Low‐input sustainable turf (LIST) management represents a resource‐efficient option in maintaining uniform, persistent turf. What species are best suited to such management needs to be established. To this end, 12 hardy species were evaluated for 3 yr in Illinois, Indiana, Iowa, Michigan, Missouri, Ohio, and Wisconsin: crested wheatgrass [Agropyron desertorum (Fisch. ex Link) Schult. ‘Fairway’, ‘Ephraim’, and ‘Ruff’], streambank wheatgrass [Agropyron riparium Scribn. & Smith ‘Sodar’; syn. Elymus lanceolatus (Scribn. & J.G. Smith) Gould subsp. lanceolatus], Canada bluegrass (Poa compressa L. ‘Reubens’), hard fescue [Festuca ovina var. duriuscula (L.) Koch ‘Durar’; syn. F. lemanii T. Bastard], sheep fescue (F. ovina L. ‘Covar’ and common), tall fescue (F. arundinacea Schreb. ‘Alta’), bulbous bluegrass (P. bulbosa L.), alpine bluegrass (P. alpina L.), redtop (Agrostis alba L. ‘Reton’; Agrostis gigantea Roth), roughstalk bluegrass (P. trivialis L. ‘Colt’), colonial bentgrass (Agrostis tenuis Sibth. ‘Exeter’; syn. Agrostis capillaris L.), and buffalograss [Buchlöe dactyhides (Nutt.) Engelm. ‘Texoka’ and ‘NE‐315’]. AH were field‐established and compared at three mowing heights: 3.8 cm, 7.6 cm, and no mowing. Quality ratings were based on uniform persistence. Tall fescue and common sheep fescue were the best and most broadly adapted to LIST. In Iowa, hard fescue, Canada bluegrass, and crested wheatgrass also did well. Colonial bentgrass was best adapted in Missouri. Redtop and roughstalk bluegrass grew better in a north‐south area from Wisconsin through central Illinois to Missouri. The buffalograsses excelled in Ohio and southern Illinois. Over all species, the 7.6‐cm mowing height allowed the best turf quality. Specifically, tall fescue, colonial bentgrass, redtop, and common sheep fescue performed best at the 7.6‐cm mowing height. Covar sheep fescue, hard fescue, Canada bluegrass, and Fairway crested wheatgrass could not maintain persistent stands under the 3.8‐cm mowing height. No mowing resulted in intermediate levels of quality with all species. A 7.6‐cm mowing height would be appropriate for testing species in LIST within the seven‐state region used in this study.
Inorganic soil amendments have been suggested for use in turf to alleviate soil compaction, increase water retention and hydraulic conductivity, and improve many other soil physical properties. The objectives of this study were to determine the effects of ceramic, porous ceramic clay (PCC), calcined diatomaceous earth (CDE), and polymer coated clay (PC) on the physical characteristics of sand‐based media and to determine the effects of these amendments on bulk density following freeze–thaw treatments. Inorganic materials were added to a sand‐based golf green at 10% on a volumetric basis during construction in 1996. Data collected from the field included saturated hydraulic conductivity (Ksat), water retention, water release curves, bulk density and total porosity on compacted samples collected at construction, and undisturbed samples collected from the treated plots 1 and 2 yr after establishment. The PCC treatment had an 8 and 7% higher cation‐exchange capacity (CEC) than the control in 1997 and 1998, respectively. The PCC increased the Ksat by 26 and 20% in the compacted and undisturbed samples, respectively, in 1998. The CDE increased water retention by 13% in both compacted and undisturbed samples. Saturated hydraulic conductivity of the sand–inorganic mixtures decreased in the 2 yr, although some increases in Ksat were observed each spring. The Ksat of plots receiving all inorganic amendments was reduced by 75% in November of 1998. The Ksat values in the spring of 1999 increased from the low levels of 1998 by 19% (PC), 44% (control), 59% (ceramic), 72% (PCC), and 82% (CDE). The changes of Ksat over the winter may have been induced by freezing and thawing. These changes may not necessarily be caused by total porosity increases; instead they may be caused by increases in macropores. This hypothesis was further tested in the laboratory in a freeze–thaw study conducted in 1999. The PC, control, CDE, and PCC decreased bulk density by 10.7, 7.2, 2.5, and 2.2%, respectively, following a freeze–thaw cycle.
Heat Tolearance Screening of Field‐Grown Cultivars of Kentucky Bluegrass and Perennial Ryegrass1
The quality of cool‐season turfgrasses frequently declines during periods of high temperature stress. Simple tests are needed to rapidly identify heat tolerant germplasm for incorporation into breeding programs. Facilitative screening tests have been devised, however, in the few studies that have been performed only immature and greenhouse or growth chamber‐grown plants have been evaluated. To be of practical value, results of screening tests, employing plants grown under artificial conditions, should correlate closely with results of tests involving field grown plants. The objective of this research was to evaluate the heat tolerance of several cultivars of Kentucky bluegrass (Poa pratensis L.) and perennial ryegrass (Lolium perenne L.) grown in the field under four different regimes of N fertilization (0, 98,148, or 196 kg ha−1 yr−1) in a Typic Hapludults, fine silty, mixed mesic soil for comparison with published results in which greenhouse and growth chamber‐grown material was used. On six sampling dates, plants representing all cultivar and N combinations were exposed to 42, 44, and 46 °C by immersion in a water bath. Heat tolerance of the cultivars was compared using the mean percent recovery weight for the three temperatures. The Kentucky bluegrass cvs. Sydsport, Vantage, and Pennstar were more heat tolerant than the perennial ryegrass cvs. Pennfine, Citation, and Caravelle. When data were averaged over 2 years, it was shown that Sydsport was significantly more heat tolerant than all other genera and cultivars tested. Pennfine had higher recovery weights than the other two ryegrasses on four of six sampling dates. When data were averaged, however, no significant heat tolerance differences among the ryegrasses were discerned. The results from the screening of field grown material followed the same trends as published results using greenhouse or growth chamber‐grown samples. This investigation therefore provides strong evidence that laboratory screening tests may be used to identify accurately and rapidly heat tolerant cultivars of Kentucky bluegrass and possibly perennial ryegrass. The overall heat tolerance of the cultivars on each sampling date correlated with the amount of precipitation (r=−0.91) and the average high temperature (r=0.93) for the period just prior to and during sampling. The moderate N fertility regimes imposed had little effect on the heat tolerance of the grasses.
Availability of newer, more competitive cool-season grasses has renewed interest in persistent, balanced warm-and cool-season species mixtures for sports turf. In this Missouri study, one-time overseedings of blends and mixtures of Kentucky bluegrass (Poa praJensis L.), perennial ryegrass (Lolium perenne L.), Chewings fescue (Festuca rubra L. subsp. commutlltll Gaud.), hard fescue (Festuca longifolia Thuill.), and creeping red fescue (Festuca rubra L. subsp. rubra Gaud.) were made on established plots of KSU S-16 and 'Midiron' bermudagrass [Cynodon dactylon (L.) Pers.). One-half of each plot was subjected to simulated traffic beginning 18 mon after overseeding, using a modified Brinkman traffic simulator. Quality of four mixtures (bermudagrass + Kentucky bluegrass, bermudagrass + perennial ryegrass, bermudagrass + perennial ryegrass + Kentucky bluegrass, and bermudagrass + perennial ryegrass + Kentucky bluegrass + Chewings fescue) remained in an acceptable range at most observation dates after 3 yr of spring-and-fall traffic. Bermudagrass control plots were in poor or marginal condition at most observation dates during the same period. Bermudagrass plus fine leaf fescues were severely damaged by simulated traffic. Quality of turf receiving no simulated traffic was generally good and varied seasonally in response to changing environmental conditions. Higher-impact absorption measurements, based on peak deceleration (maximum g) on turf receiving simulated traffic vs. no traffic, were consistent with decreasing thatch and verdure. Traction (in N·m) decreased on trafficked turf as thatch and aboveground biomass deteriorated. Kentucky bluegrass and perennial ryegrass dominated mixtures with bermudagrass after 3 yr, and showed good tolerance to simulated traffic.
Influence of Core Aerification, Topdressing, and Nitrogen on Mat, Roots, and Quality of ‘Meyer’ Zoysiagrass
Thatch accumulation is a common occurrence in lawn and sports turf and is usually detrimental. We initiated aerification, topdressing, and N treatments in July 1987, to investigate their influence on thatch, mat, quality, and color of zoysiagrass (Zoysia japonica Steud. cv. Meyer). Turfgrass color responses to N were positive and strongly linear. Turfgrass quality was generally good to excellent in response to N. However, trends were not as well defined as color responses and varied according to month and year. The aerification + topdressing combination according to N level was nonsignificant for turfgrass quality in all months and significant for color only in October. Weight of mat, which consisted mostly of rhizomes, and root weights declined linearly in response to increasing N. The root weight response is consistent with research reports of C3 turfgrasses but inconsistent with earlier studies of C4 turfgrasses where root weights increased with increasing N. Mat depth averaged over N was equal in response to topdressing vs. no topdressing. Root weights and mat weight were significantly greater with topdressing. Mat organic matter (OM) was greater with no topdressing. Our results suggest that maintenance of zoysiagrass with only enough N to provide acceptable turfgrass density and color will give the best root development in nonsandy soils. Annual topdressing with soil similar to that of the growing site may further enhance root development.
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