There are large uncertainties in the aerothermodynamic modelling of super-orbital re-entry which impact the design of spacecraft thermal protection systems (TPS). Aspects of the thermal environment of super-orbital re-entry flows can be simulated in the laboratory using arc- and plasma jet facilities and these devices are regularly used for TPS certification work [5]. Another laboratory device which is capable of simulating certain critical features of both the aero and thermal environment of super-orbital re-entry is the expansion tube, and three such facilities have been operating at the University of Queensland in recent years[10]. Despite some success, wind tunnel tests do not achieve full simulation, however, a virtually complete physical simulation of particular re-entry conditions can be obtained from dedicated flight testing, and the Apollo era FIRE II flight experiment [2] is the premier example which still forms an important benchmark for modern simulations. Dedicated super-orbital flight testing is generally considered too expensive today, and there is a reluctance to incorporate substantial instrumentation for aerothermal diagnostics into existing missions since it may compromise primary mission objectives. An alternative approach to on-board flight measurements, with demonstrated success particularly in the ‘Stardust’ sample return mission, is remote observation of spectral emissions from the capsule and shock layer [8]. JAXA’s ‘Hayabusa’ sample return capsule provides a recent super-orbital reentry example through which we illustrate contributions in three areas: (1) physical simulation of super-orbital re-entry conditions in the laboratory; (2) computational simulation of such flows; and (3) remote acquisition of optical emissions from a super-orbital re entry event

Buttsworth, David

D'Souza, Mary

Eichmann, Troy

Jacobs, Carolyn

Jacobs, Peter

Jenniskens, Peter

Jokic, Michael

Khan, Razmi

Lohle, Stefan

McIntyre, Tim

Mudford, Neil

Neely, Andrew

Porat, Hadas

Potter, Daniel

Upcroft, Ben

English

Queensland University of Technology ePrints Archive

This is the author’s version of a work that was submitted/accepted for pub-lication in the following source:Buttsworth, David, Jacobs, Peter, Potter, Daniel, Mudford, Neil, D’Souza,Mary, Eichmann, Tory, Jenniskens, Peter, McIntyre, Tim, Jokic, Michael,Jacobs, Carolyn, Upcroft, Ben, Khan, Razmi, Porat, Hadas, Neely, An-drew, & Lohle, Stefan (2011) Super-orbital re-entry in Australia : labora-tory measurement, simulation and flight observation. In 28th InternationalSymposium on Shock Waves, 17 - 22 July 2011, University of Manchester,Manchester.This file was downloaded from: http://eprints.qut.edu.au/43726/c© Copyright 2011 [please consult the authors]Notice: Changes introduced as a result of publishing processes such ascopy-editing and formatting may not be reflected in this document. For adefinitive version of this work, please refer to the published source:Super-orbital Re-entry in Australia –laboratory measurement, simulation andflight observationDavid Buttsworth1, Peter Jacobs2, Daniel Potter2, Neil Mudford3, MaryD’Souza2, Troy Eichmann2, Peter Jenniskens4, Tim McIntyre2, MichaelJokic1, Carolyn Jacobs2, Ben Upcroft5, Razmi Khan2, Hadas Porat2, AndrewNeely3, and Stefan Lo¨hle61 IntroductionThere are large uncertainties in the aerothermodynamic modelling of super-orbitalre-entry which impact the design of spacecraft thermal protection systems (TPS).Aspects of the thermal environment of super-orbital re-entry flows can be simu-lated in the laboratory using arc- and plasma jet facilities and these devices areregularly used for TPS certification work [5]. Another laboratory device which iscapable of simulating certain critical features of both the aero and thermal envi-ronment of super-orbital re-entry is the expansion tube, and three such facilitieshave been operating at the University of Queensland in recent years [10]. Despitesome success, wind tunnel tests do not achieve full simulation, however, a virtuallycomplete physical simulation of particular re-entry conditions can be obtained fromdedicated flight testing, and the Apollo-era FIRE II flight experiment [2] is the pre-mier example which still forms an important benchmark for modern simulations.Dedicated super-orbital flight testing is generally considered too expensive today,and there is a reluctance to incorporate substantial instrumentation for aerothermaldiagnostics into existing missions since it may compromise primary mission objec-tives. An alternative approach to on-board flight measurements, with demonstratedsuccess particularly in the ‘Stardust’ sample return mission, is remote observationof spectral emissions from the capsule and shock layer [8].JAXA’s ‘Hayabusa’ sample return capsule provides a recent super-orbital re-entry example through which we illustrate contributions in three areas: (1) physicalsimulation of super-orbital re-entry conditions in the laboratory; (2) computationalsimulation of such flows; and (3) remote acquisition of optical emissions from asuper-orbital re-entry event.1. University of Southern Queensland, Toowoomba, Australia · 2. The University of Queensland,Brisbane, Australia · 3. University of New South Wales at ADFA, Canberra, Australia · 4. SETIInstitute, California, USA · 5. Queensland University of Technology, Brisbane, Australia · 6. IRS,University of Stuttgart, Germany12 Buttsworth et al.2 Laboratory MeasurementThe majority of super-orbital flow experimentation at the University of Queenslandover the last 5 years has been performed in the X2 facility. Recently, experimentson a 1/10 scale model of the Hayabusa sample return capsule were performed for anequivalent re-entry flight speed of 9.71 km/s. The nose radius of the models tested inthe X2 facility was R = 20 mm. Steel models, both with and without epoxy coatingson the forebody were tested. The useful test flow duration in X2 at this condition isabout 150 µs. Due to the heat transfer from the X2 flow, within tens of microsecondsthe epoxy surface begins to thermally degrade, emitting water vapour and hydrocar-bon compounds into the shock layer. Details of the epoxy-coating method and theseexperiments are presented elsewhere [3, 1], but illustrative results are presented inFigs. 1 and 2.Fig. 1 Emissions from the shock layer on an epoxy-coated subscale Hayabusa model which wastested in the X2 facility at a flow speed of 9.12 km/s. Data recorded on the HPV-1 high speedcamera and analysed using the inverse Abel transform. Origin of the spatial axes is the intersectionof the stagnation streamline and the normal shock. Figure taken from [1].Figure 1 represents the shock layer emissions detected using the Shimadzu HPV-1 high speed camera for an epoxy-coated model. In this representation, the generaldirection of the flow is from left to right and two ridges in the shock layer emissionsare apparent. The left-most ridge arises because of the nonequilibrium radiationwhich is established immediately behind the shock front. The second ridge corre-sponds to a luminous zone adjacent to the surface of the Hayabusa model whichSuper-orbital Re-entry in Australia 3occurs due to the epoxy coating – it is not observed on HPV-1 images for modelswithout the epoxy coating.Results in Fig. 2 were obtained using an Acton Research Spectra Pro 2300I spec-trograph coupled to a Princeton Instruments PI-Max intensified CCD camera. Thefield of view of the spectrograph was a narrow strip, approximately 3.9 mm longwhich included the stagnation streamline. Figure 2 demonstrates the effect of theepoxy coating relative to the steel surface case – substantially higher emissionswithin the CN manifolds and emissions within the C2 Swan bands are observedin the case of the epoxy-coated models.Fig. 2 Spectral emissions from within the shock layer close to the surface of an epoxy-coatedsubscale Hayabusa model which was tested in the X2 facility at a flow speed of 9.12 km/s. Figuretaken from [1].3 Computational SimulationSimulations of expansion tube operation are necessary because a complete set oftest flow properties cannot be obtained directly from facility measurements alone.A hybrid approach which combines time-resolved one-dimensional control masssimulations (using ‘L1d’) with time-resolved axisymmetric control volume simula-4 Buttsworth et al.tions (using ‘Eilmer3’) has been used to deduce flow conditions for the Hayabusaexperiments outlined in Section 2. L1d is an efficient tool for accurately simulatingthe free-piston compression and unsteady wave and flow processes with finite ratechemistry for conditions where the tube boundary layers are thin. For conditionsin the acceleration tube and nozzle where viscous effects are strongly coupled tothe unsteady wave and flow processes, Eilmer3 is the preferred tool because L1dforcibly merges the core and boundary layer and all viscous interactions such asheat transfer at the tube wall directly affect the core flow conditions. Details of theL1d and Eilmer3 simulation tools are presented elsewhere [7, 6]. Simulation of theX2 facility for the present operating condition is described in [11], and these simu-lations differ somewhat from earlier work reported in [1]. Selected flow parametersfrom the most recent simulations [11] are reported in Table 1.Table 1 Estimated free stream conditions generated in the X2 facility for the subscale Hayabusaexperiments, from [11].u∞ (km/s) T (K) Tv (K) ρ∞ (kg/m3) uequiv (km/s)9.12 1070 1200 1.73×10−3 9.71Mole Fractions (> 1×10−6): N2: 6.27×10−1 O2: 5.75×10−3 NO: 2.18×10−4NO+: 7.24×10−5 N: 3.63×10−2 O: 3.30×10−1 e−: 7.24×10−5Inviscid simulations without radiative exchange for the steady flow around twospheres – one with radius R = 20 mm (denoted ‘X2’), the other with R = 200 mm(denoted ’flight’) – were also performed using Eilmer3 [6]. Figure 3 shows the vari-ation of density and N+2 along the row of cells closest to the stagnation streamlinefor both conditions. The difference in the normalised shock stand-off distance –x/R ≈ 0.052 for ‘flight’ and 0.057 for ‘X2’ – arises because of the shock layerchemistry. For the simulations of the ‘flight’ conditions, the nonequilibrium region(where the N+2 mass fraction varies rapidly) represents a small fraction of the shocklayer thickness, whereas for the ‘X2’ simulations, the nonequilibrium region (andthe region of relatively low shock layer density) is on the order of the shock layerthickness. The total enthalpies for the flight and X2 conditions are very similar: thecapsule speed in the flight simulation was 9.69 km/s and the equivalent flight speedfor the X2 conditions (based on the flow total enthalpy) was 9.71 km/s. However, theρL product in the case of the flight simulations was about 5 times larger than that ofthe X2 simulations; the laboratory experiments of Section 2 are subscale physicalsimulations of the re-entry event.4 Flight ObservationThe JAXA spacecraft, ‘Hayabusa’ re-entered the atmosphere above Australia latein the evening on the 13th of June 2010 at about 12 km/s, the fastest re-entry sinceSuper-orbital Re-entry in Australia 5Fig. 3 Results from computational simulations of spheres at super-orbital speeds. Variation ofnormalized density (ρ/ρ∞) and N+2 mass fraction close to the stagnation streamline plotted withnormalized distance from the surface of the sphere (x/R). Two cases are presented: ‘X2’ – spherewith radius R = 20 mm with free stream conditions reported in Table 1, simulated using a 60× 60 array of cells; and ‘flight’ – sphere with radius R = 200 mm travelling at 9.69 km/s andapproximately 52 km altitude, simulated using a 120 × 120 array of cells.‘Stardust’ in 2006. Teams of researchers from the University of Queensland, theUniversity of Southern Queensland, and the University of New South Wales atADFA were positioned at Tarcoola and Coober Pedy for ground-based observa-tions of the re-entry, and airborne observations were also made using an instrumenton board the NASA DC-8 platform. A significant body of spectral data in the range450 to 900 nm was acquired from the Tarcoola site using a semi-autonomous visualsystem developed for the event and this work is reported in a separate publication[4].The configuration of the ‘AUS’ instrument (Australian Ultraviolet Spectrometer)which was used on the DC-8 platform is illustrated in Fig. 4. The instrument wasmounted at station 610 (inches from the nose) in the DC-8, and at this station, aquartz window was fitted to enable acquisition of emission signatures in the near UVregion. The AUS instrument consisted of a 45 degree fused silica prism positionedahead of a 1200 lines/mm fused silica grating. An offset of approximately 10 degreeswas applied to the prism to achieve a centre wavelength of about 375 nm on theintensified CCD array, as illustrated in Fig. 4. The 105 mm lens used in the AUS6 Buttsworth et al.device had colour correction between 250 and 650 nm and an f/4.5 aperture and wasmanufactured by Jenoptik.Fig. 4 Optical arrangement of the Australian Ultraviolet Spectrometer (‘AUS’ Instrument) used onthe DC-8 airborne observation laboratory for the Hayabusa re-entry observation.The intensified CCD system in the AUS instrument has 1024 x 256 pixels(Princeton Instruments, PI-Max). The 1024 pixels were aligned in the vertical di-rection – the direction of the wavelength dispersion giving a resolution of 0.187nm/pixel. The spectrometer field of view in the direction of the 256 pixels was ap-proximately 3.6 degrees. A wide field of view video camera with good performanceat low light levels was co-aligned with the spectrometer to facilitate manual track-ing which was achieved by displaying the video signal on a headset display withcross-hairs.A representative frame from the AUS instrument recorded at approximately 2seconds after the peak in total (convective plus radiative) heating calculated to havebeen experienced by the Hayabusa capsule is presented in Fig. 5a. At this trajectorypoint, the estimated speed and altitude of the capsule are 9.69 km/s and 52 km re-spectively. During re-entry, the capsule was followed closely by the main bus, whichdisintegrated and was substantially brighter than the capsule itself. The proximityof the capsule and bus and the brightness of the bus made it difficult to distinguishthe capsule emission signature from that of the bus for certain times leading upto peak heating. Nevertheless, capsule emission spectra were successfully acquiredthroughout the re-entry event using the AUS instrument.The AUS instrument was calibrated at the NASA Ames Research Center post-flight using both an integrating sphere and a deuterium lamp with a wavelengthreference provided by a mercury lamp. The counts on the CCD array were summedover the capsule region in the spatial direction (the vertical direction as presented inof Fig. 5a) and the background level was removed, giving the net counts from thecapsule as a function of wavelength. Figure 5b was obtained by multiplying the netcounts by the instrument calibration at each corresponding wavelength value.Results in Fig. 5 show emissions from a variety of molecular and atomic speciessuperimposed on the continuum emissions from the capsule surface. In this figurecontinuum emission is fitted using a Planck radiation curve with a temperature ofSuper-orbital Re-entry in Australia 7Fig. 5 AUS instrument results acquired from the DC-8 aircraft at 13:52:22.40 (UTC) correspond-ing to approximately 2 seconds after the time of peak heating. Part (a): CCD image (false colour)from the AUS instrument illustrating the region of the Hayabusa capsule and the disintegratingbus. Part (b): spectral irradiance.3254 K (based on data from two ground-based instruments [9]) after scaling withthe estimated atmospheric transmission between the capsule and the DC-8. Themolecular radiation has been simulated using the PARADE software [12] basedon a manual selection of translational, vibrational, rotational, and electronic tem-peratures between the values of 5000 and 10000 K in order to fit the experimentaldata. The principal species contributing to observed molecular radiation are N2, N+2and CN. Contributions from NH have not yet been clearly identified. Carbon is amajor elements of Hayabusa’s carbon phenolic ablator TPS so CN is expected tobe generated primarily through the combination of dissociated nitrogen in the hightemperature shock layer air and ablation products from the heat shield. Calciumlines (Ca and Ca+) are also apparent (Fig. 5) and aluminium can also be observedbetween the two Ca+ lines.Contributions from N+2 can be observed in Fig. 5, but N+2 emissions did notfeature in the laboratory result presented in Fig. 2. The emission spectra obtainedfrom the Hayabusa re-entry represent an integration of the emission from the capsuleand surrounding flow field. For the flight observation, each CCD pixel could receiveemissions from an area of about 50 × 50 m at the range of the capsule so the N+2formed in the nonequilibrium region of the shock layer can be a strong contributorto the observed emissions. In contrast, laboratory experiments can resolve spatial8 Buttsworth et al.variations within the Hayabusa shock layer; the results of Fig. 2 were from a location0.15 mm ahead of the stagnation point, within the simulated ablation layer.5 ConclusionSubstantial sets of super-orbital re-entry data have been obtained through laboratoryexperimentation using the X2 expansion tube facility and remote observation of theHayabusa capsule’s atmospheric descent. Computational tools suitable for simulat-ing the super-orbital flows of the X2 facility and atmospheric re-entry have alsobeen established recently. We expect that a more complete understanding of thesecomplex flows can be achieved by employing these computational tools to analyselaboratory measurements in parallel with the flight data so we are proceeding in thisdirection.AcknowledgementWe would like acknowledge the Australian Research Council for support throughthe ARC Discovery program, the University of Queensland and the University ofSouthern Queensland for travel support for the Hayabusa observation mission, andcomputing support provided by the Queensland Smart State Research FacilitiesFund and the UQ High Performance Computing Unit. We thank NASA for the in-vitation to participate in the airborne observation mission, Prof Richard Morganfor assistance with AUS instrument configuration, calibration and especially his ac-curate capsule targetting, Dr Michael Winter for assistance with instrument calibra-tions, and Dr Tetsuya Yamada of JAXA for facilitating the appointment of Hayabusaobservers to the Hayabusa Joint Science Team.References1. D R Buttsworth, M D’Souza, D Potter, T Eichmann, N Mudford, M McGilvray, T J McIn-tyre, P Jacobs, and R Morgan. Expansion tunnel radiation experiments to support hayabusare-entry observations. In 48th AIAA Aerospace Sciences Meeting, AIAA Paper 2010-634,Orlando, Florida, 4 – 7 January 2010.2. D L Cauchon. Radiative heating results from FIRE II flight experiment at a re-entry velocityof 11.4 km/s. Technical Memorandum X-1402, NASA, 1967.3. M G D’Souza, T N Eichmann, D F Potter, R G Morgan, T J McIntyre, P A Jacobs, andN R Mudford. Observation of an ablating surface in expansion tunnel flow. AIAA Journal,48(7):1557–1560, 2010.4. T. N. Eichmann, R. Khan, T. J. McIntyre, C. Jacobs, H. Porat, D. Buttsworth, and B. Upcroft.Radiometric temperature analysis of the hayabusa spacecraft re-entry. In 28th InternationalSymposium on Shock Waves, Manchester, UK, 17 – 22 July 2011.Super-orbital Re-entry in Australia 95. G Herdrich, A Knapp, S Lo¨hle, D Petkow, and S Fasoulas. Ground testing facilities andmodeling tools: Research examples. In 27th AIAA Aerodynamic Measurement Technologyand Ground Testing Conference, AIAA Paper 2010-4339, Chicago, Illinois, 28 June – 1 July2010 2010.6. P. A. Jacobs and R. J. Gollan. The Eilmer3 code: User guide and example book. MechanicalEngineering Report 2008/07, The University of Queensland, Brisbane, Australia, 2010.7. P. A. Jacobs, R. J. Gollan, D. F. Potter, D. E. Gildfind, T. N. Eichmann, B. T. O’Flaherty,and D. R. Buttsworth. CFD tools for design and simulation of transient flows in hypersonicfacilities. In O. Chazot and K. Bensassi, editors, RTO-AVT-VKI Lecture Series 2010-AVT186Aerothermodynamic Design, Review on Ground Testing and CFD., Belgium, March 2010.von Karman Institute for Fluid Dynamics.8. D A Kontinos and M J Wright. Introduction: Atmospheric entry of the Stardust sample returncapsule. Journal of Spacecraft and Rockets, 47(6):865–867, 2010.9. S. Lo¨hle, T. Marynowski, and A. Mezger. Spectroscopic analysis of the hayabusa re-entry us-ing airborne and ground based equipment. In 7th European Aerothermodynamics Symposiumon Space Vehicles, Brugge, Belgium, 2011.10. R. G. Morgan, T. J. McIntyre, D. R. Buttsworth, P. A. Jacobs, D. F. Potter, A. M. Brandis, R. J.Gollan, C. M. Jacobs, B. R. Capra, M. McGilvray, and T. N. Eichmann. Impulse facilitiesfor the simulation of hypersonic radiating flows. In 38th Fluid Dynamics Conference andExhibit, pages Paper AIAA–2008–4270. American Institute of Astronautics and Aeronautics,June 2008.11. D F Potter. Ph.D. dissertation, Department of Mechanical and Mining Engineering, Universityof Queensland, Brisbane, Australia, 2011.12. A. J. Smith, A. Wood, J. Dubois, M. Fertig, and B. Pfeiffer. Plasma radiation database PA-RADE v2.2, Final Report Issue 3. TR28/96 Issue 3, ESTEC Contract 11148/94/NL/FG,October 2006.

Super-orbital re-entry in Australia - laboratory measurement, simulation and flight observation

There are large uncertainties in the aerothermodynamic modelling of super-orbital re-entry which impact the design of spacecraft thermal protection systems (TPS). Aspects of the thermal environment of super-orbital re-entry flows can be simulated in the laboratory using arc- and plasma jet facilities and these devices are regularly used for TPS certification work [5]. Another laboratory device which is capable of simulating certain critical features of both the aero and thermal environment of super-orbital re-entry is the expansion tube, and three such facilities have been operating at the University of Queensland in recent years[10]. Despite some success, wind tunnel tests do not achieve full simulation, however, a virtually complete physical simulation of particular re-entry conditions can be obtained from dedicated flight testing, and the Apollo era FIRE II flight experiment [2] is the premier example which still forms an important benchmark for modern simulations. Dedicated super-orbital flight testing is generally considered too expensive today, and there is a reluctance to incorporate substantial instrumentation for aerothermal diagnostics into existing missions since it may compromise primary mission objectives. An alternative approach to on-board flight measurements, with demonstrated success particularly in the ‘Stardust’ sample return mission, is remote observation of spectral emissions from the capsule and shock layer [8].\ud
\ud
JAXA’s ‘Hayabusa’ sample return capsule provides a recent super-orbital reentry example through which we illustrate contributions in three areas: (1) physical simulation of super-orbital re-entry conditions in the laboratory; (2) computational simulation of such flows; and (3) remote acquisition of optical emissions from a super-orbital re entry event

Eichmann, Tory

Name not available

Super-orbital re-entry in Australia : laboratory measurement, simulation and flight observation

There are large uncertainties in the aerothermodynamic modelling of super-orbital re-entry which impact the design of spacecraft thermal protection systems (TPS). Aspects of the thermal environment of super-orbital re-entry flows can be simulated in the laboratory using arc- and plasma jet facilities and these devices are regularly used for TPS certification work [5]. Another laboratory device which is capable of simulating certain critical features of both the aero and thermal environment of super-orbital re-entry is the expansion tube, and three such facilities have been operating at the University of Queensland in recent years[10]. Despite some success, wind tunnel tests do not achieve full simulation, however, a virtually complete physical simulation of particular re-entry conditions can be obtained from dedicated flight testing, and the Apollo era FIRE II flight experiment [2] is the premier example which still forms an important benchmark for modern simulations. Dedicated super-orbital flight testing is generally considered too expensive today, and there is a reluctance to incorporate substantial instrumentation for aerothermal diagnostics into existing missions since it may compromise primary mission objectives. An alternative approach to on-board flight measurements, with demonstrated success particularly in the ‘Stardust’ sample return mission, is remote observation of spectral emissions from the capsule and shock layer [8]. JAXA’s ‘Hayabusa’ sample return capsule provides a recent super-orbital reentry example through which we illustrate contributions in three areas: (1) physical simulation of super-orbital re-entry conditions in the laboratory; (2) computational simulation of such flows; and (3) remote acquisition of optical emissions from a super-orbital re entry even

University of Southern Queensland ePrints

CFD tools for design and simulation of transient ﬂows in hypersonic facilities.

Expansion tunnel radiation experiments to support hayabusa re-entry observations.

Ground testing facilities and modeling tools: Research examples.

Impulse facilities for the simulation of hypersonic radiating ﬂows.

Introduction: Atmospheric entry of the Stardust sample return capsule.

Observation of an ablating surface in expansion tunnel ﬂow.

Radiative heating results from FIRE II ﬂight experiment at a re-entry velocity of 11.4 km/s.

Radiometric temperature analysis of the hayabusa spacecraft re-entry.

Spectroscopic analysis of the hayabusa re-entry using airborne and ground based equipment.

The Eilmer3 code: User guide and example book.

Super-orbital re-entry in Australia: laboratory measurement, simulation and flight observation [Keynote lecture]

There are large uncertainties in the aerothermodynamic modelling of super-orbital re-entry which impact the design of spacecraft thermal protection systems (TPS). Aspects of the thermal environment of super-orbital re-entry flows can be simulated in the laboratory using arc- and plasma jet facilities and these devices are regularly used for TPS certification work [5]. Another laboratory device which is capable of simulating certain critical features of both the aero and thermal environment of super-orbital re-entry is the expansion tube, and three such facilities have been operating at the University of Queensland in recent years [10]. Despite some success, wind tunnel tests do not achieve full simulation, however, a virtually complete physical simulation of particular re-entry conditions can be obtained from dedicated flight testing, and the Apollo-era FIRE II flight experiment [2] is the premier example which still forms an important benchmark for modern simulations. Dedicated super-orbital flight testing is generally considered too expensive today, and there is a reluctance to incorporate substantial instrumentation for aerothermal diagnostics into existing missions since it may compromise primary mission objectives. An alternative approach to on-board flight measurements, with demonstrated success particularly in the ‘Stardust’ sample return mission, is remote observation of spectral emissions from the capsule and shock layer [8]. JAXA’s ‘Hayabusa’ sample return capsule provides a recent super-orbital reentry example through which we illustrate contributions in three areas: (1) physical simulation of super-orbital re-entry conditions in the laboratory; (2) computational simulation of such flows; and (3) remote acquisition of optical emissions from a super-orbital re-entry event

USC Research Bank - University of the Sunshine Coast

Super-Orbital Re-entry in Australia: Laboratory Measurement, Simulation and Flight Observation

Super-orbital re-entry in Australia - laboratory measurement, simulation and flight observation

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