The First Joint European Partial-G Parabolic Flight Campaign at Moon and Mars Gravity Levels for Science and Exploration

Aircraft parabolic flights provide repetitively short periods of reduced gravity and are used to conduct scientific and technology microgravity investigations, to test instrumentation prior to space flights and to train astronauts before a space mission. Since 1997, ESA, CNES and DLR use the Airbus A300 ZERO-G, currently the largest airplane in the world for this type of experimental research flight. This mean is managed by the French company Novespace. Since 2010, Novespace offers the possibility of flying reduced gravity levels equivalent to those on the Moon and Mars achieved repetitively for periods of more than 20?s. ESA, CNES and DLR issued an international call for experiments inviting European Scientists to submit experiment proposals to be conducted at these partial gravity levels. The scientific objectives are on one hand to obtain results at intermediate levels of gravity (between 0 and 1?g) allowing a better study of the influence of gravity, and on the other hand to give them some elements to prepare for research and exploration during space flights and future planetary exploration missions. ESA, CNES and DLR jointly organised in June 2011 the first Joint European Partial-G Parabolic Flight campaign with 13 experiments selected among 42 received proposals. Parabolas were flown during three flights providing micro-, Moon and Mars gravity levels with duration typically of 20?s, 25?s and 32?s with a mixed complement of investigations in physical and life sciences and in technology. The paper presents the approach taken to organise this campaign and the 13 selected experiments with some preliminary results are presented to show the interest of this unique research tool for microgravity and partial gravity investigations.     

International Heat and Mass Transfer Experiments on the 48th ESA Parabolic Flight Campaign of March 2008

Aircraft parabolic flights provide repetitively up to 20 s of reduced gravity during ballistic flight manoeuvres and are used to conduct short microgravity investigations in Physical and Life Sciences and Technology, to test instrumentation and to train astronauts before a space flight. Their use is complementary to other microgravity platforms, such as drop towers, sounding rockets, automatic orbital capsules and the International Space Station (ISS), and preparatory to space missions. Since 1997, parabolic flights in Europe are performed with the Airbus A300 ‘Zero-G’, the world largest aircraft for this research activity. ESA campaigns are organized at a rate of two campaigns per year, usually in spring and autumn. Depending on their sizes, 12 to 14 experiments can be accommodated per campaign. Due to the scientific interest and the growing importance of heat and mass transfer experiments, ESA has dedicated its 48th ESA parabolic flight campaign of 2008 to this kind of experiments. A certain number of experiments have been identified in Europe, USA and Japan and eight of these experiments have been assigned to the 48th ESA campaign of March 2008. Five other experiments are scheduled to participate in the next 49th ESA campaign of October 2008. The ESA aircraft parabolic flight programme and the Airbus A300 ‘Zero-G’ aircraft are presented. The eight heat and mass transfer experiments foreseen for the 48th campaign of March 2008 are summarized.     

First Middle East Aircraft Parabolic Flights for ISU Participant Experiments

Aircraft parabolic flights are widely used throughout the world to create microgravity environment for scientific and technology research, experiment rehearsal for space missions, and for astronaut training before space flights. As part of the Space Studies Program 2016 of the International Space University summer session at the Technion - Israel Institute of Technology, Haifa, Israel, a series of aircraft parabolic flights were organized with a glider in support of departmental activities on ‘Artificial and Micro-gravity’ within the Space Sciences Department. Five flights were organized with manoeuvres including several parabolas with 5 to 6 s of weightlessness, bank turns with acceleration up to 2 g and disorientation inducing manoeuvres. Four demonstration experiments and two experiments proposed by SSP16 participants were performed during the flights by on board operators. This paper reports on the microgravity experiments conducted during these parabolic flights, the first conducted in the Middle East for science and pedagogical experiments.     

Gravitactic signal transduction elements in astasia longa investigated during parabolic flights

Euglena gracilis and its close relative Astasia longa show a pronounced negative gravitactic behavior. Many experiments revealed that gravitaxis is most likely mediated by an active physiological mechanism. The goal of the present study was to examine elements in the sensory transduction by means of inhibitors of gravitaxis and the intracellular calcium concentration during short microgravity periods. During the course of six parabolic flights (ESA 31th parabolic flight campaign and DLR 6th parabolic flight campaign) the effects of trifluoperazine (calmodulin inhibitor), caffeine (phosphodiesterase inhibitor) and gadolinium (blocks mechano-sensitive ion channels) was investigated. Due to the extreme parabolic flight maneuvers of the aircraft alternating phases of 1.8×g_n (about 20 s) and microgravity (about 22 s) were achieved (g_n: acceleration of Earth’s gravity field). The duration of the microgravity periods was sufficient to detect a loss of cell orientation in the samples. In the presence of gadolinium impaired gravitaxis was found during acceleration, while caffeine-treated cells showed, compared to the controls, a very precise gravitaxis and faster reorientation in the 1.8×g_n period following microgravity. A transient increase of the intracellular calcium upon increased acceleration was detected also in inhibitor-treated samples. Additionally, it was found that the cells showed a higher calcium signal when they deviated from the vertical swimming direction. In the presence of trifluoperazine a slightly higher general calcium signal was detected compared to untreated controls, while gadolinium was found to decrease the intracellular calcium concentration. In the presence of caffeine no clear changes of intracellular calcium were detected compared to the control. Dedicated to the memory of our colleague and friend Helmut Wagner     

Verification of the Microgravity Active Vibration Isolation System based on Parabolic Flight

The Microgravity active vibration isolation system (MAIS) is a device to reduce on-orbit vibration and to provide a lower gravity level for certain scientific experiments. MAIS system is made up of a stator and a floater, the stator is fixed on the spacecraft, and the floater is suspended by electromagnetic force so as to reduce the vibration from the stator. The system has 3 position sensors, 3 accelerometers, 8 Lorentz actuators, signal processing circuits and a central controller embedded in the operating software and control algorithms. For the experiments on parabolic flights, a laptop is added to MAIS for monitoring and operation, and a power module is for electric power converting. The principle of MAIS is as follows: the system samples the vibration acceleration of the floater from accelerometers, measures the displacement between stator and floater from position sensitive detectors, and computes Lorentz force current for each actuator so as to eliminate the vibration of the scientific payload, and meanwhile to avoid crashing between the stator and the floater. This is a motion control technic in 6 degrees of freedom (6-DOF) and its function could only be verified in a microgravity environment. Thanks for DLR and Novespace, we get a chance to take the DLR 27th parabolic flight campaign to make experiments to verify the 6-DOF control technic. The experiment results validate that the 6-DOF motion control technique is effective, and vibration isolation performance perfectly matches what we expected based on theoretical analysis and simulation. The MAIS has been planned on Chinese manned spacecraft for many microgravity scientific experiments, and the verification on parabolic flights is very important for its following mission. Additionally, we also test some additional function by microgravity electromagnetic suspension, such as automatic catching and locking and working in fault mode. The parabolic flight produces much useful data for these experiments.     

The national — esa soyuz missions andromède, marco polo, odissea, cervantes, delta and eneide

From the autumn of 2001 till spring of 2005 a series of six flights to the International Space Station, ISS, were conducted using the Russian Soyuz manned launcher. These flights initially known as ‘taxi-missions’, were characterized by the participation and co-funding from both the European Space Agency, ESA, and the five national delegations from France, Italy, Belgium, Spain, and the Netherlands. The national participation was reflected both in the flight of a cosmonaut/astronaut, originating from the country co-sponsoring the flight as well as in the origin of the majority of experiments and other activities carried out during these missions. In these six Soyuz missions: Andromède (October 2001), Marco Polo (April 2002), Odissea (October 2002), Cervantes (October 2003), DELTA (April 2004) and Eneide (April 2005), some more than one hundred experiments were carried out. These experiments covered the areas of basic and applied research and technology in biology, human physiology, fluid and plasma physics, material science and Earth observation. Also a significant number of education activities were part of these missions. This paper gives a complete overview of these missions, of all science, education and related activities performed. The perspectives of these activities in the light of the space exploration programs in the XXI century and some of the uncertainties and paradoxes are discussed.     

Gas jet study in microgravity environment

In this article we report on the variations of behaviour, shape, size and density profile of a CO2 gas jet near the laminar regime, during the transition from macro (1.8G) to microgravity (0G) experienced on board a A300 ZERO-G Airbus performing parabolic flights, using a Mach-Zehnder interferometer and Schlieren imaging techniques. Both optical techniques used have been successful in visualizing and measuring the gas jet, suggesting their use to further develop optical methods for detecting in real time and analysing small gas leaks in macro, normal and microgravity environments, with potential industrial applications to aerospace, aeronautics and in the production, storage and transport of gaseous and volatile substances.     

Liulin-type spectrometry-dosimetry instruments

The main purpose of Liulin-type spectrometry-dosimetry instruments (LSDIs) is cosmic radiation monitoring at the workplaces. An LSDI functionally is a low mass, low power consumption or battery-operated dosemeter. LSDIs were calibrated in a wide range of radiation fields, including radiation sources, proton and heavy-ion accelerators and CERN-EC high-energy reference field. Since 2000, LSDIs have been used in the scientific programmes of four manned space flights on the American Laboratory and ESA Columbus modules and on the Russian segment of the International Space Station, one Moon spacecraft and three spacecraft around the Earth, one rocket, two balloons and many aircraft flights. In addition to relative low price, LSDIs have proved their ability to qualify the radiation field on the ground and on the above-mentioned carriers.     

Benefits of ESA Gravity-Related Hands-on Programmes for University Students’ Careers

The Education Office of the European Space Agency (ESA) offers university students, from ESA Member and Cooperating States, the opportunity to perform investigations in physical sciences, life sciences, and technology, under different gravity conditions through three educational programmes. The “Fly Your Thesis!” (FYT) programme makes use of parabolic flights and the “Drop Your Thesis!” (DYT) programme utilizes a drop tower as microgravity carriers, while the “Spin Your Thesis!” (SYT) programme uses a large centrifuge to create hypergravity. To date, more than hundred university students had the chance to participate in the design, development, and performance of one or more experiments during dedicated campaigns. In the following paper, we examine demographics of past participants of the ESA Education Office gravity-related opportunities over the past seven years and evaluate the benefits of these educational programmes for the participants’ studies and careers. Student teams that participated in one of the programmes between 2009 and 2013 were contacted to fill in a questionnaire. The feedback from the students demonstrate significant benefits extending far beyond the primary educational objectives of these programmes.     

The ESA contribution to space research on two-phase systems

This paper gives an overview of the research programme in Heat and Mass Transfer coordinated by the European Space Agency (ESA). This research programme consists of six projects involving more than 30 partners, both academia and industry, spread in 11 countries in Europe, Canada and Israël. The microgravity experiments performed up to now are recalled as well as their main results. Finally, the experiments planned for the coming years, particularly in the Fluid Science Laboratory (FSL) on the International Space Station (ISS), are briefly described.     

Parabolic flight experiments with PK-4

PK-4 is an experiment designed to investigate complex plasmas (low-temperature plasmas containing microparticles, e.g. dust grains) in a combined dc/rf discharge under microgravity conditions on board of the International Space Station. Within the 35th and 36th ESA parabolic flight campaigns first experiments under microgravity conditions in a specially designed experiment set-up have been performed. The particle flow inside the tube, the appearance of dust waves, and lane formation in interpenetrating particle clouds have been observed.     

Real-Time Video-Microscopy of Migrating Immune Cells in Altered Gravity During Parabolic Flights

In our project we developed a technical equipment which allows to visualize migration of cells in real-time video-microscopy during altered gravity conditions of NOVESPACE Airbus A300 ZERO-G parabolic flights. For validation of the experimental device we have used fast moving human neutrophils as example, because their migration is fundamental to keep the organism under immunological surveillance. Their migration is indispensable for immune effector function, where the cells leave the blood vessels and navigate to places of infection to fulfill their main task of phagocytosis. Thereby, we have analyzed if their migration is affected during altered gravity conditions and if pharmacological modification of cytoskeletal dynamics influences neutrophil migratory activity. Whereas we detected no change in neutrophil locomotory behaviour in microgravity, we found a significant inhibitory influence of hypergravity, irrespective of the chemical stimulus used. Our results suggest that hypergravity, following a microgravity environment, could represent a hazard to the human immune system function. Thus, our cell migration assay offers an optimum experimental device for studying the migratory activity and underlying signal transduction mechanisms of neutrophils to assess the immunological fitness of humans in space to fight infection, but also for investigating the locomotion of other cell types or unicellular organisms such as ciliates.     

ESA’s Drop Tower Utilisation Activities 2000 to 2011

The European Space Research and Technology Center ESTEC, ESA’s premises in Noordwijk, The Netherlands, has a long lasting cooperation with the ZARM-FAB (Centre of Applied Space Technology and Microgravity—Drop Tower Operation and Service Company) in Bremen on the utilization of the Drop Tower for ground-based microgravity research and space hardware development studies. During the period January 2000 to December 2011 ESA will have procured in total some 840 drops addressing a variety of scientific and technological disciplines. The experiments are usually carried out in campaigns of 15 to 20 drops each, with an annual average of about 5 campaigns. The cooperation agreement between ESA and the ZARM-FAB includes experiment preparation advice by ZARM’s experts, the integration of the hardware into the drop capsule, dedicated safety reviews, the execution of the drop or catapult experiments, the post-flight payload de-integration as well as the handover of acquired data to the experimenters. The experiment hardware itself is provided by the scientists or has to be procured from sources outside of ESA’s drop tower utilization contract. ESA appreciates the cooperation of the ZARM-FAB in Bremen whose drop- and catapult facility provides excellent microgravity quality, is operated by a highly competent, flexible and extremely supportive expert team, allows campaign integration at relatively short notice throughout the entire year, offers real-time experiment operations and immediately after each drop delivers experiment results and provides on-site hardware modification possibilities.     

Foam experiments in parabolic flights: Development of an ISS facility and capillary drainage experiments

We report results of experiments on aqueous foams performed under microgravity conditions obtained during parabolic flights. After a presentation of the FOAM project for the International Space Station (concepts, objectives and technical issues), we show how some of the technical issues can be addressed in parabolic flights. Results on different methods of controlled foam production, and on prototype rheological cells are presented, also offering us the opportunity to review and describe methods of foam production. On the scientific side, we present results of different types of capillary drainage (or imbibition) experiments, based on light scattering measurements. These experiments, performed for the first time on 3D foams with controlled bubble size, surface chemistry and liquid injection rates, are in good agreement with the theoretical predictions.     

Determination of the Secondary Bjerknes Force in Acoustic Resonators on Ground and in Microgravity Conditions

We propose an experimental methodology to determine the secondary Bjerknes force between rigid particles. Measurements done for different particles sizes showed acoustical inter particles interactions. We use and extend the methodology presented in a previous work. The determination of this force will lead us a better understanding of the aggregation process in acoustic resonators. We report in this work, the results of two parabolic flights campaigns performed at the Airbus A300 ZERO-G (Novespace, France).     

ENEIDE: An experiment of a spaceborne, L1/L2 integrated GPS/WAAS/EGNOS receiver

The ENEIDE mission consisted of 22 scientific experiments that were carried out on the Soyuz and on the International Space Station (ISS) during the flight of the Soyuz 10S to the ISS in April 2005. Among these experiments there was the ENEIDE instrument, which gave the name to the whole mission. ENEIDE is a space-qualified, dual-frequency, integrated GPS/WAASEGNOS receiver aimed to the verification of the tracking of GPS plus the augmentation systems from space. The receiver is built by Thales Alenia Space-Italia, Milan plant (formerly Laben), on the basis of the space-qualified dual-frequency receiver LAGRANGE, that will be a payload of several ESA and Italian Space Agency missions like ESA’s GOCE or the Italian COSMO SKYMED constellation to cite few examples. This paper addresses the first results of the ENEIDE flight data analysis.     

Comprehensive Study of the Influence of Altered Gravity on the Oxidative Burst of Mussel (<Emphasis Type="Italic">Mytilus edulis</Emphasis>) Hemocytes

Microgravity induces alterations in the functioning of immune cell; however, the underlying mechanisms have not yet been identified. In this study, hemocytes (blood cells) of the blue mussel Mytilus edulis were investigated under altered gravity conditions. The study was conducted on the ground in preparation for the BIOLAB TripleLux-B experiment, which will be performed on the International Space Station (ISS). On-line kinetic measurements of reactive oxygen species (ROS) production during the oxidative burst and thus cellular activity of isolated hemocytes were performed in a photomultiplier (PMT)-clinostat (simulated microgravity) and in the 1g operation mode of the clinostat in hypergravity on the Short-Arm Human Centrifuge (SAHC) as well as during parabolic flights. In addition to studies with isolated hemocytes, the effect of altered gravity conditions on whole animals was investigated. For this purpose, whole mussels were exposed to hypergravity (1.8 g) on a multi-sample incubator centrifuge (MuSIC) or to simulated microgravity in a submersed clinostat. After exposure for 48 h, hemocytes were taken from the mussels and ROS production was measured under 1 g conditions. The results from the parabolic flights and clinostat studies indicate that mussel hemocytes respond to altered gravity in a fast and reversible manner. Hemocytes (after cryo-conservation) exposed to simulated microgravity (μ g), as well as fresh hemocytes from clinorotated animals, showed a decrease in ROS production. Measurements during a permanent exposure of hemocytes to hypergravity (SAHC) show a decrease in ROS production. Hemocytes of mussels measured after the centrifugation of whole mussels did not show an influence to the ROS response at all. Hypergravity during parabolic flights led to a decrease but also to an increase in ROS production in isolated hemocytes, whereas the centrifugation of whole mussels did not influence the ROS response at all. This study is a good example how ground-based facility experiments can be used to prepare for an upcoming ISS experiment, in this case the TRIPLE LUX B experiment.     

Design and test of an electronic nose for monitoring the air quality in the international space station

Long-term manned space missions requires a continuous monitoring of the air quality inside the spacecraft. For this scope, among several different solutions, electronic noses have been considered. On behalf of European Space Agency an electronic nose specifically designed for air quality control in closed environment is under development. After several ground experiments concerning the monitoring of a biofilter efficiency, the instrument has been tested during the ENEIDE mission on board of the International Space Station. in this paper the instrument main concepts and its performance in ground and space experiments are illustrated.     

Hypogravity Research and Educational Parabolic Flight Activities Conducted in Barcelona: a new Hub of Innovation in Europe

We report on different research and educational activities related to parabolic flights conducted in Barcelona since 2008. We use a CAP10B single-engine aerobatic aircraft flying out of Sabadell Airport and operating in visual flight conditions providing up to 8 seconds of hypogravity for each parabola. Aside from biomedical experiments being conducted, different student teams have flown in parabolic flights in the framework of the international contest ‘Barcelona Zero-G Challenge’, and have published their results in relevant symposiums and scientific journals. The platform can certainly be a good testbed for a proof-of-concept before accessing other microgravity platforms, and has proved to be excellent for motivational student campaigns.     

Ring-Sheared Drop (RSD): Microgravity Module for Containerless Flow Studies

Microgravity is potentially a powerful tool for investigating processes that are sensitive to the presence of solid walls, since fluid containment can be achieved by surface tension. One such process is the transformation of protein in solution into amyloid fibrils; these are protein aggregates associated with neurodegenerative diseases such as Alzheimer’s and Parkinson’s. In addition to solid walls, experiments with gravity are also subject to influences from sedimentation of aggregates and buoyancy-driven convection. The ring-sheared drop (RSD) module is a flow apparatus currently under development to study formation of amyloid fibrils aboard the International Space Station (ISS). A 25 mm diameter drop of protein solution will be contained by surface tension and constrained by a pair of sharp-edged tubes, forming two contact rings. Shear can be imparted by rotating one ring with the other ring kept stationary. Here we report on parabolic flights conducted to test the growth and pinning of 10 mm diameter drops of water in under 10 s of microgravity. Finite element method (FEM) based fluid dynamics computations using a commercial package (COMSOL) assisted in the design of the parabolic flight experiments. Prior to the parabolic flights, the code was validated against experiments in the lab (1 g), on the growth of sessile and pendant droplets. The simulations show good agreement with the experiments. This modeling capability will enable the development of the RSD at the 25 mm scale for the ISS.