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PENGELOLAAN HARA TANAMAN TERPADU

PENGELOLAAN HARA TANAMAN TERPADU. Integrated Plant Nutrient Management. PRESENTASI & DISKUSI. Integrated Nutrient management, Integrated Water Management, Integrated Soil management, etc. Apa yang dimaksud dengan hara tanaman ? Mengapa perlu dikelola secara terpadu ?

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PENGELOLAAN HARA TANAMAN TERPADU

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  1. PENGELOLAAN HARA TANAMANTERPADU Integrated Plant Nutrient Management

  2. PRESENTASI & DISKUSI Integrated Nutrient management, Integrated Water Management, Integrated Soil management, etc

  3. Apa yang dimaksud dengan hara tanaman ? Mengapa perlu dikelola secara terpadu ? Apa tujuan dari pengelolaan hara tanaman terpadu ? Hara tanaman apa saja yang dapat dikelola secara terpadu ? Bagaimana cara pengelolaannya ?

  4. UNSUR YANG ADA DALAM JARINGAN TANAMAN≠UNSUR HARA YANG DIBUTUHKAN TANAMAN

  5. Agroecology: science & sustainability • Fertilizers • Cover crops • Green manures • Mulching • Compost • Rotations Enhanced Soil Fertility Healthy Agroecosystem Integrated Plant Management Decisions Interactions (+; -) Synergisme • Crop diversity • Cultural practices • Pesticides • Herbicides • Habitat modification Enhanced Pest Regulation Healthy Crop

  6. INTEGRATED NUTRIENT MANAGEMENT • Integrated Nutrient Management advocates balanced & integrated use of fertilizers. • INM envisage following components : • Use of Chemical fertilisers including secondary and micro-nutrients, • Bio-fertilisers, • Organic manures, green manures, press mud etc. • Application of INM needs to be based upon Soil test results (ideally)

  7. Dikelola jumlah (takaran)nya HUKUM MINIMUM LIEBIG minimum

  8. 10% Reduction in Growth Luxury Consumption Toxicity Critical Nutrient Range (no symptoms) Visual Symptoms Deficiency Visual Symptoms Concentration of Nutrient in Tissue (dry basis) Critical Concentration

  9. Dikelola jenis (macam) hara-nya INTERAKSI HARA DALAM TANAH

  10. N berlebihan  meningkatkan kekahatan tembaga (Cu) & boron (B), tingkatkan kerentanan thd serangan hama & penyakit, P berlebihan mengganggu serapan tembaga (Cu), besi (Fe) dan seng (Zn), K berlebihan  menimbulkan kekahatan boron & menurunkan rasio minyak terhadap tandan pada sawit, Tembaga (Cu) & sulfat berlebihan  hambat serapan Mo,

  11. Tembaga, seng & mangan berlebihan hambat serapan Fe, K atau Na berlebihan turunkan serapan mangan & boron, N &Mg berlebihan sebabkan kekahatan tembaga, Pengapuran (Ca) berlebihan turunkan serapan boron & kekahatan Mg, Kelebihan besi, tembaga atau seng hambat serapan Mn.

  12. How the pH of Soil Affects the Availability of Nutrients Different types of plants have different soil pH requirements

  13. Dikelola jenis (macam) sumber hara-nya Mineral Organik Gas

  14. Plant roots – the primary route for mineral nutrient acquisition • Meristematic zone • Cells divide both in direction of root base to form cells that will become the functional rootand in the direction of the root apex to form the root cap • Elongation zone • Cells elongate rapidly, undergo final round of divisions to form the endodermis. Some cells thicken to form casparian strip • Maturation zone • Fully formed root with xylemand phloem – root hairsfirst appear here

  15. ROOT ABSORBS DIFFERENT MINERAL IONS IN DIFFERENT AREAS • Calcium • Apical region • Iron • Apical region (barley) • Or entire root (corn) • Potassium, nitrate, ammonium, and phosphate • All locations of root surface • In corn,elongation zone has max K accumulation and nitrate absorption • In corn and rice,root apex absorbs ammonium faster than the elongation zonedoes • In several species, root hairsare the most active phosphate absorbers

  16. WHY SHOULD ROOT TIPS BE THE PRIMARY SITE OF NUTRIENT UPTAKE? • Tissues with greatest need for nutrients • Cell elongation requires Potassium, nitrate, and chlorine to increase osmotic pressure within the wall, • Ammonium is a good nitrogen source for cell division in meristem, • Apex grows into fresh soil and finds fresh supplies of nutrients. • Nutrients are carried via bulk flow with water, and water enters near tips, • Maintain concentration gradients for mineral nutrient transport and uptake.

  17. ROOT UPTAKE SOON DEPLETES NUTRIENTS NEAR THE ROOTS • Formation of a nutrient depletion zone in the region of the soil near the plant root • Forms when rate of nutrient uptake exceeds rate of replacement in soil by diffusion in the water column • Root associations with Mycorrhizal fungi help the plant overcome this problem

  18. Dasar Penetapan PEMUPUKAN BERIMBANG • Musim  potensi fotosintesis, • Potensi produksi tanaman, • Interaksi hara (nol, sinergisme, antagonisme), • Hara total vs tersedia tanah & faktor penjerapnya,, • Reaksi pupuk (kemasaman akibat 100 kg Za diatasi dg 107 kg kaptan; 100 kg Urea dg 36 kg kaptan), • Jumlah & perbandingan hara terbawa panen, • Kandungan hara dlm daun (efektivitas serapan), • Aktivitas Biota tanah, • Cara & waktu pemberian pupuk.

  19. INTERAKSI POSITIF (SINERGISME) : Pemberian Zn  tingkatkan serapan K, perbaiki status N, P & Ca didalam tanaman,  tingkatkan produksi kelapa sawit sampai 12 – 78%, Pemberian Zn melalui daun (larutan 1000 ppm Zn) lebih efektif drpd pemberian lewat tanah atau injeksi

  20. N Ca 16EssentialElements P Mg K S C H O B Cl Cu Fe Mn Mo Zn

  21. Non-Mineral Nutrients Carbon (C) Hydrogen (H) Oxygen (O) Used in photosynthesis

  22. Micronutrients Major Nutrients MINERAL NUTRIENTS Nitrogen (N) Phosphorus (P) Potassium (K) Boron (B) Chloride (Cl) Copper (Cu) Iron (Fe) Manganese (Mn) Molybdenum (Mo) Zinc (Zn) Secondary Nutrients Calcium (Ca) Magnesium (Mg) Sulfur (S)

  23. Muatan Negatif Kation2 teradsorbsi Kation2 dalam larutan tanah H+ K+ Mg2+ H+ NH4+ H+ Na+ Ca2+ H+ K+ Mg2+ H+ NH4+ H+ Na+ ADSORPSI (JERAPAN) KATION OLEH KOLOID HUMUS & SEL-SEL MIKROBA DALAM TANAH fenolik O- karboksil COO- O- hidroksil COO- SATUAN INTI KOLOID HUMUS (C, H & O) O- COO- O- karboksil COO- O- fenolik karboksil COO-

  24. NEGATIVELY CHARGED IONSARE CALLED ANIONS

  25. SIFAT KATION-ANION - + - + Unlikes Attract Likes Repel - + - +

  26. Negatively Charged ColloidsAttract Cations Ca++ K+ - - - Soil Colloid H+ - - - Ca++ - - - Mg++ Na+

  27. CATION EXCHANGE CAPACITY

  28. HOW DOES CATION EXCHANGE AFFECT SOIL pH? • Raising soil pH with lime Ca(OH)2 + 2H+ Ca2+ + 2H2O

  29. UNSUR HARA YANG DIBUTUHKAN TANAMAN HARA MAKROESENSIAL

  30. HARA MIKROESENSIAL

  31. CATION EXCHANGE CAPACITY(CEC)The total number of exchangeablecations a soil can hold(amount of its negative charge) Determined in the lab using “conventional” procedure

  32. S O I L H+ Ca++ Mg++ K+ Al 3+ NH4+ NH4+ NH4+ NH4+ NH4+ NH4+ NH4+ NH4+ NH4+ NH4+ NH4+ + 9 NH4OAc + + 9 OAc Solution “Conventional” CEC determination by displacement of cations with ammonium acetate extraction S O I L H+ Ca++ Mg++ K+ Al 3+ NH4+

  33. S O I L S O I L NH4+ NH4+ NH4+ NH4+ NH4+ NH4+ NH4+ NH4+ NH4+ NH4+ K+ K+ K+ K+ K+ K+ K+ K+ K+ K+ + 9 NH4+ + 9 Cl- + 9 KCl Solution Displacement of ammonium ions with KCl solution Filter and measure ammonium by steam distillation of ammonia

  34. Actual Soil Test Lab CEC Method- usually a summation method • Cations determined by: • extraction using ammonium acetate, Mehlich 1, or Mehlich 3 extractants • analysis using atomic absorption spectrometry or ICP equipment • Sum of extractable cations (Ca, Mg, K, Na), with some adjustment for H+ and Al3+(using pH), gives estimate of “true” CEC

  35. Generally ….the higher the CEC The more fertile the soil tends to be The more clay the soil tends to have The more organic matter a soil tends to have (especially for weathered, sandy, soils in the South)

  36. CLAY AND ORGANIC MATTER HAVE GREATEST INFLUENCE ON CEC Organic Matter Clay 10-150 meq/100g 200-400 meq/100g ORGANIC MATTER HAS A HIGHER CEC

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