
These isotherms are plots of the amount of P adsorbed from several
solutions of known initial concentration vs. the P concentration at
equilibrium for each solution. For example, Nair et al., (1984) proposed,
based on an interlaboratory comparison study, a standard approach to
construct P sorption isotherms, using a soil:solution ratio of 1:25 (w:v),
six initial P concentrations (as KH2PO4 in a 0.01M CaCl2 matrix), and a
24 h equilibration period
Hasil-hasil dari sorpsi isothermik ini dapat dipakai untuk menghitung
maksimum P-sorpsi dan energi pengikat P untuk tanah-tanah dengan
beragam sifat dan/atau dipengaruhi oleh teknologi bubidaya, seperti
rotasi tanaman, olah tanah dan aplikasi rabuk organik.
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Soil Test Phosphorus: A Phosphorus Sorption Index
J. Thomas Sims, University of Delaware
Bache and Williams (1971) developed a “P Sorption Index” (PSI) that could rapidly
determine soil P sorption capacity. They evaluated 12 approaches and found that a PSI
derived from a single-point isotherm (P sorbed from a single solution containing 50
μmol P/g soil) was easy to use and well correlated with the P sorption capacity of 42
acid and calcareous soils from Scotland (r=0.97***).
Other researchers have used the PSI, or modified versions, and shown it to be well
correlated with soil P sorption capacity determined from complete sorption isotherms
for soils of widely varying chemical and physical properties (Mozaffari and Sims, 1994;
Sharpley et al., 1984; Simard et al., 1994).
Dalam banyak kasus peneliti ini telah mempertahankan rasio orisinil P yg
ditambahkan ke tanah (1.5 g/kg), tetapi hanya sedikit mengubah rasio tanah:larutan,
elektrolitnya, dan /atau waktu kocok nya.
Modifikasi ini tidak mempengaruhi korelasi antara kapasitas sorpsi P yg diestimasi
dari PSI dengan yang ditentukan oleh sorpsi isothermik.
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Soil Test Phosphorus: A Phosphorus Sorption Index
J. Thomas Sims, University of Delaware
Peralatan Lab:
1. Centrifuge dan tabung centrifuge poli-etilen 50 mL.
2. Pengocok (end-over-end shaker preferred to ensure thorough mixing
of soil and sorption solution).
3. Peralatan filtrasi Millipore (0.45-μm pore size filters) dan labu-labu
vakum.
4. 50 mL screw-top test tubes.
Reagen:
Phosphorus Sorption Solution (75 mg P/L): Dissolve 0.3295 g of
monobasic potassium phosphate (KH2PO4) in 1 L of deionized H2O.
Store in refrigerator until use.
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Soil Test Phosphorus: A Phosphorus Sorption Index
J. Thomas Sims, University of Delaware
Prosedur:
1.
2.
3.
4.
5.
6.
Timbanglah 1.00 g sampel tanah kering udara, lolos ayakan (2 mm) ke dalam
tabung sentrifuge 50 mL.
Tambahkan 20 mL larutan sorpsi 75 mg P/L ke dalam tabung sentrifuge. (Note:
This provides a ratio of 1.5 g P /kg soil). Add two drops of toluene or chloroform to
inhibit microbial activity.
Place the tubes in the end-over-end shaker and shake for 18 h at 25±2oC.
Centrifuge the samples at 2000 rpm for 30 minutes.
Using the Millipore filtration apparatus, 0.45-μm filters, and large vacuum flasks,
filter the centrifugate into 50 mL screw-top test tubes within the flask.
Measure P concentration in the centrifugate colorimetrically or by inductively
coupled plasma emission spectroscopy (ICP-AES).
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Soil Test Phosphorus: A Phosphorus Sorption Index
J. Thomas Sims, University of Delaware
Perhitungan :
The PSI has usually been calculated as follows, although some studies
have shown that expressing PSI directly in mg/kg is acceptable.
PSI (L kg-1) = X / Log C
dimana:
X = P sorbed (mgP/kg) = (75mg P/L – Pf) x (0.020 L)
---------------------------------(0.001kg soil)
C = Konsentrasi P pd kesetimbangan (mg/L),
Pf = Konsnetrasi akhir P setelah kesetimbangan 18 jam (mg/L).
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Soil Test Phosphorus: A Phosphorus Sorption Index
J. Thomas Sims, University of Delaware
References:
1. Bache, B.W., and E.G. Williams. 1971. A phosphate sorption index for soils. J. Soil Sci.
22:289-301.
2. Mozaffari, P.M., and J.T. Sims. 1994. Phosphorus availability and sorption in an Atlantic
Coastal Plain watershed dominated by intensive, animal-based agriculture. Soil Sci. 157:97107.
3. Nair, P.S., T.J. Logan, A.N. Sharpley, L.E. Sommers, M.A. Tabatabai, and T.L. Yuan. 1984.
Interlaboratory comparison of a standardized phosphorus adsorption procedure. J. Environ.
Qual. 13:591-595.
4. Sharpley, A.N., S.J. Smith, B.A. Stewart, and A.C. Mathers. 1984. Forms of phosphorus in
soils receiving cattle feedlot waste. J. Environ. Qual. 13:211-215.
5. Simard, R.R., D. Cluis, G. Gangbazo, and A. Pesant. 1994. Phosphorus sorption and
desorption indices for soils. Commun. Soil Sci. Plant Anal. 25:1483-1494.
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Determination of Water- and/or Dilute Salt-Extractable Phosphorus
M.L. Self-Davis, University of Arkansas
P.A. Moore, Jr., USDA-ARS, Fayetteville, AR
B.C. Joern, Purdue University
Many methods exist to determine the various forms of soil phosphorus (P). Early
interests in examining soil P were primarily based on determining the quantity of
supplemental P needed to adequately meet the needs of crops.
The method for using distilled water as an extractant to determine P needs of plants was
examined in a paper by Luscombe et al. (1979). They found a good correlation between
the concentration of water-extractable P and dry matter yield responses in ryegrass.
One criticism of various other extractants is that they are either more acid or alkaline
than the soil solution. Therefore, a portion of P extracted is actually of low availability.
For example, extractants such as Mehlich 3, which contain strong acids, would be
expected to dissolve calcium phosphates. Also, due to the specific chemical nature of
many extractants, their use is limited to specific soil types. Using distilled water or 0.01
MCaCl2 overcomes these criticisms (Pote et al., 1995).
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Determination of Water- and/or Dilute Salt-Extractable Phosphorus
M.L. Self-Davis, University of Arkansas
P.A. Moore, Jr., USDA-ARS, Fayetteville, AR
B.C. Joern, Purdue University
Peralatan :
1. Shaker (reciprocating or end-over-end).
2. Centrifuge.
3. Centrifuge tubes (40 mL).
4. Filtration apparatus (0.45 μm pore diameter membrane filter, or Whatman No. 42).
5. Spectrophotometer with infrared phototube for use at 880 nm.
6. Acid washed glassware and plastic bottles: graduated cylinders (5 mL to 100 mL),
volumetric flasks (100 mL, 500 mL, and 1000 mL), storage bottles, pipets, dropper
bottles, and test tubes or flasks for reading sample absorbance.
Reagent:
1. Asam pekat hydrochloric acid (HCl).
2. Reagents used for ascorbic acid technique for P determination, Murphy and Riley
(1962).
3. Larutan M calcium chloride (CaCl2).
4. Chloroform.
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Determination of Water- and/or Dilute Salt-Extractable Phosphorus
M.L. Self-Davis, University of Arkansas
P.A. Moore, Jr., USDA-ARS, Fayetteville, AR
B.C. Joern, Purdue University
Prosedur Ekstraksi - Air bebas ion:
Timbanglah contoh tanah 2 g (dried in a forced-draft oven at 60°C for 48 hours, sieved
through a 2-mm mesh sieve) ke dalam tabung sentrifuge 40 mL. Tambahkan 20 mL
air destilasi dan kocok selama satu jam.
Centrifuge at 6,000 rpm for 10 minutes. Filter the solution through a 0.45 μm
membrane filter. Acidify to pH 2.0 with HCl to prevent precipitation of phosphate
compounds (approximately 2 days of concentrated HC1). Freeze the sample if it is not
going to be analyzed that day.
Previous articles have noted that hydrolysis of condensed phosphates can occur when
the solution is acidified (Lee et al., 1965). Also, at this pH level, there is the possibility
of flocculation of organics.
However, it is vital to ensure that the P remains in solution, therefore, we consider the
negative effects of acidification minimal.
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Determination of Water- and/or Dilute Salt-Extractable Phosphorus
M.L. Self-Davis, University of Arkansas
P.A. Moore, Jr., USDA-ARS, Fayetteville, AR
B.C. Joern, Purdue University
Prosedur Ekstraksi -- 0.01M CaCl2:
Weigh out 1 g of dry soil into a 40 mL centrifuge tube. Add 25 mL of
0.01 M CaCl2 (you can add 2 drops of chloroform to inhibit microbial
growth if desired) and shake for one hour on a reciprocating shaker.
Centrifuge at 4000 rpm for 10 minutes.
Larutan disaring dnegan kertas saring Whatman No. 42.
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Determination of Water- and/or Dilute Salt-Extractable Phosphorus
M.L. Self-Davis, University of Arkansas
P.A. Moore, Jr., USDA-ARS, Fayetteville, AR
B.C. Joern, Purdue University
ANALISIS:
For determining water or dilute salt extractable P in soil, any
spectrophotometer with an infrared phototube for use at 660 or 882 nm
can be used. Also, samples can be analyzed by inductively coupled
plasma-atomic emission spectrometry (ICP-AES), which will measure
total dissolved P.
PERHITUNGAN:
P terekstraks air atau larutan garam encer (mg P/kg tanah) =
[Konsentrasi P dalam ekstraks, mg/L] x [Volume pengekstraks, L ÷
masa tanah, kg]
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Determination of Water- and/or Dilute Salt-Extractable Phosphorus
M.L. Self-Davis, University of Arkansas
P.A. Moore, Jr., USDA-ARS, Fayetteville, AR
B.C. Joern, Purdue University
References:
1.
2.
3.
4.
5.
6.
7.
8.
9.
Lee, G.R., N.L. Clesceri, and G.P. Fitzgerald. 1965. Studies on the analysis of phosphates in algal
cultures. Internat. J. Air Water Poll. 9:715-722.
Luscombe, P.C., J.K. Syers, and P.E.H. Gregg. 1979. Water extraction as a soil testing procedure for
phosphate. Commun. Soil Sci. Plant Anal. 10:1361-1369.
Murphy, J., and J.P. Riley. 1962. A modified single solution method for the determination of phosphate
in natural waters. Anal. Chem. Acta 27:31-36.
Olsen, S.R., and L.E. Sommers. 1982. Phosphorus. P. 403-430 In A.L. Page et al. (ed.) Methods of soil
analysis. Part 2. 2nd ed. Agronomy Monogr. 9. ASA and SSSA, Madison, WI.
Olsen, S.R., and F.S. Watanabe. 1970. Diffusive supply of phosphorus in relation to soil textural
variations. Soil Sci. 110:318-327.
Pote, D.H., T.C. Daniel, P.A. Moore, Jr., A.N. Sharpley, D.R. Edwards, and D.J. Nichols. 1995.
Phosphorus: relating soil tests to runoff concentrations across five soil series. Agronomy Abstracts, p.
294, Am. Soc. Agron., Madison, WI.
Pote, D.H., T.C. Daniel, A.N. Sharpley, P.A. Moore, Jr., D.R. Edwards, and D.J. Nichols. 1996. Relating
extractable soil phosphorus to phosphorus losses in runoff. Soil Sci. Soc. Am J. 60:855-59.
Sharpley, A.N. 1995. Dependence of runoff phosphorus on extractable soil phosphorus. J. Environ. Qual.
24:920-926.
Soltanpour, P.N., F. Adams, and A.C. Bennett. 1974. Soil phosphorus availability as measured by
displaced soil solutions, calcium chloride extracts, dilute-acid extracts, and labile phosphorus. Soil Sci.
Soc. Am. Proc. 38:225-228.
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Bioavailable Phosphorus in Soil
Andrew Sharpley, USDA-ARS, University Park, PA
Biologically available P (BAP) didefinisikan sebagai “….. Jumlah P-anorganik , yg
dapat digunakan oleh populasi algae yg defisien P selama periode 24 jam atau lebih “
(Sonzogni et al., 1982).
Jumlah P dalam tanah, sedimen, dan air yang secara potensial tersedia bagi serapan
algae (bioavailable P) dapat dikuantifikasikan dengan “algal assays”, yg memerlukan
waktu inkubasi hingga 100 hari (Miller et al., 1978). Thus, more rapid chemical
extractions, such as those using NaOH (Butkus, et al., 1988; Dorich et al., 1980), NH4F
(Porcella et al., 1970), ion exchange resin (Huettl et al., 1979) and citratedithionitebicarbonate (Logan et al., 1979), have been used routinely to estimate
bioavailable P.
The weaker extractants (NH4F and NaOH) and short-term resin extractions may
represent P that could be utilized by algae in the photic zone of lakes under aerobic
conditions. In contrast, the more severe extractants (citrate-dithionite-bicarbonate)
represent P that may become bioavailable under the reducing conditions found in the
anoxic hypolimnion of stratified lakes.
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Bioavailable Phosphorus in Soil
Andrew Sharpley, USDA-ARS, University Park, PA
Sharpley et al. (1991) showed that when using a wide solution:soil ratio (500:1), 0.1 M
NaOH extractable P (NaOH-P) was closely related to the growth of several algal
species. However, the complexity of algal assay and chemical extraction methods often
limits their use by soil testing laboratories.
For example, long assay incubation (7 to 100 d) and chemical extraction times (> 16
hr), as well as large solution volumes (> 500 mL) are particularly inconvenient.
As the amount of P extracted depends on ionic strength, cationic species, pH, and
volume of the extractant used (Hope and Syers, 1976; Sharpley et al., 1981), these
limitations will be difficult to overcome.
Pertanyaan juga telah muncul tentang validitas hubungan antara bentuk atau
ketersediaan P ekstraks larutan kimia dengan bio-availabilitas P dalam lingkungan
akuatik.
Pendekatan P-sink telah dikembangkan untuk estimasi BAP dalam tganah, sedimen,
dan air.
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Bioavailable Phosphorus in Soil
Andrew Sharpley, USDA-ARS, University Park, PA
P-Sink Approaches:
The concept of exposing the soil to a P-sink has merit toward the goal of assessing soil,
sediment, and water BAP (i.e., available to plants and algae) for both agronomic and
environmental goals.
Presumably, this would allow only P that was able to respond to such a sink to be
measured, which is analogous to a root acting as a sink in the soil or to the
concentration gradient that exists when a small quantity of sediment is placed in a large
volume of water. The analogy of a root is not entirely accurate because root exudates
and mycorrhizae fungi can alter P availability in the rhizosphere such that the root does
not behave as a pure sink. Still, P-sinks are likely the closest manifestation of the root
environment that are available. Some authors assume that the sink maintains extremely
low P concentrations in the aqueous media employed and can be considered an "infinite
P-sink" in the sense that P release by the soil is clearly the rate-limiting step (Sibbesen,
1978; van der Zee et al., 1987; Yli-Halla, 1990).
For anion-exchange resins used at low resin:soil ratios, this relationship cannot be
assumed (Barrow and Shaw, 1977; Pierzynski, 1991) and is not necessary for the
assessment of bioavailable P.
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Bioavailable Phosphorus in Soil
Andrew Sharpley, USDA-ARS, University Park, PA
Iron-oxide-Impregnated Paper
Another P sink that has received attention is Fe-oxide impregnated filter paper, which
has successfully estimated plant available P in a wide range of soils and management
systems (Menon et al., 1989; 1990, Sharpley, 1991).
Also, Sharpley (1993) observed that the Fe-oxide strip P content of runoff was closely
related to the growth of several algal species incubated for 29-d with runoff as the sole
source of P. As the resin membranes and Fe-oxide strips act as a P sink, they simulate P
removal from soil or sediment-water samples by plant roots and algae. Thus, they have
a stronger theoretical justification for use over chemical extractants to estimate
bioavailable P. These methods have potential use as environmental soil P tests to
identify soils liable to enrich runoff with sufficient P to accelerate eutrophication.
The Fe-oxide impregnanted filter paper procedure was described in the section by
Chardon (2000) in this bulletin and will not be described
further here.
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Bioavailable Phosphorus in Soil
Andrew Sharpley, USDA-ARS, University Park, PA
RESIN PENUKAR-ANION
The use of anion-exchange resins is the most common P-sink approach
for assessing available inorganic P in soils.
The procedure typically involves the use of chloridesaturated resin at a
1:1 resin-to-soil ratio in 10 to 100 mL of water or weak electrolyte for 16
to 24 h (Amer et al., 1955; Olsen and Sommers, 1982).
Korelasi antara respon tanaman dan P-terekstraks resin ternyata
sebanding atau superior dibandingkan dengan korelasi metode-metode
ekstraksi kimia (Fixen dan Grove, 1990).
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Bioavailable Phosphorus in Soil
Andrew Sharpley, USDA-ARS, University Park, PA
Ion-exchange Resin-Impregnated Membranes
A similar approach using ion-exchange resin impregnated membranes has been investigated by
several researchers (Abrams and Jarrell, 1992; Qian et al., 1992: Saggar et al., 1992).
Impregnation of the resin onto a plastic membrane facilitates separation of the resin beads from
the soil and may eliminate the soil grinding step. Also, an extraction time as short as 15 min can
be used without reducing the accuracy of predicted P availability for a wide range of soils (Qian
et al., 1992). In pot studies, the resin membranes have provided a better index of P availability
than conventional chemical extraction methods for canola (Qian et al., 1992) and ryegrass
(Saggar et al., 1992). It is likely that the utility of the resin membranes will make the use of loose
resin obsolete.
Ion exchange membranes have the potential to estimate P availability in aquatic as well as soil
environments. Edwards et al. (1993) used ion exchange membranes to obtain in-situ estimates of
the chemical composition of river water for two Scottish watersheds.
It was suggested that direct multi-element analysis by X-ray fluorescence of ions retained on the
membranes removes the need for sample storage or filtration, both of which can be sources of
potential contamination and error. Thus, the membranes can provide useful information in
addition to that obtained by conventional sampling (Edwards et al., 1993).
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Bioavailable Phosphorus in Soil
Andrew Sharpley, USDA-ARS, University Park, PA
SAMPLING TANAH:
Soil sampling protocol for environmental concerns should be re-evaluated since
the primary mechanism for P transport from most agricultural soils is by
surface runoff and erosion. Although most samples submitted to soil testing
laboratories are obtained from 0 to 20 cm, the zone of interaction of runoff
waters with most soils is normally less than 5 cm.
Consequently, environmental soil sampling should reflect this shallower depth
of soil influencing runoff P. Hence, environmental soil samples should, in
general, be taken from no deeper than 5 cm. This protocol is compatible with
sampling of no-till fields, currently recommended by extension specialists in
several states, where the traditional 0-to 20-cm depth is split into two or three
increments.
Pada tanah-tanah yang rentan terhadap kehilangan P melalui runoff, the surface
increment could be analyzed for environmental interpretation and all
increments integrated for agronomic interpretations.
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Bioavailable Phosphorus in Soil
Andrew Sharpley, USDA-ARS, University Park, PA
PERALATAN:
The following equipment is needed to conduct BAP extraction of soil
and analysis for P:
1.
2.
3.
4.
5.
Membran Resin, penukar anion.
End-over-end shaker - used to equilibrate sample and sink
Labu Volumetrik – biasanya volume 25 atau 50 mL
Pipets untuk sampel aliquot dan reagen warna
Spectrophotometer untuk menentukan konsentrasi P dalam reagen
yg menjadi berwarna kalau ketemu sampel.
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Bioavailable Phosphorus in Soil
Andrew Sharpley, USDA-ARS, University Park, PA
Reagents:
Membran Resin
Hydrochloric acid to extract P from the membranes - 1.0 M HCl (166 mL
concentrated HCl in 2 L)
Murphy and Riley Molybdenum Blue Color Reagent
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Bioavailable Phosphorus in Soil
Andrew Sharpley, USDA-ARS, University Park, PA
Resin Strip Procedure:
1. Anion exchange resin sheets are cut into 2 x 2 cm squares and are stored in propylene glycol.
Wash the resin squares in distilled water to remove all the propylene glycol. If not already
saturated with an anion, saturation with C1- , HCO3- or acetate may be necessary. They are
now ready for use.
2. Phosphorus is extracted from soil or sediment by shaking a 1-g sample and one resin
membrane square in 40 mL of deionized distilled water end-over-end for 16 hours at 25o C.
3. Remove the resin membrane square and wash thoroughly with distilled water until all soil
particles are removed.
4. The BAP content of runoff can also determined by shaking 50 mL of an unfiltered runoff
sample with one resin membrane square for 16 hours. Smaller runoff sample volumes should
be used if P concentrations are expected to be high (>1 or 2 mg/L) and made up to 50 mL
with distilled water.
5. Phosphorus retained on the resin membrane square is removed by shaking the square endover-end with 40 mL of 1 M HCl for 4 hours. Remove square and rinse with distilled water.
Retain the HCl desorption solution for analysis. Repeat this step. Do not mix the first and
second desorption solutions.
6. Mengukur konsentrasi P dua macam larutan secara terpisah. Jumlah total desorpsi P dari
membran resin berbentuk kuadrat adalah jumlah dari dua larutan itu.
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Bioavailable Phosphorus in Soil
Andrew Sharpley, USDA-ARS, University Park, PA
Perhitungan:
P-terekstraks Resin (mg P/kg) =
[Konsentrasi P dalam 1 MHCl, mg/L] x [0.04 L ÷ 0.001 kg]
Resin BAP dalam runoff (mg P/L) = [konsentrasi P dalam 1 M HC1, mg/L] x [0.04L
÷ volume runoff, L]
References:
1.
2.
3.
4.
5.
6.
7.
Abrams, M.M., and W.M. Jarrell. 1992. Bioavailability index for phosphorus using nonexchange resin impregnated
membranes. Soil Sci. Soc. Am. J. 56:1532-1537.
Amer, F., D.R. Bouldin, C.A. Black, and F.R. Duke. 1955. Characterization of soil phosphorus by anion exchange resin
and adsorption by P-32 equilibration. Plant Soil 6:391-408.
Barrow, N.J., and T.C. Shaw. 1977. Factors affecting the amount of phosphate extracted from soil by anion exchange
resin. Geoderma 18:309-323.
Butkus, S.R., E.B. Welch, R.R. Horner, and D.E. Spyridakis. 1988. Lake response modeling using biologically available
phosphorus. J. Water Pollut. Cont. Fed. 60:1663-1669.
Chardon, W.J. 2000. Phosphorus extraction with iron oxide-impregnated filter paper (P; test). In G.M. Pierzynski (ed.),
Sediments, Residuals, and Waters. Southern Cooperative Series Bulletin No. 396, p. 27-30.
Dorich, R.A., D.W. Nelson, and L.E. Sommers. 1980. Algal availability of sediment phosphorus in drainage water of the
Black Creek watershed. J. Environ. Qual. 9:557- 563.
Edwards, T., B. Ferrier, and R. Harriman. 1993. Preliminary investigation on the use of ion-exchange resins for
monitoring river water composition. Sci. of Total Environ. 135:27-36.
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Total Phosphorous in Soil
M.R. Bender and C.W. Wood, Auburn University
There have been many methods developed to extract and analyze total phosphorus (P)
in soil (Bray and Kurtz, 1945; Muir, 1952; Jackson, 1958; Syers et al., 1968; Sommers
and Nelson, 1972; Dick and Tabatabai, 1977; Olsen and Sommers, 1982; Bowman,
1988).
Two of the more commonly used and most recognizable methods of P extraction
are sodium carbonate (Na2CO3) fusion and acid digestion. Of these methods, Na2CO3
fusion is thought to give more reliable results (Syers et al., 1967; Syers et al., 1968;
Sherrell and Saunders, 1966; Sommers and Nelson, 1972). Underestimation of total P
by acid digestion is thought to be due to inability of these methods to extract P from
apatite inclusions (Syers et al., 1967).
Kemampuan “acid digestion” untuk mengekstraks P dari inklusi terganutng pada
asam atau kombinasi asam yang dipakai.
Menurut Syers et al. (1967) , efektivitas ekstraksi umumnya mengikuti urutan : Fusi >
HF digestion > HClO4 digestion > N H2SO4 > ignition.
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Total Phosphorous in Soil
M.R. Bender and C.W. Wood, Auburn University
In recent years, more rapid methods for determining total P in soils have been
developed (Sommers and Nelson, 1972; Dick and Tabatabai, 1977; Bowman, 1988).
Methods developed by Sommers and Nelson (1972) and Bowman (1988) are variations
of standard HClO4 digestion methods. These methods were shown to give a similar
degree of underestimation of total P as standard HClO4 digestion methods.
Dick dan Tabatabai (1977) mengusulkan metode oksidasi alkaline
menggunakan sodium hypobromite (NaOBr).
Metode ini ternyata menghasilkan 1% lebih tinggi dibandingkan
dnegan hasil dari metode HClO4 digestion. Akan tetapi, metode ini
masih underestimate P-total sebesar 4% kalau dibandingkan dnegan
hasil metode fusi Na2CO3.
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Total Phosphorous in Soil
M.R. Bender and C.W. Wood, Auburn University
Fusion Method (Olsen and Sommers (1982)):
Reagents
1.
2.
3.
4.
5.
6.
7.
8.
Anhydrous sodium carbonate (Na2CO3)
Larutan 4.5 M H2SO4
Larutan 1 M H2SO4
Ammonium paramolybdate [(NH4)6Mo7O24.H2O]. Prepare by dissolving 9.6 g of
(NH4)6Mo7O24. 4H2O in distilled water under heat. After solution has cooled, dilute
solution volume to 1 L with distilled water.
Larutan 2 M H2SO4
Ascorbic acid. Prepare by dissolving 10 g of ascorbic acid in 80 mL of distilled water, and
dilute solution volume to 100 mL with distilled water. Store reagent at 2°C. Make fresh
solution when noticeable color develops.
Potassium antimony tartrate (KSbO.C4H4O6). Prepare by dissolving 0.667 g of
KSbO.C4H4O6 in 250 mL of distilled water.
Mixed reagent. Mix 1:1 ratio of ascorbic acid and antimony reagents prior to use.
Siapkan larutan segar sebanyak yang diperlukan.
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Total Phosphorous in Soil
M.R. Bender and C.W. Wood, Auburn University
Prosedur:
Place a mixture of 1.0 g of finely ground (100 mesh), air-dried soil and 4-5 g of Na2CO3 in a Pt crucible. For
soils high in Fe, use 0.5 g of soil. Place 1 g of Na2CO3 on top of the mixture. Drive off moisture from
mixture by gently heating with a Meeker burner. Place a lid on the crucible so that approximately one fifth of
the crucible remains open. Apply heat with a low flame for 10 min so the mass fuses gently. Adjust heat of
Meeker burner to full, and heat mass for 15 to 20 min. To provide an oxidizing environment for this step, lift
the lid of the crucible periodically. Do not allow the reduced portion of the flame to come in contact with the
crucible. Remove crucible from flame.
Rotate crucible as it cools so to deposit the melt thinly onto the walls of the crucible. After the crucible has
cooled, gently roll it between your hands to facilitate the removal of the melt. Remove the melt with 30 mL
of 4.5 M H2SO4, using care to avoid loss by effervescence.
Place crucible and lid in a beaker containing 25 mL of 1 M H2SO4, and heat contents to a boil. Transfer the
solution from the beaker and the solution from the melt to a 250 mL volumetric flask. Dilute the solution to
volume using distilled water.
Allow sediment to settle. Remove an aliquot of clear supernatant solution for total P analysis by the ascorbic
acid method.
To analyze for total P, transfer aliquots (2 mL) into 50 mL volumetric flasks (for samples containing <150 mg
of P). With 1 M Na2CO3, adjust pH of the aliquot to 5 using p-nitrophenol indicator. Add 5 mL of 2 M
H2SO4 and 5 mL of ammonium paramolybdate reagent and mix. Add 4 mL of the mixed reagent and mix
contents of the flask. Bring to 50 mL volume with distilled water and mix thoroughly. Reduction is completed
and maximum color intensity develops in 10 min, and color is stable for 24 hours. The absorption maximum
of the blue color formed in the presence of Sb is at 890 nm (Harwood et al., 1969)
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Total Phosphorous in Soil
M.R. Bender and C.W. Wood, Auburn University
KOMENTAR
The method for color development was described by Harwood et al. (1969) and is a
variation of the method proposed by Murphy and Riley (1962). By increasing amount
of antimony added, Harwood et al. (1969) found that the range of the calibration curve
could be extended. This modification of the Murphy and Riley (1962) method was
found to increase the upper limit of the calibration curve from 50 mg P/50ml sample to
150 mg P/50ml sample.
It should be noted that presence of arsenic in the form of AsO4 in soil samples gives the
same blue color as phosphate. To eliminate this problem, AsO4 can be reduced to AsO3
using a NaHSO3 solution as described in the following digestion method (Olsen and
Sommers, 1982).
PERHITUNGAN
Total P, mg/kg =
[Konsentrasi P dalam pengenceran initial 250 mL, mg/L] x [0.25 L ÷ masa tanah, kg]
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Total Phosphorous in Soil
M.R. Bender and C.W. Wood, Auburn University
Digestion Method (Olsen and Sommers (1982)):
Reagents
1.
2.
3.
4.
5.
Larutan 60% Perchloric acid (HClO4)
Ammonium paramolybdate-vanadate. Prepare by dissolving 25 g of
(NH4)6Mo7O24 . 4H2O in 400 mL of distilled water, and by dissolving
ammonium metavanadate (NH4VO3) in 300 mL of boiling distilled water. Cool
vanadate solution, and add 250 mL of conc. HNO3. Cool NH4VO3-HNO3 solution
to room temperature before adding (NH4)6Mo7O24. 4H2O solution. Dilute the
mixed solution to 1 L with distilled water.
Standard phosphate solution. Prepare by dissolving 0.4393 g of oven-dried
potassium dihydrogen phosphate (KH2PO4) in distilled water. Dilute solution to 1
L with distilled water. Standard solution contains 100 mg P/L.
Sodium hydrogen sulfite (NaHSO3). Prepare by dissolving 5.2 g of reagent grade
NaHSO3 in 100 mL of 0.5 M H2SO4.
Persiapkan reagen setiap mingguan.
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Total Phosphorous in Soil
M.R. Bender and C.W. Wood, Auburn University
Prosedur Kerja:
In a 250 mL volumetric or Erlenmeyer flask, mix 2.0 g of finely ground soil (<0.5 mm) with 30 mL of 60% HClO4. Digest
the soil and acid mixture at a few degrees below the boiling point on a hot plate in a perchloric hood until the dark color from
organic matter disappears. Continue to heat at the boiling temperature for 20 min longer. Heavy white fumes will appear, and
the insoluble material will become like white sand. If any black particles stick to the side of the flask, add 1 or 2 mL of
HClO4 to wash down the particles. If the sample is high in organic matter it may be necessary to add 20 mL of HNO3 and
heat to oxidize organic matter before adding HClO4. Total digestion time is approximately 40 min. Cool the mixture before
bringing the volume up to 250 mL with distilled water. Mix the contents of the flask, and then allow sediment to settle.
To analyze for total P, transfer aliquots into 50 mL volumetric flasks (for samples containing between 0.05 to 1.0 mg of P).
Add 10 mL of the ammonium paramolybdatevanadate reagent, and bring the volume of the flask up to 50 mL using distilled
water.
The optical density of the sample can be measured after 10 min at wavelengths between 400 to 490 nm. The optical density
of a reagent blank should be subtracted from the optical density readings of the samples.
To reduce AsO4-3 to AsO3-3, add 5 mL of NaHSO3 solution to the aliquot. Then partially immerse the 50 mL volumetric
flasks in a water bath, and digest the solution for 30 min (20 min after temperature reaches 95oC). An alternative procedure is
to allow the solution to stand for 4 hours at room temperature.
PERHITUNGAN
Total P, mg/kg =
[Konsentrasi P dalam pengenceran initial 250 mL , mg/L] x [0.25 ÷ masa tanah, kg]
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Total Phosphorous in Soil
M.R. Bender and C.W. Wood, Auburn University
Metode Oksidasi Alkaline (Dick and Tabatabai (1977)):
Pereaksi - Reagents
1.
2.
3.
4.
5.
6.
Sodium hypobromite solution (NaOBr-NaOH). Prepare by slowly adding 3 mL of
bromine (0.5 mL/min) to 100 mL of 2 M NaOH under constant stirring. Prepare
reagent immediately prior to use.
Larutan 90 % formic acid
Larutan 2.5 M H2SO4
Ammonium molybdate -Antimony potassium tartrate solution. Prepare by
dissolving 12 g of ammonium molybdate in 250 mL of distilled water, and
dissolving 0.2908 g of antimony potassium tartrate in 100 mL of distilled water.
Add both solutions to 1 L of 2.5 M sulfuric acid, and dilute volume to 2 L with
distilled water. Store reagent in a cool place, in a dark Pyrex glass bottle.
Ascorbic acid. Prepare by dissolving 1.056 g of ascorbic acid in 200 mL of
ammonium molybdate - antimony reagent. Prepare reagent daily.
Standard phosphate solution. Prepare by dissolving 0.2195 g of potassium
dihydrogen phosphate (KH2PO4) in distilled water. Dilute solution to 1L with
distilled water. Standard solution contains 50 mg P/L.
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Total Phosphorous in Soil
M.R. Bender and C.W. Wood, Auburn University
Prosedur kerja
1.
2.
3.
4.
5.
6.
Place a 100 to 200 mg sample of finely ground, air-dried soil in a 50 mL boiling
flask.
Add 3 mL of sodium hypobromite solution to the flask, and swirl flask for a few
seconds to mix contents. Allow flask to stand for 5 min. Swirl flask again and place
it in a sand bath adjusted to 260 to 280oC. The sand bath should be situated in a
hood. Heat flask until contents evaporate to dryness. Evaporation time is 10 to 15
min. After evaporation, continue to heat for an additional 30 min. Remove flask
from sand bath, and allow it to cool for 5 min. Then add 4 mL of distilled water and
1 mL of formic acid. Mix contents before adding 25 mL of 0.5 M H2SO4. Stopper
flask and mix contents. Transfer mixture to a 50 mL plastic centrifuge tube and
centrifuge sample at 12,000 rpm for 1 min.
To analyze for total P, transfer aliquots of 1 to 2 mL into 25 mL volumetric flasks.
Add 4 mL of ascorbic acid reagent, and bring solution up to volume with distilled
water.
Stopper flask and mix solution. Allow solution to stand for 30 min for color
development.
Optical density of sample should be measured at a wavelength of 720 nm.
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Total Phosphorous in Soil
M.R. Bender and C.W. Wood, Auburn University
KOMENTAR
This method does not require neutralization of the 1 to 2 mL of aliquot, however,
longer time (30 min) is needed for full color development.
The sodium hypobromite (NaOBr-NaOH) reagent should be prepared just prior to use.
The reagent should be made in a fume hood. Formic acid added after the hypobromite
treatment will destroy any residual hypobromite remaining after oxidation of the
sample.
PERHITUNGAN
Total P, mg/kg =
[konsentrasi P dalam larutan initial asam fosmat /H2SO4, mg/L] x [0.03 L ÷ masa
tanah, kg]
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Total Phosphorous in Soil
M.R. Bender and C.W. Wood, Auburn University
References:
1.
2.
Bowman, R.A. 1988. A rapid method to determine total phosphorus in soils. Soil Sci. Soc. Am. J. 52:1301-1304.
Bray, R.H., and L.T. Kurtz. 1945. Determination of total, organic, and available forms of phosphorus is soils. Soil Sci.
59:39-45.
3. Dick, W.A., and M.A. Tabatabai. 1977. An alkaline oxidation method for determination of total phosphorus in soils. Soil
Sci. Soc. Am. J. 41:511-514.
4. Harwood, J.E., R.A. van Steenderen, and A.L. Kuhn. 1969. A rapid method for orthophosphate analysis at high
concentrations in water. Water Res. 3:417-423.
5. Jackson, M.L. 1958. Soil chemical analysis. Prentice-Hall, Inc., Englewood Cliffs, N.J. Muir, J.W. 1952. The
determination of total phosphorus in soil. Analyst 77:313-317.
6. Murphy, J., and J.P. Riley. 1962. A modified single solution method for determination of phosphate in natural waters.
Anal. Chim. Acta 27:31-36.
7. Olsen, S.R., and L.E. Sommers. 1982. Phosphorus. pp. 403-430. In: A.L. Page. R.H. Miller, and D.R. Keeney (eds.),
Methods of Soil Analysis. 2nd ed. Agronomy Series No.9, Part 2. Soil Science Society of America, Inc., Madison, WI.
8. Sherrell, C.G., and W.M.H. Saunders. 1966. An evaluation of methods for the determination of total phosphorus in soils.
N.Z.J. Agric. Res. 9:972-979.
9. Sommers, L.E., and D.W. Nelson. 1972. Determination of total phosphorus in soils: a rapid perchloric acid digestion
procedure. Soil Sci. Soc. Amer. Proc. 36:902-904.
10. Syers, J.K., J.D.H. Williams, A.S. Campbel, and T.W. Walker. 1967. The significance of apatite inclusions in soil
phosphorous studies. Soil Sci. Soc. Amer. Proc. 31:752-756.
11. Syers, J.K., J.D.H. Williams, and T.W. Walker. 1968. The determination of total phosphorus in soils and parent materials.
N.Z.J. Agric. Res. 11:757-762.
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