"Season creep" - American Nurseryman Magazine - Horticulture Magazine and Horticulture Books - "Season creep"

"Season creep"

2/14/2013

Some thought-provoking-and perhaps provocative-information from a group called "Climate Nexus," which can be accessed at www.climatenexus.org.

"Season Creep" and Its Impacts
As the planet warms, signs of spring are arriving sooner, while winters are becoming shorter and milder. This phenomenon is informally known as "season creep" in that the onset of spring is creeping earlier. The study of the timing of spring events is called phenology.
Season creep manifests in various ways. For example, flowers bloom earlier, including a week earlier on average for Washington's famous cherry blossoms. Hardwood forests hold their green leaves 10 days longer. Spring snowmelts have shifted so that peak melt flow now arrives one to four weeks earlier. Growing seasons have lengthened by 10-20 days, and bird species are leaving earlier for their migrations.
Although much research is still underway, the signs point to a causal relationship between carbon dioxide, global warming, and the manifestations of season creep. In one study, natural variability explained only one-third the rate of "creep" in the arrival of spring. Likewise, decadal oscillations, or natural cycles of change, could not fully account for early streamflow, and researchers found leaf retention in hardwood forests was "consistent with other studies documenting measurable climate change effects."
A shorter winter may sound great to those who eagerly await gardening season, but in many ways these changes negatively affect gardeners. Here's how:
Frost vulnerability: High spring temperatures can create earlier flowering schedules. This leaves blooms at risk of a freeze. Although it sounds counter-intuitive given the "global warming" we're experiencing, cold snaps are still projected to happen even during warmer-than-average springs. This is of greatest concern to commercial fruit farmers, who lose their crop if a frost destroys the flowers. Yet hobbyists who grow fruit and flowers will also be affected. For example, mountain-dwelling wildflowers are experiencing frequent frost damage due to early blooming.
Species mismatch: Research shows that species differ in their ability to adjust lifecycles to warming temperatures. If one species adjusts and the other does not, for instance, flowering times can end up out of sync with peak pollinator activity. Mismatches can also occur between predators and their prey, which may affect gardeners interested in attracting birds to their gardens. For example, the pied flycatcher now migrates at the wrong time relative to the availability of its insect prey, and as a result has experienced population declines of 90 percent.
Pests and invasives: Season creep provides favorable conditions to many pests and invasive species. In the western U.S., harsh winters normally cull the bark beetle population, but recent mild winters have allowed their population to skyrocket. Gypsy moths, tent caterpillars, beech bark disease, and hemlock woolly adelgid are also expected to expand their ranges thanks to the changing seasons. Invasive plant species are by no means uniform in their response to climate change, but research indicates that in many cases they will be able to adapt more effectively to season creep than native species. This was the case at Thoreau's Walden Pond, where invasive species slowly drove out native plants as the climate shifted.
Hardiness zones: In 1990, the U.S. Department of Agriculture (USDA) published the Plant Hardiness Zones, a map that divides the country into regions with different climatic conditions. This map aids gardeners in determining which plants will thrive in which regions. However, as conditions warmed and the climate changed, the real conditions in the zones began to differ with what was shown on the map. In 2012, the USDA revised the zones, changing the boundaries and moving most of them northward. For example, Ohio used to be mostly within Zone 5, but now it is almost entirely within the warmer Zone 6. As such, gardeners in these areas may have had to reconsider their planting choices.
 
 
Extreme Weather and Gardening 
Gardeners are highly attuned to the weather in order to maintain the best care and well-being for their gardens. What a typical season looks like, however, is changing. Climate change can make certain types of extreme weather more intense or frequent, thus creating new challenges for gardeners.  
Heavy Downpours: Extreme rainfall events have been linked to human-caused global warming. One study found that intensity of extreme precipitation events has increased 6-8 percent for each degree increase in global average temperature. Although it doesn't sound threatening, that can be the difference between a soggy day and one that floods a town's sewer system. Studies using climate models also show extreme precipitation will become more common in a warming world. Flooding and extreme rain can damage gardens by eroding landscaping, physically damaging to plants, and causing root rot in overly wet soil.
Droughts: Droughts are a complicated climate impact, in that they do not always have a single cause. Lack of rainfall, early snowmelt, high temperatures, and human overdevelopment and overuse of water can all cause drought. That said, climate change is connected to all of these factors except human overuse, and is predicted to continue to exacerbate them in the future. For gardeners, droughts mean more time and money spent on watering, and even bans on watering in some cases of extreme drought.
It may seem counter-intuitive that both droughts and downpours are increasing, but these are not mutually exclusive. Overall variability in the climate has increased, which means that we are seeing more "feast or famine" swings rather than constant conditions. As such, some regions are experiencing a simple rise in drought or rainfall, while others are experiencing a rise in both through increased variability.
Regional Impacts 
In addition to widely generalized effects across the country, gardeners are experiencing more localized climate change impacts from region to region. This list - though by no means exhaustive - shows some site-specific impacts. Many examples focus on agricultural crops and impacts but are still applicable to gardeners and their plants.
Northeast: When it comes to phenological changes, the northeastern United States is particularly vulnerable.
  • In the Washington, D.C. area, 89 flowering species have advanced their flowering by an average of 4.5 days in the past 30 years, with some flowering as much as 46 days earlier than usual. This leaves them vulnerable to frost damage.
  • Woody northeastern perennials such as apple, grape, lilac, and honeysuckle have advanced their spring phenology from two to eight days since 1965.
  • Hemlock wooly adelgid, forest tent caterpillar, beech bark disease, and oriental bittersweet are all "problematic" species that are projected to increase in the forests of the northeastern U.S.
  • The country's northernmost states are expected to experience the most dramatic change in phenology as climate change continues, with an increase of 38 days by 2100 in Maine and New York, compared to 10 days in the southernmost states.
Draft NCA Conclusions for the Northeast 
A special panel of scientists convened by the U.S. government issued a draft report stating that global warming is already changing America and how Americans live. The authors write: "climate change, once considered an issue for a distance future, has moved firmly into the present."
For the Northeast region, key takeways from the draft include:
  • Heat waves, coastal flooding due to sea level rise, and river flooding due to more extreme precipitation events will pose a growing challenge to the region's environmental, social, and economic systems. This will increase the vulnerability of the region's residents, especially populations that are already most disadvantaged.
  • Infrastructure will be increasingly compromised by climate-related hazards including sea level rise and coastal flooding, and intense precipitation events.
  • Agriculture and ecosystems will be increasingly stressed by climate-related hazards, including higher temperatures, sea level rise and coastal flooding, and more extreme precipitation events. A longer growing season may allow farmers to explore new crop options, but this and other adaptations will not be cost or risk-free, and inequities exist in the capacity for adaptation.
  • While a majority of states and several municipalities have begun to incorporate the risk of climate change into their planning activities, implementation of adaptation measures is still at early stages.