1
00:00:01,620 --> 00:00:05,620
Larsen: You guys got everything tied down back there?

2
00:00:05,620 --> 00:00:09,620
Truffer: Yep. Christoffersen: Yep.

3
00:00:09,620 --> 00:00:13,620
Larsen: We’re going through the lee of St. Elias, so there might be some turbulence.

4
00:00:13,620 --> 00:00:17,620
Christoffersen: Fasten Seat Belt sign on?

5
00:00:17,620 --> 00:00:21,620
Larsen: Well … who am I to tell you what to do?

6
00:00:21,620 --> 00:00:25,620
[aircraft engine noise, rising music]

7
00:00:25,620 --> 00:00:29,620


8
00:00:29,620 --> 00:00:33,620
[music builds]

9
00:00:33,620 --> 00:00:37,620


10
00:00:37,620 --> 00:00:41,620


11
00:00:41,620 --> 00:00:45,620


12
00:00:45,620 --> 00:00:49,620
[booming sound]

13
00:00:49,620 --> 00:00:53,620


14
00:00:53,620 --> 00:00:57,620
[theme music]

15
00:00:57,620 --> 00:01:01,620


16
00:01:01,620 --> 00:01:05,620


17
00:01:05,620 --> 00:01:09,620


18
00:01:09,620 --> 00:01:13,620


19
00:01:13,620 --> 00:01:17,620
Narrator: There are tens of thousands of glaciers in Alaska, 

20
00:01:17,620 --> 00:01:21,620
some stunning cliffhangers, others wide glaciers that come down 

21
00:01:21,620 --> 00:01:25,620
to meet the ocean tides. Some, like this one 

22
00:01:25,620 --> 00:01:29,620
we flew over in August, are easily visible

23
00:01:29,620 --> 00:01:33,620
from low Earth orbit, and are mesmerizing 

24
00:01:33,620 --> 00:01:37,620
from a thousand feet above, and have trees growing on top of their soil-laden boundaries. 

25
00:01:37,620 --> 00:01:41,620
Those glaciers – although they represent only a fraction 

26
00:01:41,620 --> 00:01:45,620
fraction of the world’s ice – are contributing much more than their share

27
00:01:45,620 --> 00:01:49,620
to sea level rise. 

28
00:01:49,620 --> 00:01:53,620
Chris Larsen and his colleagues have repeatedly measured 

29
00:01:53,620 --> 00:01:57,620
220 of them in a small single engine Otter,

30
00:01:57,620 --> 00:02:01,620
measuring their height with lasers and their depth with radar, 

31
00:02:01,620 --> 00:02:05,620
and watching them change from season to season and year to year.

32
00:02:05,620 --> 00:02:09,620
But Alaskan glaciers 

33
00:02:09,620 --> 00:02:13,620
are all so different we’re only just figuring out how they all behave.

34
00:02:13,620 --> 00:02:17,620
Data from flights like these, part of NASA’s Operation IceBridge,

35
00:02:17,620 --> 00:02:21,620
can help fill the gaps.Chris and radar specialist Martin Truffer

36
00:02:21,620 --> 00:02:25,620
are both from the University of Alaska Fairbanks, 

37
00:02:25,620 --> 00:02:29,620
and both seasoned Alaskan pilots, but they rely

38
00:02:29,620 --> 00:02:33,620
on their good friend and legendary bush pilot Paul Claus

39
00:02:33,620 --> 00:02:37,620
and his 35,000 hours in the cockpit 

40
00:02:37,620 --> 00:02:41,620
cockpit to fly the incredibly demanding flightlines the mission requires. 

41
00:02:41,620 --> 00:02:45,620
And does it help you guys being pilots too? Chris: I would like to think so but

42
00:02:45,620 --> 00:02:49,620
but watching Paul fly and seeing what he does is kind of like trying to 

43
00:02:49,620 --> 00:02:53,620
learn quantum mechanics in kindergarten.

44
00:02:53,620 --> 00:02:57,620
Truffer: you know, I can fly my airplane around, but just seeing what Paul does in this extremely 

45
00:02:57,620 --> 00:03:01,620
challenging environment in the mountains 

46
00:03:01,620 --> 00:03:05,620
while trying to follow the specific flight line at a 

47
00:03:05,620 --> 00:03:09,620
specific altitude above ground negotiating winds,

48
00:03:09,620 --> 00:03:13,620
topography, maybe occasional low-level clouds

49
00:03:13,620 --> 00:03:17,620
that you have to get around – just managing all that

50
00:03:17,620 --> 00:03:21,620
that is just several levels above 

51
00:03:21,620 --> 00:03:25,620
what I could do as a pilot.

52
00:03:25,620 --> 00:03:29,620
Claus: Well, I think the first time I came here to this park I was probably four years old

53
00:03:29,620 --> 00:03:33,620
with my father. I’ve been blessed to be able to fly

54
00:03:33,620 --> 00:03:37,620
fly in lots of places in the world, all over the place actually, almost every continent. 

55
00:03:37,620 --> 00:03:41,620
I guess I’m always looking for some place that might be better 

56
00:03:41,620 --> 00:03:45,620
than this, but I haven’t found it. [laughs]

57
00:03:45,620 --> 00:03:49,620
Narrator:Paul’s plane is about 60 years old and the first single engine Otter

58
00:03:49,620 --> 00:03:53,620
ever retrofitted with a 1000 horsepower engine, 

59
00:03:53,620 --> 00:03:57,620
which make takeoffs feel effortless and gives Paul the ability 

60
00:03:57,620 --> 00:04:01,620
to negotiate wild terrain.
Which he certainly did during the first

61
00:04:01,620 --> 00:04:05,620
first two incredible science flights of this campaign, and with sunny skies 

62
00:04:05,620 --> 00:04:09,620
and relatively calm air, we covered three vastly different pieces of ice.

63
00:04:09,620 --> 00:04:13,620
While Paul fueled up 

64
00:04:13,620 --> 00:04:17,620
the plane Chris gave us a preview of today’s science and scenery.

65
00:04:17,620 --> 00:04:21,620
Larsen: So it has one of the greatest coastal 

66
00:04:21,620 --> 00:04:25,620
reliefs anywhere in the world. So between 

67
00:04:25,620 --> 00:04:29,620
the ocean and the summit of Mt. St. Elias, which is 18,008 feet high, 

68
00:04:29,620 --> 00:04:33,620
it’s less than 10 miles. There’s a stupendous amount of mountain 

69
00:04:33,620 --> 00:04:37,620
right off the ocean. It’s hard to beat it anywhere in the world. 

70
00:04:37,620 --> 00:04:41,620
It might be the prettiest for me. It’s absolutely stunning. 

71
00:04:41,620 --> 00:04:45,620
From here in McCarthy we’ll cross one of the bigger 

72
00:04:45,620 --> 00:04:49,620
precipitation gradients in Alaska too. Here it’s about 

73
00:04:49,620 --> 00:04:53,620
10 inches of precipitation a year and we’ll go over to an area where it’s on the order 

74
00:04:53,620 --> 00:04:57,620
of 200 inches per year. So from one of the driest parts of Alaska 

75
00:04:57,620 --> 00:05:01,620
to one of the wettest parts of Alaska in about 45 minutes, flight time. 

76
00:05:01,620 --> 00:05:05,620
[aircraft engine noise, music]

77
00:05:05,620 --> 00:05:09,620
Truffer: Whoa that’s pretty good. Larsen: That’s awesome.

78
00:05:09,620 --> 00:05:13,620
Do you want to do Tyndall next? Claus: Sure, whatever you want.

79
00:05:13,620 --> 00:05:17,620
Larsen: If the winds are calm now might as well grab it. [laughs]

80
00:05:17,620 --> 00:05:21,620
Narrator: First, we came to the rugged landscape

81
00:05:21,620 --> 00:05:25,620
of Icy Bay, which not that long ago wasn’t a bay at all – 

82
00:05:25,620 --> 00:05:29,620
it was filled with ice. Tidewater glaciers in this region 

83
00:05:29,620 --> 00:05:33,620
can make dramatic advances and retreats as they feed on high rates 

84
00:05:33,620 --> 00:05:37,620
of snowfall and then retreat as they’re melted by warm ocean waters.

85
00:05:37,620 --> 00:05:41,620
Like the Tyndall glacier seen here, most of these glaciers 

86
00:05:41,620 --> 00:05:45,620
retreated dramatically over the last hundred years, but nearby

87
00:05:45,620 --> 00:05:49,620
Yahtse Glacier, after years of retreat, is currently the most rapidly 

88
00:05:49,620 --> 00:05:53,620
advancing glacier in Alaska.Overall though,

89
00:05:53,620 --> 00:05:57,620
the IceBridge Alaska surveys, from the Denali region in the north,

90
00:05:57,620 --> 00:06:01,620
to the Juneau Icefield in the Southeast, have documented pretty substantial 

91
00:06:01,620 --> 00:06:05,620
thinning of glacial ice. Areas seen here

92
00:06:05,620 --> 00:06:09,620
here in orange and red show between about 10 and 15 feet

93
00:06:09,620 --> 00:06:13,620
of thinning per year. Larsen: 1,200

94
00:06:13,620 --> 00:06:17,620
Truffer: That’s a nice waterfall up there from that hanging ice.

95
00:06:17,620 --> 00:06:21,620
Larsen: When we very first started profiling this Paul 

96
00:06:21,620 --> 00:06:25,620
this gravel fan and the one in the valley next to it didn’t exist.

97
00:06:25,620 --> 00:06:29,620
Claus: Yeah, I was gonna say. Look at all the good landing spots here.

98
00:06:29,620 --> 00:06:33,620
There was no place to land here before. Larsen: No, it was deep water.

99
00:06:33,620 --> 00:06:37,620
Narrator:After covering several of Icy Bay’s glaciers, 

100
00:06:37,620 --> 00:06:41,620
given that it was time for lunch, just like that, we landed

101
00:06:41,620 --> 00:06:45,620
in this unforgettable spot. [waterfall noise]

102
00:06:45,620 --> 00:06:49,620


103
00:06:49,620 --> 00:06:53,620


104
00:06:53,620 --> 00:06:57,620
[engine noise taking off]

105
00:06:57,620 --> 00:07:01,620
Flying eastward, leaving Icy Bay behind, 

106
00:07:01,620 --> 00:07:05,620
we came to the mighty Malaspina, one of the Earth’s 

107
00:07:05,620 --> 00:07:09,620
great examples of a “Piedmont” glacier, that spills out like pancake

108
00:07:09,620 --> 00:07:13,620
batter onto a broad plane as it approaches the sea. 

109
00:07:13,620 --> 00:07:17,620
It surges at uneven intervals, creating dramatic patterns 

110
00:07:17,620 --> 00:07:21,620
on its surface as it distorts the moraines of rock and soil 

111
00:07:21,620 --> 00:07:25,620
borne along by the glacier. The Malaspina 

112
00:07:25,620 --> 00:07:29,620
is less dynamic than the Yahtse and is only melting

113
00:07:29,620 --> 00:07:33,620
at about the average rate for Alaska. But that could change quickly.

114
00:07:33,620 --> 00:07:37,620
Larsen:Has the potential for being one of the bigger geographic evolutions in Alaska

115
00:07:37,620 --> 00:07:41,620
Certainly, my son will be able to witness 

116
00:07:41,620 --> 00:07:45,620
some big geography changes there … There’s potential for it being connected 

117
00:07:45,620 --> 00:07:49,620
with the ocean through some narrow lagoons, estuaries, 

118
00:07:49,620 --> 00:07:53,620
which would take a little bit of coastal erosion, but it’s not too hard 

119
00:07:53,620 --> 00:07:57,620
to imagine that this – where the Malaspina Glacier

120
00:07:57,620 --> 00:08:01,620
is now could become a large bay.

121
00:08:01,620 --> 00:08:05,620
Narrator:The data that Martin’s radar provides could reveal how vulnerable the Malaspina is

122
00:08:05,620 --> 00:08:09,620
to melting by the nearby ocean. Here we see the 

123
00:08:09,620 --> 00:08:13,620
 radar returns from the surface of the glacier, and here is something that Chris’s lasers

124
00:08:13,620 --> 00:08:17,620
can’t see – the rocky bed of the glacier, giving us both 

125
00:08:17,620 --> 00:08:21,620
clues as to what’s happening under the ice, as well as a

126
00:08:21,620 --> 00:08:25,620
measurement of its thickness.

127
00:08:25,620 --> 00:08:29,620
Finally, we came to the Yakutat ice field, 300 square miles of absolutely 

128
00:08:29,620 --> 00:08:33,620
doomed ice perched high in the mountains. 

129
00:08:33,620 --> 00:08:37,620
Researchers even debate how this ice field came to be at all, 

130
00:08:37,620 --> 00:08:41,620
Since in its current configuration, it’s hard to imagine how

131
00:08:41,620 --> 00:08:45,620
it could capture enough snow to form glacial ice.

132
00:08:45,620 --> 00:08:49,620
And so even if the Arctic weren’t warming faster than the rest 

133
00:08:49,620 --> 00:08:53,620
of the planet, this area would be likely to melt within a century or two.

134
00:08:53,620 --> 00:08:57,620
But with many other glaciers, 

135
00:08:57,620 --> 00:09:01,620
, it’s easier to see the connection between a warming planet and ice loss.

136
00:09:01,620 --> 00:09:05,620
Thanks to data from IceBridge and other surveys, 

137
00:09:05,620 --> 00:09:09,620
we now have a good estimate of the current rate of loss from Alaskan glaciers 

138
00:09:09,620 --> 00:09:13,620
-- 75 gigatons a year. 

139
00:09:13,620 --> 00:09:17,620
While airborne observations over Alaskan glaciers have

140
00:09:17,620 --> 00:09:21,000
provided a rich record of change in the area, those efforts

141
00:09:21,000 --> 00:09:25,620
are now augmented by NASA’s newest ice-measuring tool, ICESat-2.

142
00:09:25,620 --> 00:09:29,000
With six laser beamss of its own,

143
00:09:29,000 --> 00:09:33,620
and orbiting the Earth every 90 minutes, the satellite

144
00:09:33,620 --> 00:09:37,620
will carry on the record of Alaskan change.

145
00:09:37,620 --> 00:09:41,620
For their part, Chris and his team will continue to do their surveys for at least 

146
00:09:41,620 --> 00:09:45,620
the next two years, helping to validate the ICESat-2 data, 

147
00:09:45,620 --> 00:09:51,936
and make further detailed observations over the stunning glaciers of Alaska.