Short-stature and tall maize hybrids have a similar yield response to split-rate vs. pre-plant N applications, but differ in biomass and nitrogen partitioning

Kevin R. Kosola, Magen S. Eller, Frank G. Dohleman, Lia Olmedo-Pico, Brad Bernhard, Eric Winans, Ty J. Barten, Lillian Brzostowski, Lesley R. Murphy, Chiyu Gu, Lyle Ralston, Mike Hall, Kelly M. Gillespie, David Mack, Frederick E. Below, Tony J. Vyn

Research output: Contribution to journalArticlepeer-review

Abstract

Context: Development of semi-dwarf wheat (Triticum aestivum) and rice (Oryza sativa) led to increased yields and agronomic efficiencies with less lodging. While these short-stature cereals have become common in global crop production, commercial maize (Zea mays L.) hybrids remain tall. There is no information currently available on plant N uptake or yield responses to N timing for short stature maize hybrids. Objective: We tested three hypotheses on short-stature and tall maize hybrids 1) short-stature maize hybrids would have similar yield response to in-season N application compared to tall hybrids, 2) short-stature maize hybrids would have similar dry matter and N uptake patterns to tall hybrids, and 3) there would be significant partitioning differences between short-stature and tall hybrids in dry matter and N within the plants at multiple growth stages. Methods: In ten side-by-side field trials across eight site-years in the Midwestern USA, we tested the yield response and underlying nitrogen physiology of short-stature maize hybrids and tall comparators to split-rate N application. Results: We show that split-rate application of 50% of the total N at mid-vegetative stages (V6) averaged 0.24 t ha−1 more grain yield across 10 field trials (positive yield response in 6 out of 10 trials) compared to a single 100% up-front N application, with the same pattern for short-stature and tall hybrids. In both hybrid statures, V6 N applications showed more frequent improvement in grain yield than V12 N applications. Total N uptake at maturity was not different between short-stature hybrids and their tall counterparts (p = 0.62). N partitioning differed between short-stature and tall hybrids; leaves in short-stature hybrids had 5% higher N concentration and 13% more N content in early vegetative development, stalks had 18–27% less dry matter and 5–25% less N content, depending on growth stage, while R1 ears averaged 18% more dry matter and N accumulation (p < 0.10 in all cases). At maturity short-stature hybrids had 4% higher harvest index and 3% higher N harvest index (p < 0.10). Conclusions: Based on these results, we expect that N management recommendations in short-stature maize hybrids would be similar to their tall counterparts, but that short stature mitigates logistical risk by providing more flexibility for in-season N applications. Implications: This study provides a unique, robust dataset on yield and physiological response to split-rate N treatments in commercially relevant maize hybrids.

Original languageEnglish (US)
Article number108880
JournalField Crops Research
Volume295
DOIs
StatePublished - May 1 2023

Keywords

  • Harvest index
  • Maize
  • Nitrogen accumulation
  • Nitrogen application timing
  • Short-stature
  • Split-rate nitrogen
  • Yield

ASJC Scopus subject areas

  • Agronomy and Crop Science
  • Soil Science

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