from 19.3 km2 to 1.72 km2, representing a      calving event ever witnessed, when            gas–forced warming will drive tempera-
91% loss (Kincaid, 2007). From 2000 to         Greenland’s Ilulissat glacier discharged      tures to rise faster with elevation, with this
2002 alone, surface area decreased from        a section of its terminus that measured       vertical amplification being greatest in the
2.326 km2 to 2.152 km2, or by 7.48%            ~5 km wide, 1 km thick, and 1.5 km long.      tropics due to feedbacks involving upper-
(Klein and Kincaid, 2006). The rate of                                                       tropospheric humidity, as well as snow
retreat accelerated from 1988 to 2005, even    CAUSES OF ICE LOSS                            albedo and surface-based and water-vapor
while precipitation (partly as rain) actually                                                feedbacks (Ramaswamy et al., 2006;
increased (Kincaid, 2007). When ice con-         Extensive literature shows that the         Randall et al., 2007; Pepin et al., 2015).
tracts in area and thickness, the ice within   ongoing loss of mass from glaciers is         Results from general circulation models
the glacier can also be affected by melting.   being caused primarily by warming over        indicate that the combined water-vapor/
Snow pits and cores at the Quelccaya ice       those glaciers and that this warming is, in   lapse-rate feedback provides the largest
cap in southern Peru reveal that since the     turn, being caused primarily by the rising    positive radiative reaction and that this
late 1970s the seasonal oxygen isotopic        CO2 concentrations in the atmosphere.         effect alone roughly doubles the warming
(d18O) variations have been homogenized        The reports of the Intergovernmental          in response to forcing by greenhouse
by meltwater percolating through the top       Panel on Climate Change (IPCC) provide        gases. As a result, the projected changes in
20 to 30 m of firn. This homogenization        useful starting points for understanding      mean annual free-air temperatures show
compromises the long-term seasonally           the linkage between temperature and the       twice as much warming at higher eleva-
resolved record of past climate variations.    mass balance of a glacier (e.g., Lemke et     tions in the tropics as is predicted at
This finding is consistent with analyses of    al., 2007), and IPCC (2013) examines the      Earth’s surface generally (Bradley et al.,
shallow cores throughout the Cordillera        history and causes of warming. Glaciers       2006). These projections are consistent
Blanca of northern Peru (Davis et al.,         can respond to changes in accumulation        with the recently documented rise of the
1995). Radiocarbon dates from wetland          of snowfall, seasonality of temperature,      free-air 0 °C isotherm in the tropical atmo-
plants exposed by the retreating margins of    cloudiness, and other factors. The advance    sphere (Bradley et al., 2009). Furthermore,
Quelccaya ice demonstrate that, for            or retreat of a single glacier may be dif-    as more dark land surface is exposed,
>~6,300 years, this ice cap has not been       ficult to interpret without targeted stud-    absorption of the intense higher-elevation
smaller than it is today (Thompson et al.,     ies, but literature summarized in these       radiation increases, thus accelerating the
2013). Rapid retreat of the ice margin con-    sources shows that for a large suite of gla-  melting (Bradley et al., 2006).
tinues to expose such evidence.                ciers ending on land, retreat is primarily
                                               driven by atmospheric warming.                  Low- to mid-latitude glaciers are
Photography                                                                                  extremely susceptible to such warming. In
                                                 Paleoclimate information contributes in     accord with model predictions of warming,
  Our collaboration features the work of       fundamental ways to the strong evidence       high-elevation tropical glaciers appear to
the Extreme Ice Survey (EIS), a non-           that warming temperature is the primary       be responding with an accelerating rate
governmental organization founded to           driver of the recent acceleration of ice      of glacier loss (Coudrain et al., 2005;
photograph the retreat of glaciers. Photo      retreat (Thompson et al., 2011, 2013). For    Thompson et al., 2006). Smaller glaciers
couplets of ice retreat have been both         example, evidence for warming is associ-      respond more rapidly to climate changes,
coincidentally and intentionally collected.    ated with ice retreat in the tropical Andes   and these mountain glaciers are generally
Ernest Shackleton’s expedition on HMS          (Rabatel et al., 2013). Arendt et al. (2013)  much smaller than their polar counterparts.
Endurance, for example, collected historic     found that mean summer temperatures           These ice masses are also particularly sen-
photos of the extent of ice on South           derived from ground and lower tropo-          sitive to small changes in ambient tempera-
Georgia that can be compared to modern         sphere records were good predictors of        tures, because they already exist very close
photos (see https://vimeo.com/125634374).      GRACE-derived summer mass balances            to the melting point.
Figure 2 presents photo couplets of glacial    in Gulf of Alaska glaciers, capturing 59%
retreat in Alaska, Iceland, Switzerland, and   and 72% of the variability. In the context      We again emphasize that many environ-
Peru, where lateral retreat and thinning are   of the ice retreat in New Guinea from         mental factors affect glaciers, and one
apparent. In a similar vein, the EIS has       1972 to 1987, mean monthly atmospheric        glacier may change for many reasons. As
amassed >1.1 million images recorded by        temperature was the only climate variable     glaciers shrink, the insulating effect of a
43 cameras observing 24 glaciers in            that changed in a statistically significant   debris cover that slows further melting
Alaska, the Rockies, the Andes, South          way (+0.24 °C; Klein and Kincaid, 2006).      may become more important, joining other
Georgia, Antarctica, the Alps, Iceland, and    Warming is also seen throughout the           factors influencing glaciers, some of which
the Himalayas. Ice: Portraits of Vanishing     Tibetan Plateau (now sometimes charac-        are mentioned above. Thus, proper charac-
Glaciers (Balog, 2012) provides graphic        terized as the Third Pole [TP]), where        terization of ongoing trends requires moni-
evidence in print form. Such time-lapse        meteorological data show that surface         toring of many glaciers in many places,
imagery has also been assembled into           temperatures are rising faster at higher      together with targeted studies of selected
videos that display ice retreat, such as       elevations than at lower elevations (Liu      glaciers to better characterize controls.
“Extreme Ice” (https://www.youtube.com/        and Chen, 2000). On average, the tem-         Taken together, though, the full scholar-
watch?v=6scs-Q-Ut_E). The film Chasing         perature on the TP has been increasing at     ship as summarized above gives high con-
Ice is critically acclaimed for its portrayal  a rate of 0.16 °C annually and 0.32 °C per    fidence that warming caused primarily
of glacial retreat. The film captured spell-   decade during winter.                         by human release of greenhouse gases is
binding imagery of perhaps the largest                                                       causing the retreat of glaciers.
                                                 On decadal and longer time scales,
                                               climate models project that greenhouse-

6 GSA Today | August 2017