Ruvimbo SamangaSpace Law & Policy Analyst On the 2nd of October 2020, the Astro Zimba space education curriculum for young children began its programme, launching a pilot study with the Whitestone School, in Bulawayo, Zimbabwe. This space education curriculum recognises that building Zimbabwe’s space autonomy is hinged on the nation’s capacity to make a critical mass of skilled individuals. This capacity-building must necessarily begin from the early developmental stages. The Astro Zimba curriculum, created by myself and Marco Romero, in collaboration with InnovaSpace and Students for Exploration & Development of Space (Zimbabwe), is a series of lectures on space and space-related themes, using interactive sessions, games, videos, comic books and other learning activities to spark space science and technology curiosity amongst the youth. This is done in the hopes that more children, especially young girls, will be inspired to take up STEM subjects and careers. The founders of this programme identified a gap in existing curricula, one which they wish had been filled during their initial years, and one which they believe has a profound impact on the development of the space industry. Space sciences and technology, while a rapidly developing and exciting field, can often be quite a technical subject area for young children to understand. That said, having a dedicated programme which delivers science content in an engaging, tailored and fun way helps to boost interest in young children. It has the dual effect of inspiring both genders to become involved, which is the goal of the Valentina project for girls, facilitated by InnovaSpace, acknowledging that young girls are underrepresented in the STEM sciences. Giving access to quality education boosts social and economic circumstances, alleviates poverty and empowers young girls, positively impacting on the SDG 1 (poverty reduction), SDG4 (quality education) and SDG5 (gender equality). The following lesson plans were presented during the pilot study. The introductory video sought to spark the learner’s curiosity and inspire more children to pursue careers in the space industry. Having careers in the space industry, the Founders thought it important to add a touch of personal experience and insights, including initiatives that have made a difference in their personal career journeys. The learners are introduced to each week’s theme through an interactive video message, before proceeding with practical in-person class sessions. Tafadzwa BangaNational Point of Contact, Space Generation Advisory Council - Zimbabwe High Altitude Balloon Discover Mission (HABDM) is the first space student-led project that has been done in Zimbabwe. The project was a collaborative engagement project between students from the Students for the Exploration and Development of Space Zimbabwe (SEDS Zimbabwe) and the Meteorological Service Department (MSD) of Zimbabwe. The purpose of this mission was to spearhead space education in Zimbabwe and ensure that students are aware of the opportunities that space has. Our primary goal was to record the flight to the stratosphere and use that footage for educational purpose as well as celebrating the World Space Week. Prior to the launch date we decided that we would send our payload together a radiosonde from the MSD so that we could compare the atmospheric information obtained. To add to the mission, we covered the capsule pink acknowledging that the month of October is the month for breast cancer awareness. It only took us three days to have all the equipment for the payload. Despite the risks involved and the probability of failing to recover our instruments was high because we did not have enough time to prepare. We had seen videos of well-prepared teams who had done high altitude projects facing some challenges in recovering their payloads when they were using state of the art equipment. So in our case to avoid too much disappointment we had to lower our expectation and accept any outcome. On the 10th of October the whole team met at the MSD offices and without wasting time the balloon was launched. We were graced by the presence of the Deputy Director of MSD Zimbabwe, Mr Mazhara. Unfortunately on the launch the weight of the payload posed a huge challenge. We ended up removing the radiosonde to ensure that the balloon ascended to the stratosphere. Our payload consisted of two cameras, mobile device, usb adapter, power bank and a data logging system. The team consisted of students from University of Zimbabwe and National University of Science and Technology Zimbabwe, with the assistance from Claire a geography teacher at St John’s College in Harare and William, a self-employed space enthusiast. It was through the collaborative effort of the team that we were able to have all the resources that were needed for the launch. The MSD came through for us by providing us with the balloon and hydrogen gas. This week InnovaSpace is highlighting the great work taking place in Angola by the Academy of Kandengue Scientists, with a blog written by Mentor of the project Pedro Paris and Aeronautical Engineer Marco Romero. We thank the Academy for the contribution of their students to our Kids2Mars project - and for their amazing work in creating opportunity for the local people and community! You are all stars! The Academy of Kandendgue Scientists is a technology-based start-up that empowers children and adults from 5 to 25 years of age, instilling the seed of inventive and technological skills from an early age. Enabling children to discover their own potential helps them to avoid bad practices, such as drugs, prostitution and delinquency, and envisages a society that is technologically well prepared for future challenges, and perhaps even a renewed Africa. Formed in 2017 by Professor and Inventor Pedro Paris (telecommunications technician) and Aeronautical Engineer Marco Romero, the project aims to provide more opportunities for children and young people without access to education. In 2012, an ordinary residence in Viana in the province of Luanda was transformed into a laboratory, an explanatory and preparatory centre, and 5 years later the idea was born to include children who lacked the opportunity to access education, but who, like others, had the enormous potential to become “Kandengue Scientists”. The Academy already has the involvement of around 80 Kandengues aged from 6 to 30 years, of which 30 are now tutors with more than 5 years of experience, having been trained by Professor Pedro Paris. KANDENGUE VISION: To transform children and adults from Angola, Africa and the World into budding scientists and professional IT technicians, so they can provide solutions to the problems of their community and country. KANDENGUE MISSION: To bring sustainable technologies to the neediest communities, occupying the spare time of children and adults with art, education and sustainable technology. KANDENGUE VALUES: Discipline, Love, Patriotism In recent years, more than 976 children and adults from private and public schools, and foster homes throughout the nation have learned the basics of electronics, robotics, programming, game development, applications, aeronautics and space technology, thanks to the “Kandengue Scientists”. Changes in the lives of many families can already be felt, having received the tools and knowledge needed to put bread on their tables, having access to schools and universities, and solving community problems. The financial and logistical difficulties for ensuring better conditions for the children in the development of educational activities are initially resolved by the tutors, who create teaching methods and materials tailored to existing conditions, for example, reusing electronic waste for e-learning and the creation of decorative and visual arts. Partnerships with public entities have already taken place in 2019 and 2020, such as with the network of Angolan media libraries, Ministry of Telecommunications and Information Technologies (MTTI), National Technology Centre, Ministry of Higher Education, Science, Technology and Innovation (MESCTI), BusCenter, Unitel, Methodist University of Angola, and the Seaka Center (Angolan Spiritualist Society Allan Kardec), in which the academy made available 10 professors to help the institution with a lack of teaching staff. Some of our KEY SUSTAINABILITY INITIATIVES are:
And below are just some of the ideas and projects the Kandengue Scientists have been developing:
“innovations arise from simple ideas that fully resolve the observed problem” If you would like to know more about the Kandengue Scientists and the wonderful work they do in Angola, do get in touch with Marco Romero at - [email protected] The First Lego League (FLL) is an annual international tournament involving teams of young people aged 9-16 years. It introduces a scientific and real-world challenge for teams to focus on, research, and create solutions to identified problems, and includes a robotics challenge to perform a set task with a programmable robot constructed from LEGO electronic and mechanical components. This year, over 40,400 teams competed in regional, national and international tournaments with their ideas, including team AC/DC/EG from Brazil, who had a very successful competition and were kind enough to give us an insight into their FLL Into Orbit experience in this year's competition, in their words below: "The AC/DC/EG team was created on 07/12/2007 to represent the Eduardo Gomes College in São Caetano do Sul, Brazil in the FIRST LEGO League tournament. The team name is formed from the name of the rock band AC/DC together with EG for Eduardo Gomes, and so far, we have participated in competitions at 11 State, 11 National and 7 International stages. The 2018/2019 FLL - INTO ORBIT tournament has been sensational for us. Our team began taking shape in May 2018, and underwent some changes, beginning with 8 team members and finishing up with 5 members - Eduardo, Felipe and Sophia (from the beginning), and later joined by Gabriella and Fernanda. And it was with this team of 5 that our coach Reginaldo and mentors Giovanni and Giovanna reached the end of the competition. The official launch of the FLL tournament took place on August 1st 2018, so we used the time from May to August to research several problems related to this year's theme by visiting universities, watching films and videos, reading books, magazines and theses, and talking to experts in the field. At the beginning of September, we talked with Aerospace Medicine & Space Physiology specialist Dr Thais Russomano, presenting to her everything we had studied so far, and it was during one of our initial conversations that we realised there was a problem faced by astronauts, which is: WASHING IN SPACE We already had the FLL competition documentation in this initial period of our discussions so we began to compare the problems raised to make sure they fitted in with the competition guidelines. In all, we analysed 14 problems: A phrase we heard that marked our work was by NASA space scientist Robert Frost, who said: "When several people are trapped in an enclosed space, HYGIENE IS OF GREAT IMPORTANCE." So, having done our analysis, we chose the subject of how to wash the body in space and defined our problem: THE INEFFICIENCY OF WASHING IN MICROGRAVITY And we asked: HOW CAN WASHING BE MADE MORE EFFICIENT IN MICROGRAVITY? We continued studying, raising new points and discussing them with Dr Russomano. We looked at the ways of washing that have previously been used and the current method of washing in space. ⇨ A sponge with soap and water, used during the Gemini and Apollo missions. ⇨ A shower on the MIR Space Station that wasted a lot of time, water and energy. ⇨ The Russian kit, which consists of a pre-moistened wipe and can be used for up to 3 days, using less water. ⇨ The NASA Kit, which is a cloth moistened with soap and water. We noted that, to be ideal, washing should be able to deal with dead skin cells, sweat, oiliness, odour, and bacteria and fungi! We had a lot of ideas, including a kind of human jet wash that used little water – but this and other ideas were discarded as our objective was for something low-cost, water-free and lightweight, that would occupy very little space on a spacecraft. It was in thinking about this goal that we discovered a gel called DryBath, created by Ludwick Marishane, mostly for use on the African continent and in places with a scarcity/lack of water. Ludwick’s idea is that water should only be used for drinking and cooking, and for washing it can be replaced by the gel. With just 15ml of the gel, it is possible for an adult to wash without using water, and without the need to remove the gel from skin, as it is moisturising. All of our team tried using the gel, including our coach. The benefits of the gel in comparison with the existing solutions are enormous, as besides dispensing with the need for water for washing, there is a gain in transport weight and the gel occupies a minimum of space on a spacecraft. However, we needed to know its viability for use in space, so we talked to Chemical Engineer Matheus Messias, who confirmed the gel is non-flammable, and with Dermatologist Oswaldo Cipullo, who said the gel fulfils all the requirements for body washing and can be used daily. Nonetheless, the current gel packaging makes it unfeasible for use in space, as it generates a lot of waste. Therefore, after some brainstorming and tests, we developed a new storage and application system utilising a 2-litre urine collection bag filled with gel, calculating that each explorer would need 3 such bags to cover a 1-year period. Each bag is fitted with a valve connector to guarantee the pressure required to transport the gel into a syringe-type applicator, which allows its controlled delivery to the body. This system for gel storage and use saves important resources, enables fast application, requires no cleaning of the equipment, has no loss, and needs no repairs. Currently, 4 litres of water is used in space per wash, whereas, with this quantity of gel it would be possible to have 266 washes, meaning water will no longer be needed for washing the body and can be used for something else within the spacecraft. The cost of the gel and the system is 1610 Brazilian real (approx. £310) per person for a year. Therefore, it is possible to take something that was designed for use on Earth and adapt it to make its use possible in space, rather like the tortillas of astronaut Rodolfo Vela, as quoted in the FLL Into Orbit competition guidelines." The InnovaSpace team would like to congratulate the AC/DC/EG team and everyone who supported them for their success and the enthusiasm and joy they brought to the tournament stages! Congratulations also go to the thousands of teams from around the world for their hard work, curiosity, research and enthusiasm - YOU ARE ALL STARS!
Authors: Kids from the STEP Computer AcademyAnd InnovaSpace Admin Director - Mary Upritchard Over the last few months, InnovaSpace's very own space doctor, Thais Russomano, has been listening to some of the First Lego League tournament teams talking about the projects they have developed for this year’s Into Orbit mission, answering their questions and giving some tips as to areas they might also consider. The annual competition has teams taking part from all over the world (92 different countries this year), adopting a different theme each time linked to robotics and the STEM areas, and aimed at encouraging young students to improve critical thinking and team-building skills, stimulating their creativity and giving the opportunity to present their projects in public in front of judges. As part of this year’s competition, students have been thinking about ways to improve the life, health and wellbeing of astronauts in space, with some really constructive and original ideas being contemplated by these bright young minds. We were approached by teams from the STEP Computer Academy in Seattle USA a little while back, with great questions they had about their projects. With Thais having given them some feedback, we were delighted to hear recently that 3 of the 5 Into Orbit teams from the academy had made it through to the semi-finals of their national competition, and we are even more delighted now to be able to present three short texts from those teams: Gabriela Albandes de SouzaInnovaSpace Culture & Education Project Manager The InnovaSpace outreach projects Valentina and Astronaut for a Day had another edition in Brazil last week, with company founder, Dr. Thais Russomano, giving two space science talks to students from the state school Olegário Mariano, in Porto Alegre. The first lecture, watched by 48 teenagers from the 9th year (aged 14-15 years), focused on the Valentina initiative, which aims is to raise the interest of girls in the sciences and to break gender prejudice by highlighting those women who have made important contributions to the development of the space program since its inception. Following a final Q & A session in which the curious students asked many interesting questions, the group were asked to use their creativity to build a rocket using simple materials provided by the school, such as fizzy drink bottles, cardboard boxes and aluminium foil. Chatting with the students afterwards we found that, while some said they already intended to pursue careers in the STEM areas, others became interested after getting to know the many possibilities that these fields offer. The second lecture of the day, called Astronaut for a Day and attended by 25 5th year students (aged 10-11 years), explained how astronauts live and work in space, the impact of microG and radiation on human physiology, and the importance of the spacecraft and spacesuit in keeping the astronauts alive and well in space. The students also watched a video about the life of the crew aboard the ISS and were amazed by the differences between life in space and on Earth. These inquisitive young people actively participated in the event, raising their hands to answer questions posed by Dr. Russomano (five raised hands when asked who wanted to be an astronaut), and coming up with questions of their own about many aspects of life in space. At the end of the presentation, this group were set the task of making a spacesuit from the materials provided, while a group of young ladies resolved to create a spacecraft.
Roberto FanganielloInnovaSpace Scientific & Strategic Consultant. In this month of November I have joined the University of Eastern Piedmont (Università degli Studi del Piemonte Orientale Amedeo Avogadro - UPO) to lecture BSc students on basic and applied research in regenerative medicine and tissue regeneration, MSc candidates on innovations in medical biotechnologies, and PhD candidates on bone and cartilage tissue bioengineering. These courses are very much in line with my own three-pronged professional interests: basic and applied research, educational projects/programs, and technology transfer from academia to the market. With different degrees of depth, the main purpose of these courses is to provide students with a concrete understanding of complex biological systems, studied at the molecular, cellular and physiological levels (and especially related to humans), to equip them with practical knowledge of state-of-the-art biotechnological protocols used in the medical field, and to guide them on developing communications and networking skills in order to cooperate in multidisciplinary, multifaceted teams. The ultimate goal is to prepare them so they will be able to quickly fit into the working environment, at national, European and extra-European levels after graduation. Anthropology Of outer Space - On human/non-human relationships in the context of space science19/10/2018
One of the first ethnographies I read when beginning my Social Anthropology Master’s degree course was Beamtimes and Life Times: The World of High Energy Physicists (1988), by Sharon Traweek. She based this seminal account on her five years of fieldwork within the almost exclusively male domain of particle physicists, studying their culture, cosmology and worldview. One fascinating aspect that she underlines is the peculiar relationship that exists between these scientists and the accelerators and detectors they use to identify subatomic particles and understand their behaviour. The accelerators are some of the largest machines built and a great part of the scientist’s life is spent inside them: hence, not just a machine, but a place. Inside these accelerators are placed the detectors, each designed and crafted by a group of scientists to find answers to their specific research questions: not just a machine, but a conceptual and intellectual fingerprint. A new particle found may unveil a big mystery about the universe and catapult a scientist to academic stardom, however, it could also prove the whole hypothesis to have been built on a misguided assumption and thus, failure. As cosmologies and careers are at stake and the data collected may promote a paradigm shift, the detectors hold the hope of access to a hidden world. Therefore, they are more like portals than machines. There is a same high dependency on machines in space science in order to access far away or invisible events and data, and this steered my attention toward human/non-human relationships in this context. This dichotomy itself is rather a cultural construct, and in some cultures this line is not clearly defined and is variable according to the cultural context, being more or less defined in certain places at certain times. In the context of space science, it becomes even more blurred. When applied to an astronaut, for instance, this concept tends not to make sense. In fact, an astronaut only becomes an astronaut in conjunction with the spacesuit/spacecraft, or they would be unable even to reach space to become a space-traveller. In this sense, you do not have simply the human (astronaut) and the non-human (spacesuit, spacecraft), but one single entity. An astronaut is inexorably a cyborg: a hybrid of organism and machine. The tagline of the InnovaSpace Valentina project is ‘Science is for girls too!’ – an ideal we very much support, and an excellent example of which is Space Physiologist, Dr. Julia Attias, who is a PhD Researcher at King's College London. I had the pleasure of meeting Julia a few years ago when she was doing her Master’s degree in Space Physiology and Health (2012) at King’s College London, which then led on to her completing a PhD in Space Physiology (2018). Julia is passionate about inspiring young ladies to pursue a career in the STEM areas, and dedicates some of her time to writing blogs for websites such as WISE (Women In Science and Engineering), and a charity, GlamSci, aimed at breaking down perceived stereotypes and barriers to STEM areas. We asked Julia a few questions about her life and path to becoming a space physiologist: What sort of child were you? I can say I was a very energetic child and very focused on sports activities from a very early age. My Mum was a tennis coach, so from about the age of about 4 years old, I could be found running around a tennis court, gripping my first racquet in hand, on which someone had spray-painted the letter ‘J’. Naturally enough by the time I started school my favourite subject was PE (physical education), at which I was always very competitive indeed! What were your school years like? I was lucky enough to go to great schools; I enjoyed my school years and made some good friends. At primary school I sometimes used to get in trouble for talking too much, but in fact it wasn’t just idle chatter for the sake of it, it was my constant curiosity about anything and everything that made me ask questions and comment out loud - too loud sometimes! I loved music (probably inspired by my Dad who was a drummer) and being in plays at primary school, and continued this on into my teenage years when I joined the Pineapple Performing Arts School in Covent Garden. I learned street dance, singing and acting there, and grew up wanting to be in front of the camera - this ambition I have since achieved through participating in a Discovery Channel series called 'Meet The SuperBrains' and more recently in the Channel 4 series 'Food Unwrapped''. |
Welcometo the InnovaSpace Knowledge Station Categories
All
|