34 AUSTRALIAN SKY & TELESCOPE April 2018
NASA / BILL RODMANqualityimages)fromthestratosphere?Advancesinballoon
andcontroltechnologymakethisarealpossibility.Among
the major recent developments aresuper-pressure balloons,
whichwillenablelongerandhigherflights.
Conventional balloons maintain what’s calledzero pressure:
They vent helium as they fly in order to keep the pressure inside
theballoonequaltotheatmosphericpressureoutside.Butat
nighttheseballoonssinkastheheliumcools,sotheymust
dropballast.Thenextday,theballoononceagainascendsin
thewarmthofthesunlight,ventingheliumtostabilisealtitude.
And the next night, it will cool again and drop more ballast —
andsoon.Thiscyclemakeslongflightsimpossible.
Super-pressure balloons, however, are closed systems
madeofstrongmaterialthatcanmaintainpositivepressure
(thatis,higherpressureinsidetheballoonthanoutside).
Assuch,theyflyatnearlyconstantaltitudes,evenwhenthe
Sunsets.Theseballoonscanbelaunchedfromanywhereon
Earthandstayafloatformonths,tracingawanderingpath
around the planet.
NASA’s super-pressure balloon program has only been
availabletoscienceexperimentsforafewyears,butalready
therecordforoneoftheseflightsatmid-latitudesis46
days—muchlongerthanpreviouslypossible.Thegoalisto
routinelyhaveflightsofupto100days.
Anothermajordevelopmenthasbeenintelescopecontrol.
It remains a challenge to take deep visible light images
withoutsmearingthem,asthetelescopemustdriftless
thanafractionofanarcsecondwhenpointingatatarget
—that’slikethreadinganeedlefromakilometreaway.TheStratoscope II telescope, which operated about 50 years ago,
achievedaremarkable0.2-arcsecondresolutionforimages
with5to20secondsofexposuretime.Toimagefaintobjects,
though,we’dneedsimilarstabilityforatleastafewminutes.
TheSuper-pressureBalloon-borneImagingTelescope
(SuperBIT)hasmadehugeadvancesinthisarea.Itusesmotors
topointtheballoongondola;thetelescope,whichismounted
to an inner frame, can then be positioned to compensate for
anyrockingmotion.Motorscanalsoadjustamirrorinside the
camera to keep the image centre from drifting.
SuperBITshouldhaveitsfirstfullscienceflightonasuper-
pressureballooninaboutayear.LaunchingfromWanaka,
NewZealand,itwillmakedeep,high-resolutionmapsof
hundredsofgalaxyclusters.Astronomerscanthenusestrong
andweakgravitationallensingtomapdarkmatteraround
andbetweenthegalaxies.
This next-gen technology will make balloon-borne
telescopesanexcellentoptionforlongviewsofthesky
in visible light as well as ultraviolet and near-infrared
wavelengths, all of which require the dark-sky conditions
ofmiddlelatitudes(asopposedtothemidnightSunof
Antarctica). Soon we may have balloon telescopes mapping
distantgalaxieswithimageclaritysimilartotheHubble
Space Telescope or searching for planets around other stars.
For balloon astronomers, the sky is no longer the limit!LAURA FISSELis a postdoctoral research fellow at the US
National Radio Astronomy Observatory and a member of the
BLAST team.- Watchballoonslaunchathttps://is.gd/balloonastroandfollowtheBLASTteam’sprogressonTwitter:@BLAST_TNG.
THE NEXT GENERATION A super-pressure balloon is readied for launch from Wanaka, New Zealand. The May 16, 2016, take-off
marked the first time a super-pressure balloon carried a scientific payload, called the Compton Spectrometer and Imager.BALLOON ASTRONOMY