Studies of impact craters on Venus from the Magellan images have placed important constraints on surface volcanism. Some 840 impact craters have been identified with diameters ranging from 2 to 280 km. Correlations of this impact flux with craters on the Moon, Earth, and Mars indicate a mean surface age of 0.5 +/- 0.3 Ga. Another important observation is that 52 percent of the craters are slightly fractured and only 4.5 percent are embayed by lava flows. These observations led researchers to hypothesize that a pervasive resurfacing event occurred about 500 m.y. ago and that relatively little surface volcanism has occurred since. Other researchers have pointed out that a global resurfacing event that ceased about 500 MYBP is consistent with the results given by a recent study. These authors carried out a series of numerical calculations of mantle convection in Venus yielding thermal evolution results. Their model considered crustal recycling and gave rapid planetary cooling. They, in fact, suggested that prior to 500 MYBP plate tectonics was active in Venus and since 500 MYBP the lithosphere has stabilized and only hot-spot volcanism has reached the surface. We propose an alternative hypothesis for the inferred cessation of surface volcanism on Venus. We hypothesize that plate tectonics on Venus is episodic. Periods of rapid plate tectonics result in high rates of subduction that cool the interior resulting in more sluggish mantle convection

Turcotte, Donald

English

NASA Technical Reports Server

LP! Contribution No. 789 12"/
Tessera is characterized by troughs, which det'mc -110-370-kin-
long I_d ~15-50-km-wide ea.st-west-oriented segments of CRT,
These elongatedareashave some of the highesttopography in the
MmaiTessera. One ofthesegments formsthepreviouslymentioned
easternextensionof the CRT ("G" in Fig. I). Although these
dongated partsofthe Mcni Tcssera do not have a similarstrikeas
the ridgelikctypography and morphology, and theyare not corn-
posed of clearindividualridges,theydo have a strikesimilartothe
ridgelikecomponents innortheasternTellusRegio.
StructurallyMcni TcsseraCRT ismore complex thannortheast-
can TellusRegio. The oldestunderlyingstructuresare curvilinear
ridges,but theyarewider and shorter(2-8km wide and 10--30km
long) and more widely spaced thanin noaheastern Tellus.There
does appeartobe very freeridgelikestructuresupcrposedon these
ridges,but they can not always be distinguishedfrom scarpsand
normal faults.The dominant directionof theridgesisto be north-
south/northeast-southwest,but thisoricntatlonmay be due tomore
laterdeformation and theoriginaldirectionsmay not bc observable
any more. Near theeasternedge of centralMcni Tessera theridges
followthecurvingtesseraborder.The centralpartsofMeniTessera
are characterizedby areasof orthogonal terrainof intersecting
northeast-southwestand northwest-southeastgrabcn ("H" in Fig.
I). This terrainhas bccn partlycovered by lavasof intratesscra
plainsinthe areaswhere itisvisible.There arealsoplaccswhere
grabcn cut across the border bctwccn the CRT and the plain,
especiallyaround western and northerncdgcs of Mcni Tcsscra.
The relationshipsbetween graben withdifferentorientationsis
complex: North-southstrikinggrabcn and individualscarps(prob-
ablynormal faults)cutotherfeaturesextensivelyinthe easternand
northernpartsof the centralMcni Tcsscra. There are alsograbcn
orientedin the northeast-southwestdirection,cspcciallynear thc
northwcsternand southeasternborders,which cutridgesand north-
west-southeastgrabcn. In the centralpartsof the CRT thcreare
northeast-southwest-orientedgrabcn thatcut other features,but
thesegrabcn arefrequentlycovered by lavas.There arc alsosmall
areas where grabcn are not widespread or at leastcan not be
distinguishedfrom small-scaleridges or closelyspaced faults.
Deformation sccms to have followed the same kind of basic
sequence asinnortheasternTcllusRcgio cxccptthattherehavebccn
severaldifferentepisodes of grabcn formationwith both spatially
and chronologicallymorccomplcx relationships.Also,differences
in orientationand morphology of ridges in Mcni Tessera and
northcastcm Tcllus Regio may reflcctdiffcrentoriginalstress
,regimes. Although no major strike-slipfaultswcrc identifiedin
Mcni Tcsscra,thereiscvidcncc of probable sheardcforrnationin
nearby plainsareas.
Discussionand Conclusions: Similaritiesinthc topographic
trends,especiallythe similartypes of lincarridgclikcfeaturesin
northeasternTcUus Regio and correspondingelongatedsegments in
northern Mcni Tcssera, which togethcrform a roughly south-
concave arc of topographicallyhigher CRT, as well as some
similaritieswith structuresof the CRT of the easternmost Mcni
Tcsscraand western edge ofnortheasternTcllusRegio,indicatethat
these areas of CRT were probably earlierinterconnected.The
troughlikcplainarea bctwcen Mcni Tesscra and TcllusRcgio is
probably underlainby CRT. which has been disruptedand covered
by lavas. The adjacent northcrn Leda Planitiaisdcforrncd by
complex intersectingsystems of fracturcsand ridges.Some of this
deformationmay reflectapresence of a covcredbasement of CRT.
The arcllkcpatternoftcsseraebetween Kamari Dorsa and northeast-
ern TellusRcgio may alsoreflectan carlicrlargerareaof tcssera.
Similarconclusionswcrc earlierprcscntcdon the basisofanalysis
of Venera data [14,15] and more recently by a comprehensive
analysis of distribution and characteristics of tessera from Magellaxt
images [16]. Based on this work, however, it is very hard to det'm¢
exactly the original extent of the CRT in this region.
Tessera areproposed toform by hot-spot-relatedvolcanism and
tcctonism[17,18]or by convection-driventectonicsabove mantle
downwellings [I,12,19].The resultsof thiswork do not conclu-
sivelyruleout eithermodel. Analysisofstracturesand deformation
shows thatthe earliestdistinguishabledeformation was compres-
sion,which was followed by widespread extensionand volcanism
(formationof intratesseraplains).Thisresultisin agreement with
otherstudies[e.g.,1,3,11,13]and similarresultshave been used to
supportthe mantle downweUing model [I,12],but in our opinion
they do not lcave out otherpossibilities.
The arclike arrangement of topographicallyhigher ridgelikc
featuresin northeasternTcllusRegio and northernMcni Tesserais
roughly similarinplanform,but smaller than theDckla Tcssera-
northcasternTellusRcgio archinthe north.These arcuatcpattcras
of tessera are typical to the area between longitudes 0 ° and 150°E
[ 16] and could tell us about the scales of deformation of the crust in
these areas. Observed complex deformational sequences in the
northeastern Tellus Regio--Mcni Tessera region do support the idea
that the CRT is probably a result of repeated deformation through
different mechanisms [20]. We are currently analyzing in more
detail structures in Meni Tessera and northern Tellus Regio and their
relationships with topography, intratessera volcanism, and the
deformation and volcanism on the adjacent plains.
References: [1] B indschadler D. L. et at. (1992) JGR, submit-
ted. [2] Barsukov V. L. et at. (1986) Proc. LPSC 17th, in JGR, 91,
D378-D398. [3] Bindschadler D. L. and Head J. W. (1991)JGR, 96,
5889-5907. [41 Smrekar S. and Phillips R. J. (1990) LPSC XXI,
1176-1177. [51Smrekar S. and Phillips R. J. (1992) EPSL, 107,
582-597. [6] Williams D. R. and Gaddis L. (1991) JGR, 96,
18841-18859. [7] Baker V. R. et at. (1992) JGR, submitted.
[8] Komatsu G. and Baker V. R. (1992) LPSC XXIII, 715-716.
[9] Gulick V. C. et at. (! 992) LPSC XXIII, 465--466. [ I 0] Komatsu
G. el al. (1992) LPSC XXIH, 719-720. [ 11 ] Bindschadler D. L. and
Tatsumura M. J. (1992) LPSC XXIII, 103-104. [12] Bindschadler
D. L. et al. (1992) JGR, submitted. [ 13] DeCharon A. V. and Stofan
E. R. (1992) LPSC XXHI, 289-290. [14] Sukhanov A. L. (1986)
Geotectonics, 20, 294-305. [15] Nikishin A. M. (1990) Earth Moon
Planets, 50/51, 101-125. [16] Ivanov M. A. et at. (1992) LPSC
XXIH, 581-581. [17] Herrick R. R. and Phillips R. J. (1990) GRL,
17, 2129--2132. [18] Phillips R. J. et al. (1991) Science, 252,
651-658. [ 19] Bindschadler D. L. and Parmentier E. M. (1990)JGR,
95, 21329-21344. [20] Solomon" S. C:et al. (1992)JGR. submitted.
N93 14390 :
EPISODIC PLATE TECTONICS ON VENUS. Donald Turcotte,
Department of Geological Sciences, Cornel1 University, Ithaca NY
14853, USA.
Studies of impact craters on Venus from the Magellan images
have placed important constraints on surface volcanism. Some 840
impact craters have been identified with diameters ranging from 2
to 280 km. Correlations of this impact flux withcraters on the Moon,
Earth, and Mars indicate a mean surface age of 0.5 + 0.3 Ga. Another
important observation is that 52% of the craters are slightly frac-
tured and only 4.5% are embayed by lava flows. These observations
led Schaber et al. [7] to hypothesize that a pervasive resurfacing
event occurred about 500 m.y. ago and that relatively little surface
volcanism has occurred since. An alternative hypothesis has been
https://ntrs.nasa.gov/search.jsp?R=19930005202 2020-03-17T09:04:46+00:00Z
128 International Colloquium on Venus
proposed by Izenber etal. [3]. They suggested that the observations
can be explained by a random distribution of small volcanic events.
Strom etal. [8] have pointed out that a global resurfacing event
that ceased about 500 MYBP is consistent with the results given by
Axkani-Hamed and Toksoz [ 1]. These authors carried out a series of
numerical calculations of mantle convection in Venus yielding
thermal evolution results. Their model 4 considered crustal recy-
cling and gave rapid planetary cooling. They, in fact, suggested that
prior to 500 MYBP plate tectonics was active in Venus and since
500 MYBP the lithosphere has stabilized and only hot-spot volca-
nism has reached the surface. Thus they suggested that the transition
to a near pristine lithosphere was the result of the secular cooling of
the planet.
In this abstract we propose an alternative hypothesis for the
inferre_ cessation of surface volcanism on Venus. We hypothesize
that plate tectonics on Venus is episodic. Periods of rapid plate
tectonics result in high rates of subduction that cool fl_e interior
resulting in more sluggish mantle convection. With a cool viscous
interior the surface lithospheric plate stabilizes and plate tectonics
cease. The stable lithosphere thickness increases with time reducing
the surface heat flow. As a result the interior temperature increases
leading to an increase in the plume flux. Eventually the lithosphere
is sufficiently thick and its gravitational instability initiates an
episode of global subduction.
This hypothesis is illustrated qualitatively in Fig. 1. During a
period of about 500 m.y. the lithosphere is globally stable and no
plate tectonics occurs. During this period the lithosphere thickens,
the surface heat flow decreases, and the mantle temperature in-
creases. As the lithosphere thickens it becomes gravitationally
unstable. Eventually this instability leads to a catastrophic global
subduction event. In the model illusa'ated in Fig. 1 this event
occurred 600 MY'BP. At the time of the global lithospheric instabil-
ity the mantle on Venus is expected to be considerably hotter and
less viscous than on the Earth so that rapid subducdon would occur.
Without a lithosphere, vigorous mantle convection would lead to
extensive volcanism, vigorous plate tectonics, a high surface heat
flow, and a rapid cooling of the mantle. As the mantle cools the
mantle convection and its surface manifestation, plate tectonics,
become less vigorous. Eventually the global lithosphere stabilizes
and plate tectonics ceases. In the model illustrated in Fig. 1 this
occurs at 500 MYB P. The lithosphere thickens, the surface heat flow
decreases, and the cycle repeats.
1000 -
globally rigid llthospheTe
low surlace host flow
inler_or heals up
800 -
Global subduclion OCCURS
600 - /i- . vigorous plate teclonlcs
My_Sp I extensive suHace volcanism
• _ ¢ high stJrface heal flow
_ InletJor cools
400 -- Iilhosphere stabilizes
200 -
g[obafty rigid lithosphere
low surface heat flow
[n(edor hea(s up
O-
Fig. 1. Illustration of episodic tectonics on Venus for the last 1000Go. Also
shown is the qu_liultive behavior of =hemean mantle temperature Tm.
Assuming that the venusian lithosphere stabilized 500 MY'BE i¢
is easy to determine its thermal swucture, assuming no basal heating
from mantle plumes and no partial delaminatlon. After 500 m.y. the
depth to the 1475-K isotherm is 290 km, the depth to the 1275-K
isotherm is 180 Ion, and the depth to the 1125-K isotherm is 120 kin.
The corresponding depths for a venusian lithosphere with steady-
state conductive heat t_ansport are 34, 26, and 19 km respectively.
The transient cooling of the lithosphere results in much greater
thicknesses, almost an order of magnitude. Such a thick lithosphere
is consistent with the large observed topographic and gravity
anomalies.
McKenzie et al. [4] have argued that the perimeters of several
largecoronae on Venus, specifically Artemis, Latona, and Eithinoha,
resemble terres_al subduction zones in both platform and topogra-
phy. Artemis chasma has a radius of curvature similar to that of the
South Sandwich subduction zone on the Earth. Sandwell and
Schubert [6] have shown that the morphologies of several coronae
are in good agreement with the lithosphere flexure models that have
been successful in explaining the sea floor morphology at ocean
trenches on this planet. Their flexural profiles yield elastic lithos:,
phere thicknesses of 37 km [or Artemis, 35 km for Latona, 15 km
for Eithinoha, 40 km for Heng-O, and 18 km for Freyja. These values
are consistent with a thick conductive lithosphere. The presence of
incipient subduction zones may be an indication of the onset of
another episode of active plate tectonics.
References: [1] Arkani-Hamed L and Toksoz M. N. (1984)
PEPI,34,232-250. [2] Ghail R. and Wilson L. (1992)LPSCXXI[[,
409-410. [3] Izenber N. K. et al. (1992) LPSC XXilI, 591-592.
[4] McKenzie D. etal. (1992)JGR, submitted. [5] Parmentier E. M.
and Hess P. C. (1992)LPSCXXIII, 1037-1038. [6] SandweU D. T.
and Schubert G. (1992) LPSCXXlii, 1209-1210. [7] Schaber G. G.
et al. (1992) LPSCXXlII, 1213-1214. [8] Strom R. G. etaL (1992)
LPSC XXIII. 1279-1380. /3-
,N93-14391 .... -,'
SCATTERING PROPERTIES OF VENUS' SURFACE. G.L.
Tyler, R. A. Simpson, M. J. Maurer, and E. Holmann, Center for
Radar Astronomy, Stanford University, Stanford CA 94305-4055,
USA.
^ , o
Radar backscatter functions o0 (_p) for incidence angles between
0 -< _ -< 4°-10 ° have been derived from Magellan altimetry radar
echoes. The procedure includes constrained solution of a system of
simultaneous equations for which the echo specmam and echo time
profile are inputs. A practical and workable set of constraints has
been applied; optimization and improved results are expected as
the analysis matures. The scattering functions yield information on
small-scale surface structure (tens of centimeters to tens of meters)
but averaged over hundreds of km z. RMS surface slopes derived
from fits of analytic functions to the _0(_) results have been
converted to map form and show patterns similar to those reported
using other techniques. While all three forms are found on Venus,
fit residuals imply that an exponential scattering function matches
data better than either the Hagfors or gaussian form in most areas,
although the Hagfors function may be a better descriptor at some
sites. Limited study of image data indicates that average backscatter
cross section, and possibly its slope, can be derived at oblique angles
(17 ° < (_ _<45°). Offsets of the echo peak in altimetry speca-a are
surprisingly common and are loosely correlated with Venus topog-
raphy, but no cause for this phenomenon has yet been identified.


Episodic plate tectonics on Venus

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