Tree-Ring Research is the peer-reviewed journal of the Tree Ring Society. The journal was first published in 1934 under the title Tree-Ring Bulletin. In 2001, the title changed to Tree-Ring Research.

Issues from 1934–2006 are freely available on the publications section of the Tree-Ring Society website. The Tree-Ring Society and the Laboratory of Tree-Ring Research at the University of Arizona partnered with the University Libraries to re-digitize back issues for improved searching capabilities and long-term preservation.


Contact the Editor of Tree-Ring Research at editor@treeringsociety.org.

Recent Submissions

  • In Memoriam- Robert E. Bell

    Dean, Jeffrey S. (Tree-Ring Society, 2006)
  • In Memoriam- Henry N. Michael

    Unknown author (Tree-Ring Society, 2006)
  • Lost and Found: the Bristlecone Pine Collection

    Hallman, Christine; Harlan, Tom; Arnott, Howard; Laboratory of Tree-Ring Research, University of Arizona, Tucson, AZ 85721; The Center for Electron Microscopy, University of Texas at Arlington, Arlington, TX 76019 (Tree-Ring Society, 2006)
  • Age Dependence of Spiral Grain in White Oaks (Quercus Alba L.) in Southwestern Illinois

    Rauchfuss, Julia; Speer, James H.; Department of Geography, Geology, and Anthropology, Indiana State University, Terre Haute, IN 47809 (Tree-Ring Society, 2006)
    Dendrochronologists have used the presence of spiral grain as an indicator of old trees for most of the history of the field, although this relationship has been little studied. We examined cross-sections from dead trees and used a 12-mm Haglof Swedish Increment borer to collect cores from living white oak (Quercus alba L.) trees in an Eastern Deciduous Forest stand in southwestern Illinois. Spiral grain is the alignment of wood fibers to the longitudinal axis of trees and is driven by patterns of initial cambial cell division. In this study, we examine environmental factors that may affect spiral grain severity, the usefulness of non-destructive sampling methods (using the 12-mm increment borer), and the relationship between tree age and spiral grain. We tested Brazier’s method (1965) of averaging the spiral grain angle from two radii taken 180 degrees apart (i.e. one diameter in the tree) to get representative grain angles for the whole circumference of a tree at a certain height. The 12-mm increment borer did not produce consistent results in this study; therefore, the collection of cross-sections is advised for the study of spiral grain in white oaks. Brazier’s method should not be used in white oaks and should not be applied universally to all tree species. The severity of spiral grain is expressed in the xylem and may not be expressed in the bark of the tree. Left spiral grain does generally increase in white oaks with age, although this relationship is not always consistent, so a tree without severe spiral grain is not necessarily young.
  • Root-Zone Hydrology: Why Bald-Cypress in Flooded Wetlands Grow More When It Rains

    Davidson, Gregg R.; Laine, Brian C.; Galicki, Stanley J.; Threlkeld, Stephen T.; University of Mississippi, Department of Geology and Geological Engineering, University, MS 38677; Millsaps College, Jackson, MS 39210; University of Mississippi, Department of Biology, University, MS 38677 (Tree-Ring Society, 2006)
    Bald cypress (Taxodium distichum) is known to respond to increases in precipitation with increased radial growth even when rooted in continuously saturated sediments where water is not a growth-limiting factor. Measurements of δ¹⁸O, Cl⁻, ³H and hydraulic head in surface water and shallow groundwater in an oxbow lake-wetland in northern Mississippi show that rapid downward flow of surface water into the root zone is initiated only after precipitation-induced increases in surface water depth exceed a threshold value. Rapid flow of surface water through the root zone has the potential to introduce oxygen to sediments that would otherwise be anoxic, facilitating nutrient uptake and growth. Climatic reconstruction using tree rings from bald cypress in this environment appears possible because increases in precipitation generally correlate well with increases in water level, which in turn enhances the delivery of oxygenated water to the roots.