improving the efficiency of foliar fertilization with urea ... · urea-75% with nbpt compared...

Improving the Efficiency of Foliar Fertilization

with Urea using Urease Inhibitors

Derrick Oosterhuis and Eduardo Kawakami

University of Arkansas

The Problem The cotton crop needs large amounts of nitrogen,

about 125 kg N/ha. 2 – 5% of plant dry matter(Marschner, 1995)

Involved in many metabolic processes, protein and Nucleic Acids etc

N deficiencies result in poor growth and lower yields. Decreased learaea, growth rate, (-) protein, (-) photosynthetic rate, and (-) hydraulic

conductivity , and increased fruit shed, root:shoot ratio, and premature cutout (Radin

and Parker, 1979; Radin and Mauney, 1986; Wullschleger and Oosterhuis, 1990)

Cotton has low N use efficiency, only about 20-30 % of

N applied is recovered by the plant (Karlen et al., 1996; Constable

and Rochester, 1988)

Nitrogen fertilizer is expensive and constitutes > 10%

of total production cost.

Challenge

Improve cotton NUE

Agronomic Aspect

Increase yield

Economic Aspect

Maintain acceptable yields / lower N rates

Environmental Aspect

Decrease eergy input in the system

(NO3-) water table contamination

(N2O and N2) greenhouse gas

www.esri.com

www.rpi.edu

NUE

Agronomic

Recovery Efficiency

Use of Additives to Inhibit Loss of N

Urease Inhibitor - N-(n-butyl) thiophosphoric triamide (NBPT)

Inhibit urea hydrolysis - NH3 volatilization

Nitrification inhibitor - Dicyandiamide (DCD)

Inhibit nitrate formation in the soil - leaching and denitrification

N Uptake = N Availability / N losses

Urea Fertilization

Split application (Constable and Rochester, 1988)

Incorporation at planting (Elberhar and Turpper, 1988)

Slow-release source (Oosterhuis and Howard, 2008)

Crop rotations (Hons et al., 2004)

NBPT

• N-butyl thiophosphoric triamide - Urease Inhibitor

(NH2)2CO +2 H2O + H+ 2NH4 + HCO3- NH3 + CO2 + H2O

Benefit of NBPT to soil applied urea is well understood.

– (-) Phenylphosphorodiamidate (PPD ) in Soybean increased leaf

burn (Krogmeier et al., 1989)

– (±) NBPT in wheat no effect on leaf burn or yield (Rawluk et al., 1999)

But addition of Urease Inhibitor to Foliar Urea ?

(Urease)

Physiological and Yield Responses of Field-Grown Cotton

to Soil Application of Urea with NBPT

Material and Methods

• Location: Marianna, Arkansas

• Cultivar: ST 4554 B2RF – standard management (except N)

• Design : RCBD with 5 treatments and 5 replications

Treatments N Rate

(kg/ha)

N Source Split Applied

Treatment 1 0 -

At 10 days After

Germination

At PHS Stage

Treatment 2 125 (100%) Urea

Treatment 3 94 (75%) Urea

Treatment 4 94 (75%) Urea + NBPT (Agrotain)

Treatment 5 94 (75%) Urea+NBPT+DCD (Super U)

Measurements

Leaf Chlorophyll

N Uptake (DM and N concentration)

N use Efficiency (Estimation - difference method)

N Partitioning (Stem, leaves, capsule wall, seeds)

Fiber Quality

Lint yield (Seedcotton and gin turnout)

N UE = (N Content Treatment X) – (N Content Unfertilized Control) X 100

N Applied

N Use Efficiency

ab

b

a

ab

0

10

20

30

40

50

60

70

80

90

100

Urea (100%) Urea (75 %) Urea(75%) +NBPT Urea(75%)+

NBPT+DCD

NU

E (

% N

ap

pli

ed)

Lint Yield

c

a

b

a ab

0

200

400

600

800

1000

1200

Control Urea (100%) Urea (75 %) Urea(75%)

+NBPT

Urea(75%)+

NBPT+DCD

Lin

t Y

ield

(k

g h

a-1

)

Summary (Field Experiment)

Urea-75% with NBPT

Compared Urea-100% • Chlorophyll

• N Uptake

• N Fertilizer Use Efficiency

• Lint Yield

Application of urea with NBPT increased N fertilizer use efficiency of cotton.

Sub-rates of nitrogen with NBPT maintained cotton growth and yield equal to

the levels of the full recommended urea application

than Urea-75%

To Study the Effects of Foliar Urea Application

with NBPT on Cotton Plants

FOLIAR UREA

• Foliar Nutrient Application

– Main Purpose:

• Supplement Soil Nutrients - root problems

• (+) low cost, rapid response

• (-) foliar burn, chemical incompatibility, limited amount

Results of foliar urea in cotton yields

– Highly variable: Maples and Barker (1993); MacConnell et al., 1998;

Oosterhuis and Bondada (2001); Roberts et al., 2006; Wilborn et al., 2006.

– FACTORS: soil conditions, N availability, fruit load and stress.

• Urea – main N source for foliar N application

– Rapid absorption, low salt index and low phytotoxicity

Field Study with Foliar Fertilization

Field Study

Treatment

Nitrogen

Soil N Application

(kg/ha)

Foliar Nitrogen Application

(12 kg N/ha)

1. 100% Soil N Rate – No Foliar 112 (100%) No

2. 75% Soil N Rate – No Foliar 84 (75%) No

3. 75% Soil N Rate - Foliar Urea 84 (75%) Urea

at FF and FF+2weeks

4. 75% Soil N Rate - Foliar Urea

+ NBPT 84 (75%)

Urea + NBPT (0.84%)

at FF and FF+2weeks

• Location: Lon Mann Cotton Research Station, Marianna, AR

• Cultivar: ST 4554 B2RF – Standard Management (Except N)

• Design : RCBD with 4 treatments and 5 replications

• Measurement:

• Seedcotton Yield (machine picked)

Results

A

B B

A

0

200

400

600

800

1000

1200

1400

1600

1800

2000

100% N Rate - No

foliar

75% N Rate - No

foliar

75% N Rate -

Foliar Urea

75% N Rate -

Foliar Urea+NBPT

See

dco

tto

n Y

ield

(k

g h

a-1

) Seedcotton Yield

Growth Room Study

Growth Room Study

Treatment Foliar Nitrogen Application

(12 kg N/ha)

1 – Control No

2 – Foliar Urea Foliar Urea

3 – Foliar Urea + NBPT Urea + NBPT (0.84%)

4 - Foliar NBPT Check 0.84 % of NBPT

• Location: AR Agricultural Research Station, Fayetteville, AR

• Environment: 30/20oC day/night temperature, 14 h photoperiod

• Cultivar: ST 4554 B2RF

• Design : CRD with 4 treatments and 5 replications

No soil N – foliar urea treatments applied at pinhead-square

• Membrane Decomposition:

Malondialdehide (MDA)

• Cell Integrity :

Membrane Leakage (% Injury)

• Photosynthesis:

Portable photosynthesis system Licor 6200

• Urea Assimilation:

Urea, Urease, Glutamine Synthetase and Protein

Time: 2 h and 24 h after treatment application

Measurements

A A AB B

A A AB

B

-0.05

0.05

0.15

0.25

0.35

0.45

0.55

0.65

0.75

0

5

10

15

20

25

30

35

40

Control Urea Urea + NBPT NBPT

Lea

ka

ge

(% I

nju

ry)

MD

A (

nm

ol

g-1

FW

)

A A AB

B

0

5

10

15

20

25

30

35

40

Control Urea Urea + NBPT NBPT

MD

A (

nm

ol

g-1

FW

) Results

Leaf Membrane Degradation and Leakage

Results Leaf Urease

B

B

B

B B

A

B B

0.00

0.00

0.00

0.01

0.01

0.01

0.01

0.01

Control Urea Urea +

NBPT

NBPT Control Urea Urea +

NBPT

NBPT

Ure

ase

(u

nit

s g

-1 F

W)

2h After Application 24 h After Application

Results Leaf Urea Concentration

BC

AB

A

C

0

0.5

1

1.5

2

2.5

3

3.5

Control Urea Urea + NBPT NBPT

Ure

a C

on

ten

t (m

M g

-1 F

W)

Arginine

Urea Glutamine

Glutamate

NH3

+

CO2

Glutamine

Synthetase Urease

Phytotoxicity Cell Membrane

Photosynthesis

Ornithine

Cycle

?

Leaf Urea Assimilation

Protein

Urea Glutamine

Glutamate

NH3

+

CO2

Glutamine

Synthetase Urease

Phytotoxicity Cell Membrane

Photosynthesis

?

+

NBPT

X X

Protein

Foliar Urea

Results Interpretation

Summary

• Field Experiment with Urea and NBPT

– Cotton yield

• Growth Room Studies

– Urease Activity

– Trends:

• Urea

• MDA and Membrane Leakage

• Field Experiment with Foliar Urea and NBPT

– Increase in cotton yield

Addition of NBPT to Urea Resulted in:

Addition of NBPT to foliar applied urea inhibits leaf

urease activity and has the potential of increasing

cotton yield.

This study will be repeated to confirm findings.

Conclusion

Acknowledgements

Fluid Fertilizer Foundation

Arkansas Agricultural Experiment Station

Cotton Incorporated