The Role of Soil Testing in Precision Agriculture

Similar documents
FUTURE OF TRI-STATE FERTILIZER RECOMMENDATIONS

Optimizing Nitrogen and Irrigation Timing for Corn Fertigation Applications Using Remote Sensing

Proceedings of the 3 rd Annual Nitrogen: Minnesota s Grand Challenge & Compelling Opportunity Conference

Managing Nitrogen for Corn. Jim Camberato Dan Emmert Bob Nielsen Brad Joern

EVALUATION OF THE ILLINOIS SOIL NITROGEN TEST IN THE NORTH CENTRAL REGION i. Abstract. Introduction

Proceedings of the 2007 CPM Short Course and MCPR Trade Show

Sidedress. trogen Uptake. Seasonal Nit. 80% of requirement after V8-10

UPDATING TRI STATE FERTILIZER RECOMMENDATIONS

Determining Optimum Nitrogen Application Rates for Corn Larry Bundy, Todd Andraski, Carrie Laboski, and Scott Sturgul 1

Nitrogen Management on Sandy Soils: Review of BMPs. Carl Rosen Department of Soil Water and Climate University of Minnesota

Lessons Learned from Iowa On-Farm Studies Testing Manure Nitrogen Availability

Evaluation of Mosaic MicroEssentials Sulfur Fertilizer Products for Corn Production

On Farm Assessment of Critical Soil Test Phosphorus and Potassium Values in Minnesota. AFREC Year 4 Summary Report 8/31/2014 for

EVALUATION OF ADAPT-N IN THE CORN BELT. Introduction

Protein and Yield Response to Nitrogen Fertilizer and Variation of Plant Tissue Analysis in Wheat

Increasing Importance of Sulfur for Field Crops

Institute of Ag Professionals

Nitrogen Management Guidelines for Corn in Indiana

Approaches to N Recommendations in the North Central Region

Nutrient Management in Field Crops MSU Fertilizer Recommendations Crop*A*Syst 2015 Nutrient Management Training

Best Management Practices for Nitrogen Use in SOUTH-CENTRAL MINNESOTA

SOIL APPLIED AND WATER APPLIED PHOSPHORUS APPLICATION. M. J. Ottman, T. L. Thompson, M. T. Rogers, and S. A. White 1 ABSTRACT

Cover Crops and Nitrogen in Water

Basic Principles of Liming. John Peters UW Soil Science Department

Economics of Irrigation Ending Date for Corn 1

HOW CHANGES IN NUTRIENT MANAGEMENT REGULATIONS WILL AFFECT FORAGE PRODUCTION

NITROGEN FERTILIZER MANAGEMENT OF TEMPORARILY FLOODED SOILS TO IMPROVE CORN PRODUCTION AND REDUCE ENVIROMENTAL N LOSS

Nitrogen Management in Sugarcane and Cotton in Louisiana

Simplot FŪSN Fertilizer Potato Trials

SOIL TEST N FOR PREDICTING ONION N REQUIREMENTS - AN IDAHO PERSPECTIVE. Brad Brown, University of Idaho Parma Research and Extension Center

Organic Systems Trial. Advisory Group Meeting 2008

QUANTIFYING CORN N DEFICIENCY WITH ACTIVE CANOPY SENSORS. John E. Sawyer and Daniel W. Barker 1

Institute of Ag Professionals

FERTILIZER RECOMMENDATIONS for the Lower Rio Grande Valley

Fertility management in organic strawberries

Does Organic Matter Really Matter? Jodi DeJong-Hughes Regional Extension Educator, Willmar x 2006

Soil Amendment and Foliar Application Trial 2016 Full Report

NUTRIENT MANAGEMENT. philosophy/approach for determining N rate guidelines for corn.

Institute of Ag Professionals

CORN NITROGEN RATE RESPONSE AND CROP YIELD IN A RYE COVER CROP SYSTEM. Introduction

Nitrate, Well Testing and Rules

R.W. Heiniger Vernon G. James Research and Extension Center North Carolina State University

Soil Health & Tillage Long-term Impacts

Natural Resources & Environmental Stewardship

Nitrogen mangement for organic potatoes. Dan M. Sullivan Soil Scientist Oregon State University Corvallis, OR

Is the soybean N credit real? Indiana CCA Conference Indianapolis, December 12, 2017

2013 Research Report Impact of Cover Crops and Field Corn Stover Removal on Squash Yield.

SOIL ACIDIFICATION. Chouteau County January 11, Clain Jones MSU Soil Fertility Extension

Using Dairy Manure as a Fertilizer Source for Forage Crops. Workgroup. Marsha Campbell Mathews University of California Farm Advisor Stanislaus County

Crop Response to Shallow Placement of Anhydrous Ammonia in Corn

wheat N small plot and OFT studies

Fertilizing Corn in Minnesota

Makin and Usin Management Zones A Case Study

Optimizing Strip-Till and No-Till Systems for Corn in the Biofuel Era

Soil Nutrient Management: Testing, Sources, and Foliar Application Soils Workshops for Hill, Blaine and Phillips Counties Feb.

Irrigation Scheduling: Checkbook Method

Best Management Practices for Nitrogen Use in SOUTHWESTERN AND WEST-CENTRAL MINNESOTA

SULFUR AND NITROGEN FOR PROTEIN BUILDING

Exercise 2: Determining a Phosphorus Nutrient Recommendation and Fertilizer Rate

Nitrate-N Loss Reduction: Scale of In- Field and Edge-of-Field Practice Implementation to Reach Water Quality Goals

Agronomic Practices for Optimizing Corn Silage Production in Central Minnesota. Royalton, MN February 12, 2009

SLOW RELEASE NITROGEN FOR IRRIGATED HARD RED SPRING WHEAT YIELD AND PROTEIN. B. D. Brown University of Idaho, Parma Research and Extension Center

Emergence Uniformity in Corn: Is it Essential for Ear Size Consistency and Improved Yield?

Improving soil physical and chemical properties for better tree performance

Evaluation of Fertilizer Additives for Enhanced Nitrogen Efficiency in Corn. Final Project Report (2013 and 2014)

Nutrient Management (NM)

Understanding Salt Index of Fertilizers. Carrie Laboski Department of Soil Science University of Wisconsin-Madison

AGRICULTURE APSA-80 Nutriplant SD, SL & AG. Field Test Program 2015 APSA 80 APSA 80

Air. Water. Minerals (rocks)

Placement and Interpretation of Soil Moisture Sensors for Irrigated Cotton Production in Humid Regions SITE SELECTION IN A FIELD OBJECTIVE

Corn/Soybean Efficient Fertility Management. Robert Mullen Nutrient Management/Soil Fertility Specialist Ohio State University January 14, 2008

Soil Quality, Nutrient Cycling and Soil Fertility. Ray Ward Ward Laboratories, Inc Kearney, NE

Air. Water. Minerals (rocks)

FERTILIZER RECOMMENDATIONS

Sugarbeet Response to Nitrogen Fertilizer Rates K.A. Rykbost and R.L. Dovell

Pete Fandel Illinois Central College llinois Council on Best Management Practices

FDACS Contract No Deliverable Report #3: Corn Fertility Trials Report. January 12, 2016

R.W. Heiniger Vernon G. James Research and Extension Center North Carolina State University

Soil Fertility Management The Optimum Nutrient Balance. Stan Lalor Teagasc, Johnstown Castle. ASA Conference 20 Mar 2014, Portlaoise

Monitoring soil moisture helps refine irrigation management

Keeping the Grass Greener on Your Side of the Fence Understanding Pasture Fertility

LIQUID SWINE MANURE NITROGEN UTILIZATION FOR CROP PRODUCTION 1

Long-Term Soil Fertility Research

Cropping System Nutrient Management

Nutrient Management. Things to Know. Chapter 16. Fertilizer Use Concerns. Goals of Fertilizer Usage. Nutrient Balance in Soil. p.

Objective 1: Manage the demonstration site using common agricultural practices and monitor runoff quantity and quality.

NUTRIENT MANAGEMENT. Figure 1. The availability of P is affected by soil ph.

In-Crop Application of Liquid Hog Manure in Irrigated Potato Production

NATURAL RESOURCES CONSERVATION SERVICE CONSERVATION PRACTICE STANDARD. Nutrient Management. (Acre) Code 590

PROCEEDINGS 2017 Crop Pest Management Short Course & Minnesota Crop Production Retailers Association Trade Show

Interpreting Nitrate Concentration in Tile Drainage Water

A Presentation of the 2011 IA MN SD Drainage Research Forum. November 22, 2011 Okoboji, Iowa

Antonio Ray Asebedo, Eric Adee, and David B. Mengel Department of Agronomy Kansas State University Manhattan, KS 66502

IMPROVING PERFORMANCE OF RYE COVER CROP SYSTEMS

Successful 4R Nutrient Stewardship Extension Techniques: Fertilizer Rate, Source and Placement

Resources Conservation Practices Tillage, Manure Management and Water Quality

NITROGEN MANAGEMENT 2013 YWTG

2016 Southern Consultants Meeting High Yield Soybean Production

DEVELOPMENT OF A NUTRIENT BUDGET APPROACH AND OPTIMIZATION OF FERTILIZER MANAGEMENT IN WALNUT

Objective 1: Manage the demonstration site using common agricultural practices and monitor runoff quantity and quality.

Transcription:

The Role of Soil Testing in Precision Agriculture Fabián G. Fernández Department of Soil, Water, and Climate fabiangf@umn.edu AGVISE Seminars. 10-12 Jan. 2017 Granite Falls, MN Watertown, SD Grand Forks, ND

Soil Testing Soil testing IS a useful tool Soil testing is NOT perfect Don t overvalue its worth Natural processes and management practices can make it difficult to translate test results into fertilizer recommendations/guidelines

Field Soil Test Calibration Soil test values only indicate the available nutrient in the soil, not the fertilizer required to grow a crop Field soil test calibration gives meaning to a soil-test value in terms of nutrient sufficiency and fertilizer need Units of measurement for test results are meaningless without proper field calibration with yield response Follow your state recommendations/guidelines

Dark Colored Prairie Soils" Corn-Soybean Rotation Same yield Same rate Yield N rate

How Much Yield Can We Get Through Mineralization in MN? Percent of Corn Yield at EONR Obtained from the 0-N Check 53% C-C, 71% C-S 52 bu/a 58 lb N/a 218 bu/a 244 lb N/a Ave:116 bu/a 130 lb N/a

Nitrogen management is risk management So many unpredictable variables can make it a game of chance Need to manage based on probability MRTN Rate 108 (120) 133

Adding N in D increase Nmin Adding N in UD decrease Nmin Soybean less Nmin than corn D greater Nmin than UD Yes Yes Yes Yes 191 168 176 163 244 159 229 116

2014 Adding N in D increase Nmin Adding N in UD decrease Nmin Soybean less Nmin than corn D greater Nmin than UD Yes No Yes No 23 10 12 3 249 77 68 17

2015 Adding N in D increase Nmin Adding N in UD decrease Nmin Soybean less Nmin than corn D greater Nmin than UD Yes Yes Yes Yes for fert. trt only 56 28 15 20 120-4 31 2

400 samples 0-12 deep Every 6 distance ½ acre linear transect

TIN Spatial Variability 180 samples (0-6, 6-12, 12-24 ) 10-core composite Each dot is a 10x10 area 90x100 90x100

Overall, 20 samples per 2.5 acres are needed to achieve a TIN estimate with 10% error margin at 0.05 significance level

Can a shallow sample estimate a deeper sample? 0-6 soil samples can be good predictors of 0-12 soils, but the predicting power for 6-12, 12-24, and 0-24 soils is limited

End of Season Soil N

Lamberton, Yield c b b ab ab ab PP: EONR 124 lb N/a, 142 bu/a a Ves loam soil

Soil N with Pre-plant Applications Soil with 4% OM, CEC 24 meq/100g Ves loam soil

Becker, Yield Hubbard loamy sand

Soil N with Pre-plant Applications Soil with 1.6% OM, CEC 8 meq/100g Hubbard loamy sand

(226 lb/a)

Becker 2014; 2015a,b Clara City 2014; Waseca 2014 a,b; Waseca 2015 a,b Clara City 2015; Lamberton 2014; Theilman 2014 Lamberton 2014

V4 Nitrate TIN

V8 Nitrate TIN

V4 soil N (lb ac -1 ) corn yield prediction Soil Grouping NO 3 TIN 0-1' 0-2' 0-1' 0-2' R 2 Plateau R 2 Plateau R 2 Plateau R 2 Plateau Coarse- Textured Fine- Textured 3 Site-yrs 0.31 113 0.38 269 0.40 226 0.36 --- 5 Site-yrs 0.69 124 0.69 191 0.63 154 0.66 --- 3 Site-yrs 0.27 109 0.33 121 0.20 145 0.26 168 1 Site-yrs 0.06 74 0.15 120 0.12 85 0.13 142 V8 soil N (lb ac -1 ) corn yield prediction Soil Grouping NO 3 TIN 0-1' 0-2' 0-1' 0-2' R 2 Plateau R 2 Plateau R 2 Plateau R 2 Plateau Coarse- Textured Fine- Textured 3 Site-yrs 0.32 58 0.42 --- 0.30 119 0.40 --- 5 Site-yrs 0.25 54 0.40 100 0.16 103 0.27 173 3 Site-yrs 0.20 62 0.25 84 0.14 92 0.19 121 1 Site-yrs 0.12 --- 0.13 --- 0.26 --- 0.38 ---

Waseca, MN; clay loam soil

Becker, MN; sandy soil

Lamberton, C-C at 120 lb N/a

Becker, C-C at 120 lb N/a Hubbard loamy sand

Can We Use Crop Sensors To Improve N Management? Application Timing Spatial Variability Temporal Variability

V4 V8 V12 R1 V4 V8 V12 R1 V4 V8 V12 R1 V4 V8 V12 R1 1 Grain Yield Prediction Sensor only 0.8 0.6 R 2 0.4 0.2 0 SPAD GS-NDVI RS-NDVI RS-NDRE

R 2 =0.63 R 2 =0.83 R 2 =0.92

V4 Stage <10% of N needs V3 4% V6 10% V12 30% Silking R1 60% Milk R3 80% Physiological maturity R6 May Jun Jul Aug Sep 100%

Grain Yield Prediction Sensor only V4 GreenSeeker Field of View Adapted from Barmeier and Schmidhalter, (2016)

Relative Sensor Reading (RSR) N Deficiency Determination Sensor only QPLoc V8 1.1 1.05 1 ND = -84 lb N ac -1 RSR = 1.0 ND = -29 lb N ac -1 RSR = 1.01 0.95 0.9 0.85 0.8 SPAD RS-NDVI 0.75 RS-NDRE 0.7-200 -150-100 -50 0 50 Nitrogen Deficiency (kg N ha -1 ) ND = -41 lb N ac -1 RSR = 0.99

Relative Sensor Reading N Deficiency Determination Sensor only QPLoc V12 1.1 1.05 1 ND = -52 lb N ac -1 RSR = 1.0 ND = 27 lb N ac -1 RSR = 1.01 0.95 0.9 0.85 0.8 0.75 RS-NDVI 0.7 RS-NDRE -200-150 -100-50 0 50 Nitrogen Deficiency (kg N ha -1 ) ND = -2 lb N ac -1 RSR = 0.99 SPAD

Prescribed N Rate Variability (kg N ha -1 ) N Deficiency Determination Sensor only QPLoc Relative Sensor Reading (RSR)

N Deficiency Determination Sensor only LINLoc Stage V4 V8 V12 R1 SPAD Linear Q-P Linear Linear GS-NDVI Q-P Q-P ns ns RS-NDVI Linear Linear Linear Linear RS-NDRE Linear Linear Linear Linear R 2 = 0.65 R 2 = 0.64

Soil N sampling timing to improve sensor predictions of N deficiency

R 2 1 Improving Sensor Measurements Sensor only Sensor + Stepwise Sensor + V4 Soil N 0.8 0.6 0.4 0.2 0 SPAD RS-NDVI SPAD RS-NDVI V4 V8

Sampling Depth and Nitrogen Measurement Predicitve Tool AIC* R 2 Sensor only 784 0.34 Sensor + 0-24 TIN 729 0.78 Sensor + 0-12 TIN 735 0.74 - Sensor + 0-24 NO 3 731 0.79 - Sensor + 0-12 NO 3 741 0.76 * Lower AIC means better fit V4 Soil NO 3- @ 0-12 is the best approach to improve predictive power

Soil N only SPAD GS-NDVI RS-NDVI RS-NDRE SPAD GS-NDVI RS-NDVI RS-NDRE SPAD GS-NDVI RS-NDVI RS-NDRE SPAD GS-NDVI RS-NDVI RS-NDRE RMSE (Kg N ha -1 ) Utility of Soil Nitrogen to Improve Predictive Power of N Deficiency 100 80 Sensor only Sensor + Soil Nitrate Soil Nitrate only 60 40 20 0 V4 V8 V12 R1

Take Home Messages Soil N is variable but it is an important tool Canopy sensors can help us manage N: The earlier the sensing the greater the flexibility to apply nitrogen, BUT The earlier the sensing the lesser the predictive power The later the sensing the greater the predictive power, BUT The later the sensing the lesser the flexibility to apply nitrogen and greater potential for yield loss Canopy sensor adjustments with soil N show promise In-season N application is A tool

http://mawrc.org/events

Questions? fabiangf@umn.edu 612-625-7460

2024 © businessdocbox.com Privacy Policy | Terms of Service | Feedback