The freezing rain from an ice storm covers everything with heavy, smooth glaze ice. Ice-covered roads become slippery and hazardous, as the ice causes vehicles to skid out of control, which can cause devastating car crashes as well as pile-ups. Pedestrians are severely affected as sidewalks become slippery, causing people to slip and fall, and outside stairs can become an extreme injury hazard.

In addition to hazardous driving or walking conditions, branches or even whole trees may break from the weight of ice. Falling branches can block roads, tear down power and telephone lines, and cause other damage. Even without falling trees and tree branches, the weight of the ice itself can easily snap power lines and also break and bring down power/utility poles; even steel frame electricity pylons have been sent crashing to the ground by the weight of the ice. This can leave people without power for anywhere from several days to a month. According to most meteorologists, just one quarter of an inch of ice accumulation can add about 500 pounds of weight per line span. Damage from ice storms is highly capable of shutting down entire metropolitan areas.

Additionally, the loss of power during ice storms has indirectly caused numerous illnesses and deaths due to unintentional carbon monoxide (CO) poisoning. At lower levels, CO poisoning causes symptoms such as nausea, dizziness, fatigue, and headache, but high levels can cause unconsciousness, heart failure, and death. The relatively high incidence of CO poisoning during ice storms occurs due to the use of alternative methods of heating and cooking during prolonged power outages, common during severe ice storms. Gas generators, charcoal and propane barbecues, and kerosene heaters contribute to CO poisoning when they operate in confined locations. CO is produced when appliances burn fuel without enough oxygen present, such as basements and other indoor locations.

Loss of electricity during ice storms can also easily lead to hypothermia and even death from hypothermia. It can also lead to ruptured pipes due to water freezing inside the pipes.

Tree sensitivity to sap coloration and resistance to crown damage from an ice storm.
Sensitivity to sap coloration Resistance to ice damage to crown
Low or average Average or strong Strong

Sensitive
  • Manitoba maple (Acer negundo)
  • Pennsylvania maple
  • Silver maple (Acer saccharinum)
  • Norway maple (Acer platanoides)
  • Red Maple (Acer rubrum)
  • White birch (Betula pubescens)
  • Grey birch (Betula populifolia)
  • Jack pine (Pinus banksiana)
  • Red pine (Pinus resinosa)
  • Aspens
  • Pin cherry (Prunus pensylvanica)
  • Chokecherry (Prunus virginiana)
  • Willows and Alders
  • Mountain ashes
  • Linden (or basswood)
  • Locusts and Honey locusts (Gleditsia triacanthos)
  • Yellow birch (Betula alleghaniensis)
  • American beech (Fagus grandifolia)
  • White ash (Fraxinus americana)
  • Elms
  • Sugar Maple (Acer saccharum)
  • White pines
  • Apple trees
  • Balsam fir (Abies balsamea)
  • Little-leaf linden (Tilia cordata)
  • Hawthorns
  • Spruces

Insensitive
  • Eastern white cedar (Thuja occidentalis)
  • American larch (Larix laricina)
  • Black cherry (Prunus serotina)
  • Red ash (Fraxinus pennsylvanica)
  • Common hackberry (Celtis occidentalis)
  • Bitternut hickory (Carya cordiformis)
  • Red oaks
  • Tree of Heaven (Ailanthus altissima)
  • Black ash (Fraxinus nigra)
  • Shagbark hickory (Carya ovata)
  • Eastern hemlock (Tsuga canadensis)
  • Burr oak (Quercus macrocarpa)
  • White oak (Quercus alba)
  • Swamp white oak (Quercus bicolor)
  • Hophornbeam
  • Black walnut (Juglans nigra)
  • Hornbeam
  • Saskatoon berry (Amelanchier alnifolia)

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