Your search keyword '"Arnold W. Schumann"' showing total 12 results

1. Leaching losses from blueberries grown in sandy soils amended with pine bark

Author

Davie M. Kadyampakeni, James P. Syvertsen, Wije Bandaranayake, and Arnold W. Schumann

Subjects

Environmental Engineering, Blueberry Plants, 010501 environmental sciences, Management, Monitoring, Policy and Law, 01 natural sciences, Soil, Nutrient, Sand, Plant Bark, Cultivar, Leaching (agriculture), Waste Management and Disposal, Subsoil, 0105 earth and related environmental sciences, Water Science and Technology, biology, 04 agricultural and veterinary sciences, Pinus, biology.organism_classification, Pollution, Horticulture, Soil water, 040103 agronomy & agriculture, 0401 agriculture, forestry, and fisheries, Environmental science, Vaccinium

Abstract

Leaching of irrigation water from blueberry (Vaccinium spp.) plants intensifies when sandy soils are amended with pine (Pinus spp.) bark. In a greenhouse study, leaching fractions of water (LFW) and nutrients (LFN) were determined from two blueberry (V. corymbosum L.) cultivars, 'Emerald' and 'Jewel', grown in biochar-treated and nontreated sandy subsoil and irrigated with drip emitters using one of three pulse frequencies in a factorial design. The LFW was 50% under Emerald and 20% under Jewel, which has a more extensive root system. When the frequency of same volume of irrigation was increased from 2 (F2) to 10 (F10) pulses per day, the average LFW decreased from 46 to 30%. The LFN from a single fertigation was much lower than the total LFN after 6 d of irrigations applied between two fertigation events. The LFN increased linearly with LFW. Amending subsoil with 2% biochar increased soil pH, limited root growth, and did not reduce nutrient leaching. Eighteen months after plant establishment, 1.9% of applied NO

Published

2020

2. Detection of broadleaf weeds growing in turfgrass with convolutional neural networks

Author

Nathan S. Boyd, Shaun M. Sharpe, Jialin Yu, and Arnold W. Schumann

Subjects

0106 biological sciences, biology, business.industry, Deep learning, General Medicine, Cynodon dactylon, biology.organism_classification, Weed control, 01 natural sciences, Convolutional neural network, 010602 entomology, Oenothera laciniata, Agronomy, Insect Science, Artificial intelligence, Weed, business, Agronomy and Crop Science, Paspalum notatum, 010606 plant biology & botany, Mathematics, Field conditions

Abstract

BACKGROUND Weed infestations reduce turfgrass aesthetics and uniformity. Postemergence (POST) herbicides are applied uniformly on turfgrass, hence areas without weeds are also sprayed. Deep learning, particularly the architecture of convolutional neural network (CNN), is a state-of-art approach to recognition of images and objects. In this paper, we report deep learning CNN (DL-CNN) models that are remarkably accurate at detection of broadleaf weeds in turfgrasses. RESULTS VGGNet was the best model for detection of various broadleaf weeds growing in dormant bermudagrass [Cynodon dactylon (L.)] and DetectNet was the best model for detection of cutleaf evening-primrose (Oenothera laciniata Hill) in bahiagrass (Paspalum notatum Flugge) when the learning rate policy was exponential decay. These models achieved high F1 scores (>0.99) and overall accuracy (>0.99), with recall values of 1.00 in the testing datasets. CONCLUSION The results of the present research demonstrate the potential for detection of broadleaf weed using DL-CNN models for detection of broadleaf weeds in turfgrass systems. Further research is required to evaluate weed control in field conditions using these models for in situ video input in conjunction with a smart sprayer. © 2019 Society of Chemical Industry.

Published

2019

3. Modeling Water and Nutrient Movement in Sandy Soils Using HYDRUS-2D

Author

James W. Jawitz, Kelly T. Morgan, Davie M. Kadyampakeni, Peter Nkedi-Kizza, and Arnold W. Schumann

Subjects

Irrigation, Fertigation, Hydrus, Agricultural Irrigation, Environmental Engineering, Nitrogen, 0208 environmental biotechnology, 02 engineering and technology, Drip irrigation, Management, Monitoring, Policy and Law, Soil, Nutrient, Nutrient leaching, Water Movements, Soil Pollutants, Fertilizers, Waste Management and Disposal, Water Science and Technology, Hydrology, Agriculture, Phosphorus, 04 agricultural and veterinary sciences, Pollution, 020801 environmental engineering, Models, Chemical, Soil water, Florida, 040103 agronomy & agriculture, 0401 agriculture, forestry, and fisheries, Environmental science, Water Pollutants, Chemical, Environmental Monitoring

Abstract

Models help to describe and predict complex processes and scenarios that are difficult to understand or measure in environmental management systems. Thus, model simulations were performed (i) to calibrate HYDRUS-2D for water and solute movement as a possible decision support system for Candler and Immokalee fine sand using data from microsprinkler and drip irrigation methods, (ii) to validate the performance of HYDRUS-2D using field data of microsprinkler and drip irrigation methods, and (iii) to investigate Br, NO, and water movement using annual or seasonal weather data and variable fertigation scenarios. The model showed reasonably good agreement between measured and simulated values for soil water content ( = 0.87-1.00), Br ( = 0.63-0.96), NO-N ( = 0.66-0.98), P ( = 0.25-0.78), and K ( = 0.44-0.99) movement. The model could be successfully used for scheduling irrigation and predicting nutrient leaching for both microsprinkler and drip irrigation systems on Florida's sandy soils.

Published

2018

4. Water Use in Drip- and Microsprinkler-Irrigated Citrus Trees

Author

Arnold W. Schumann, Davie M. Kadyampakeni, Peter Nkedi-Kizza, Thomas A. Obreza, and Kelly T. Morgan

Subjects

Field capacity, Hydrology, Irrigation, Nutrient, Agronomy, Soil water, Soil Science, Environmental science, Root system, Drip irrigation, Water use, Entisol

Abstract

Advanced citrus production systems (ACPS) are being evaluated in Florida citrus groves for sustainable, profitable citrus production. The ACPS practic- es provide tight control over water and nutrient-mediated plant growth and development using irrigation to train the root system into a limited area and fertigate with daily nutrient requirements. Thus, a study was undertaken to (i) compare daily water use using the stem heat balance method on ≤5-yr-old citrus trees using two ACPS irrigation methods (using daily drip and micro- sprinkler irrigation) and conventional irrigation on two Florida sandy soils; (ii) determine relationships between hourly sap flow and time of day, and daily water use vs. total available soil water in the irrigated zone; and (iii) evaluate the effect of Huanglongbing (HLB) disease on water uptake. The sap flow data suggest that intensive drip and microsprinkler irrigation systems resulted in similar or higher water use than conventional irrigation. Water use was greater (P ≤ 0.01) with ACPS than conventional microsprinkler practice irrigation in summer 2010, spring 2011, and late summer 2011 at the Entisol site. Water use was 29 to 38% greater using ACPS than conventional irriga- tion in June 2011 at the Spodosol site, albeit, not significantly different. All irrigation systems showed water contents close to field capacity at both sites, indicating that water was nonlimiting in each irrigation system despite having different irrigation schedules. The high water uptake using intensive irrigation systems is ascribed to frequent irrigation and improved water distribution in the irrigated zone.

Published

2014

5. Ammonium and nitrate distribution in soil using drip and microsprinkler irrigation for citrus

Author

Davie M. Kadyampakeni, Kelly T. Morgan, Arnold W. Schumann, Peter Nkedi-Kizza, and Kamal Mahmoud

Subjects

Irrigation, chemistry.chemical_compound, Agronomy, Nitrate, chemistry, business.industry, Distribution (economics), Environmental science, Ammonium, General Medicine, Drip irrigation, business

Published

2014

6. Ammonium and Nitrate Distribution in Soil Using Drip and Microsprinkler Irrigation for Citrus Production

Author

Kamal Mahmoud, Davie M. Kadyampakeni, Peter Nkedi-Kizza, Kelly T. Morgan, and Arnold W. Schumann

Subjects

chemistry.chemical_compound, Irrigation, Agronomy, chemistry, Nitrate, Nutrient management, Information storage, Soil Science, Environmental science, Ammonium, Drip irrigation

Abstract

Soil Sci. Soc. Am. J. 78:645–654 doi:10.2136/sssaj2013.07.0319 Received 31 July 2013. *Corresponding author (dkadyampakeni@ufl.edu). © Soil Science Society of America, 5585 Guilford Rd., Madison WI 53711 USA All rights reserved. No part of this periodical may be reproduced or transmitted in any form or by any means, electronic or mechanical, including photocopying, recording, or any information storage and retrieval system, without permission in writing from the publisher. Permission for printing and for reprinting the material contained herein has been obtained by the publisher. Ammonium and Nitrate Distribution in Soil Using Drip and Microsprinkler Irrigation for Citrus Production Nutrient Management & Soil & Plant Analysis

Published

2014

7. Phosphorus and Potassium Distribution and Adsorption on Two Florida Sandy Soils

Author

Peter Nkedi-Kizza, Kamal Mahmoud, Davie M. Kadyampakeni, Kelly T. Morgan, and Arnold W. Schumann

Subjects

Fertigation, Irrigation, Phosphorus, Soil Science, chemistry.chemical_element, engineering.material, Nutrient, chemistry, Agronomy, Soil water, engineering, DNS root zone, Environmental science, Fertilizer, Water quality

Abstract

Phosphorus and K are critical nutrients in citrus production whose deficiency or excess can affect yield, fruit quality, and water quality. However, no study has been conducted to understand the nutrient distribution in the root zone using intensive fertigation practices in Florida’s sandy soils. Thus, experiments were conducted to: (i) compare the performance of intensively managed drip and microsprinkler fertigation systems with conventional grower practices; and (ii) determine P and K adsorption based on recommended fertilizer application rates on Candler (hyperthermic, uncoated Lamellic Quartzipsamments) and Immokalee (sandy, siliceous, hyperthermic Arenic Alaquods) fine sands. Phosphorus and K were applied and tracked with time and distance from point of application. Soil P on Immokalee soil was 27 to 163% higher in the irrigated zone for drip and restricted microsprinkler fertigation than the unirrigated zone and up to 70% greater in the 0- to 15-cm depth of the irrigated zone than conventional microsprinkler practices. Soil K was 5 to 61% greater in the upper 0- to 15-cm of the irrigated zone with drip and microsprinkler fertigation than conventional microsprinkler practices on Immokalee fine sand. Soil P and K on Candler also differed by fertilization method, depth, and between irrigated and unirrigated zones. The linearized P sorption coefficients for Candler were three- to fourfold greater than the corresponding depths for Immokalee, while sorption coefficients for K were similar for the two soils. It is unlikely that P or K would present a water quality concern as strictly related to irrigation practice. The P application rate for Candler should be lowered for young trees (

Published

2014

8. Analyzing the efficiency of soil amendments and irrigation for plant production on heterogeneous sandy soils under greenhouse conditions

Author

Arnold W. Schumann, Jerry B. Sartain, Sanjay Shukla, Thomas A. Obreza, Willie G. Harris, and Kirandeep K. Mann

Subjects

Irrigation, biology, Randomized block design, Amendment, Soil Science, Plant Science, Sorghum, biology.organism_classification, Field capacity, Soil conditioner, Agronomy, Soil water, Environmental science, Water content

Abstract

Variability in soil properties is a complication for fertilization, irrigation, and amendment application. However, only limited progress has been made in managing soil variability for uniform productivity and increased water-use efficiency. This study was designed to ameliorate the poor-productivity areas of the variable sandy soils in Florida citrus groves by using frequent small irrigations and applying organic and inorganic soil amendments. Two greenhouse experiments were set up with sorghum and radish as bioassay crops in a randomized complete block design (RCBD). The factors studied were two soil-productivity classes (very poor and very good), two water contents (50% and 100% of field capacity), two amendments (phosphatic clay and Fe humate), and two amendment rates (10 and 25 g kg–1 for sorghum and 50 and 100 g kg–1 for radish). Amendments applied at 50 and 100 g kg–1 increased the water-holding capacity (WHC) of poor soil by 2- to 6-fold, respectively. The lower rates (10 and 25 g kg–1) of amendments were not effective in enhancing sorghum growth. The higher rates (50 and 100 g kg–1) doubled the radish growth as compared to the control. The results indicate that rates greater than 50 g kg–1 of both amendments were effective in improving water retention and increasing productivity. Irrigation treatment of 100% of field capacity (FC) increased the sorghum and radish growth by about 2-fold as compared with the 50%–water content treatment. The results suggest that the root-zone water content should be maintained near FC by frequent small irrigations to enhance water availability in excessively drained sandy soils. In addition, application of soil amendments in the root zone can enhance the water retention of these soils. Furthermore, managing variable sandy soils with WHC-based irrigation can increase water uptake and crop production in the poor areas of the grove.

Published

2011

9. Spatial Variability of Soil Chemical and Biological Properties in Florida Citrus Production

Author

Kirandeep K. Mann, Max Teplitski, Willie G. Harris, Arnold W. Schumann, Jerry B. Sartain, and Thomas A. Obreza

Subjects

Agronomy, Agroforestry, Biological property, Soil Science, Production (economics), Environmental science, Spatial variability

Published

2011

10. Chemical Evaluation of Nutrient Supply From Fly Ash-Biosolids Mixtures

Author

Malcolm E. Sumner and Arnold W. Schumann

Subjects

Biosolids, Chemistry, Soil Science, Mineralogy, Biodegradable waste, engineering.material, Nutrient, Environmental chemistry, Fly ash, engineering, Qualitative inorganic analysis, Fertilizer, Organic fertilizer, Plant nutrition

Abstract

Prediction of plant nutrient supply from fly ash and biosolids (sewage sludge and poultry manure) may enhance their agricultural use as crop fertilizer. Two mild extraction methods (42-d equilibration with ion-exchange resins; 2-d equilibration with pH 4.8 buffered nutrient solution) and analysis of nutrient data by the Diagnosis and Recommendation Integrated System (DRIS) were tested with 29 fly ash samples, four biosolids samples, and their mixtures. The resin method was useful for major nutrient (N, P, K, Ca, Mg, S) extraction from fly ashes and organic materials, particularly where mineralizable fractions of N and P under aerobic conditions are required. However, resins were inefficient in extracting P from high-Fe sewage sludges because organic waste samples caused premature failure of semipermeable membranes and fouling of resins. Extraction of fly ash with dilute buffered nutrient solution was more successful because micronutrient recovery was improved, major nutrients were correlated to the resin method, both addition and removal of nutrients were recorded. DRIS analysis was possible, and equilibration was rapid (2 d). The overall nutrient supply from these extremely variable fly ashes was: Cu = Fe {approx} B {approx} Mo > Ca > S > Zn >> Mn > N > Mg > Pmore » > K (high micronutrient, low major nutrient supply). For biosolids, the major nutrients ranked: P > N {approx} Ca > S > Mg > K (sewage sludges), and N > Ca {approx} K > P > Mg > S (poultry manures). In mixtures of fly ash with 26% sewage sludge the order was: Ca > S > N > Mg > P > K, while in mixtures of fly ash and 13% poultry manure, the nutrients ranked: Ca > K {approx} N {approx} S > Mg > P. Optimal plant nutrition (especially N-P-K balancing) should be possible by mixing these three waste materials.« less

Published

2000

11. Plant Nutrient Availability from Mixtures of Fly Ashes and Biosolids

Author

Arnold W. Schumann and Malcolm E. Sumner

Subjects

Environmental Engineering, Biosolids, fungi, Management, Monitoring, Policy and Law, engineering.material, Pollution, Soil management, Nutrient, Agronomy, Fly ash, engineering, Environmental science, Fertilizer, Waste Management and Disposal, Plant nutrition, Organic fertilizer, Sludge, Water Science and Technology

Abstract

Nutrient imbalances, both deficiencies and excesses, are one reason for the poor acceptance of waste materials as fertilizer substitutes. Two greenhouse experiments were established using 24 different fly ashes with sewage sludge and poultry manure to estimate nutrient availability and imbalances to maize (Zea mays L.). The maximum maize growth attained with fly ash amendment of 80 Mg ha{sup {minus}1} was significantly less (50%) than a fertilized control treatment. The additional growth improvements obtained from mixtures with sewage sludge or poultry manure ranged from 30 to 49% and 30 to 71%, respectively. Organic materials applied alone achieved only 54 and 62% of the maximum potential, while growth on poultry manure mixtures was up to 94% of the best performing fertilized treatment. Results of foliage and soil analyses suggest that P and K were the main nutrient deficiencies, while B phytotoxicity and an imbalance in the K/Ca/Mg ratio also were likely causes of plant growth reduction. Fly ashes did not contribute significant P or K to correct soil and plant deficiencies, but more often exacerbated the imbalances by precipitation or adsorption of soil P. Sewage sludge mixed at 26% and poultry manure at 13% (DM) with fly ash had negligible effectmore » on availability of phytotoxic fly ash B, but were good sources of P (both) and K (poultry manure). Good agreement between plant nutrition in pot experiments and previous laboratory extraction studies implies that chemical analysis, efficient formulation and optimized application rates may overcome nutrient limitations for use of wastes as fertilizer substitutes.« less

Published

1999

12. Trace Element Solubility from Land Application of Fly Ash/Organic Waste Mixtures

Author

Malcolm E. Sumner, William P. Miller, Arnold W. Schumann, and Brian P. Jackson

Subjects

Environmental Engineering, Chemistry, Amendment, Trace element, Lessivage, Biodegradable waste, Management, Monitoring, Policy and Law, Pollution, Agronomy, Fly ash, Environmental chemistry, Phytotoxicity, Solubility, Waste Management and Disposal, Poultry litter, Water Science and Technology

Abstract

Use of fly ash (FA) as a soil amendment is hindered by a lack of macronutrients in the ash and concerns about trace element availability. Mixing FA with an organic waste can increase macronutrients while reducing odor and improving material handling, but the trace element solubility requires investigation. This study examined the trace element solubility and availability resulting from land application of such mixed wastes. Two FAs were applied as mixtures with either poultry litter (PL) or sewage sludge (SS) to field plots at rates 100 and 120 Mg ha -1 for FA/PL and FA/SS, respectively. Suction cup lysimeters were used to collect soil solution, and trace element uptake was monitored in maize (Zea mays L.) leaf tissue and grain. Soluble B was initially >25 mg L for one high B FA/PL mixture and led to initial toxicity in seedlings. Soil solution concentrations of dissolved C, P, As, Se, Mo, Cu, and Cr were increased in FA/PL field plots. For P, C, As, and Cu, increased solubility was due to increased load in the FA/PL mixtures, while for Mo, Se, and Cr, mixing fly ash with poultry litter appeared to increase solubilization from the ash when compared with an equivalent mass of FA mixed with sewage. Leaf tissue data confirmed an increase in available As from the FA/PL mixtures, while leaf tissue Se was more dependent on the total Se concentrations of the ash.

Published

1999