Projects-MOONSHOT ACADEMY

Zero-Carbon Building-Building a Sustainable Future

Disciplines/Subjects: Architecture, Environmental Science, Engineering, Physics Key Themes: Zero-Carbon Building, Renewable Energy, Smart Building, Carbon Neutrality, Sustainable Development In the face of the intensifying global climate change, humanity is confronted with unprecedented environmental challenges. Scientific research indicates that the construction industry is one of the major sources of global carbon emissions, accounting for a significant proportion of the total global emissions. To tackle this challenge, countries around the world are taking action to reduce carbon emissions in the construction sector. China, as one of the largest construction markets globally, is actively responding to the national "dual carbon" goals (carbon peak and carbon neutrality), promoting the green transformation of the construction industry, and achieving sustainable development. Against this backdrop, our project is launched. It aims to design and construct a zero-carbon building model through interdisciplinary collaboration, demonstrating how to achieve minimal environmental impact and maximum energy efficiency in architecture. Students will learn the principles of zero-carbon buildings, including energy efficiency, renewable energy integration, and resource management, and apply them to real architectural design. The core of the project is to have students work in teams to design and build a building model that incorporates renewable energy systems (e.g., solar panels) and green building technologies (e.g., green roofs, rainwater harvesting systems). Students need to consider the energy needs of the building, material selection, environmental adaptability, and aesthetic design. They will ultimately present their model and explain their design choices and how they align with zero-carbon goals. Through this project, students will not only master the theoretical knowledge of zero-carbon buildings but also develop teamwork, problem-solving, and innovative design skills. This project is not only a practical exploration of architecture but also a profound experience of sustainable development and a contribution to global climate goals.

Exploring Trade in West African Countries: Creating a Visual Work Centered on a Proposal

Disciplines/Subjects: Social Science Key Themes: a Community with a Shared Future for Mankind, Trade, West African Countries, Artificial Intelligence (AI) Under the grand vision of the Belt and Road Initiative, China-Africa cooperation is increasingly becoming a global focal point. As a future international relations expert, you will have the opportunity to explore this promising region, applying interdisciplinary knowledge from mathematics, history, and computer science to examine how trade can drive shared prosperity. This project requires you to select a West African country, conduct an in-depth analysis of its trade landscape, identify opportunities and challenges, and write a proposal outlining strategies for economic development. Additionally, you will create a visual piece—whether a poster or video—to present your insights in an engaging and accessible way, helping the public understand and care about West Africa’s future. Through this project, you will enhance your data analysis and problem-solving skills, while learning how to articulate your ideas clearly and persuasively. Your work will be showcased in school gallery corridor and may also be featured on public platforms, allowing more people to witness your efforts and achievements. This is not only an academic leap but also a significant step in personal growth. Let us work together to contribute to the harmonious development of a Community of Shared Future for Mankind, shaping a more equitable and sustainable global trade system for the future.

Biomimetic Design

Disciplines/Subjects: Science、Language、Engineer Key Themes: Creativity, Design, Biomimetics Biomimetics is a discipline that involves understanding the principles and mechanisms of biology and applying this knowledge to fields such as engineering, technology, and design. It aims to imitate the structures, functions, and behaviors of living organisms in nature to develop products and systems that are more efficient, energy-saving, environmentally friendly, and intelligent. The applications of biomimetics are extremely broad, including robotics, aircraft, automobiles, architecture, materials science, medicine, and more. Common examples of biomimetic design in our daily lives range from large-scale items like airplanes and eco-friendly buildings to smaller ones like medical bandages and swimsuits. All these are inspired by nature, which provides endless inspiration to designers willing to change reality. In this project, third-grade learners will observe the different characteristics of plants and animals, identify real-life problems that need to be solved, establish connections between the two, and attempt to design a biomimetic product to address these practical issues. Even more excitingly, they will have the opportunity to embark on an entrepreneurial journey. They will hold a formal product launch with their own design. If they receive support from more judges, they may even have the chance to initiate the production of their entrepreneurial product! Throughout this process, they will act as product designers, understanding what a product is, who it aims to solve problems for, what unique design it should have, and how to transform a design into a tangible prototype. They will also be entrepreneurs, needing to deliver a presentation to showcase their achievements and growth. Of course, we also encourage them to fulfill their roles and contribute within their teams. If they can manage budgeting and design, it may offer even greater assistance to their entrepreneurship.

Exploring the Chicken-Vegetable Symbiosis System - A Learning Journey from Life to Ecology

Discipline/ Subject: Biology, Ecology, Engineering Key Themes: Life Cycle, Ecological Cycle, Engineering Design, Sustainable Development This project follows the life cycle of chickens as the main thread, integrating ecological cycles and engineering design concepts to create a chicken-vegetable symbiosis system that promotes sustainable agricultural practices. Learners will explore the entire process of chicken incubation, growth, rearing, and its symbiotic relationship with plants while continuously optimizing the system through engineering design and scientific experimentation. The project covers the stages of egg incubation and chick development, the construction and management of the chicken coop, the application of microbiological technology in chicken manure treatment, and the continuous optimization of the ecological symbiosis system. Through hands-on practice, teamwork, and scientific inquiry, learners will enhance their problem-solving abilities and gain a deeper understanding of ecological cycles and sustainable development principles.

3D Geometric Model Design

In this interdisciplinary project, learners will integrate Geometry (Math) and basic Computer Science (3D CAD modeling) to create a new 3D-printable object by combining common geometric solids (cubes, rectangular prisms, cylinders, cones, etc.). Real-World Context. Students imagine a scenario where they must design a small object for a specific function such as an organizer, a desk accessory, or a decorative figurine. They learn how shape choice, dimensions, and angles affect both the visual appeal and structural stability of the item. Core Activities. Ideation & Sketching: Students research real-world objects, brainstorm designs, and sketch initial ideas using geometric solids. CAD Modeling: Students import or construct shapes in a user-friendly 3D CAD environment (e.g., Tinkercad or Fusion 360), focusing on alignment, scaling, and boolean operations (union/subtraction) to create a combined model. Math Connections: They calculate approximate surface area, volume, and predict 3D print times or materials used. This might also involve problem-solving around stability and weight distribution. Iterative Prototyping: Students print small-scale prototypes, observe flaws or design improvements, then adjust the model and reprint if time allows. Presentation & Reflection: Learners showcase their final 3D-printed object, explain the design choices, and reflect on how math and computer science skills drove their success.

Capturing the trajectory of movement under slow-motion lenses

Disciplines/Subjects: Health and Sports & Visual Arts Key Themes: Slow motion and movement trajectory. Scientific Research and Artistic Presentation Biomechanical Analysis: Slow-motion footage can be utilized in biomechanical studies to scrutinize muscle activity and force transmission during movements. For instance, when examining the batting trajectory in baseball, slow-motion can capture the muscle contractions and the path of the movement, providing a foundation for scientific training. Data Recording and Analysis: Slow-motion can record detailed data of movements for subsequent analysis and research. For example, in track and field training, it can document an athlete's running posture and stride frequency, assisting coaches in devising more scientific training plans. Visual Effects Presentation: Slow-motion enhances visual effects, enabling students to more intuitively comprehend the physical processes of movements. Display of Action Details: Slow-motion can clearly reveal complex actions and movement trajectories, allowing the audience to appreciate every detail of the action. For example, in action films, slow-motion is often used to showcase stunts and fight scenes, intensifying visual impact. Aesthetic of Movement: Slow-motion can transform ordinary actions into visually appealing experiences with artistic beauty. For example, slow-motion footage of dance or sports movements can highlight the grace and power of motion. Students will take burst photographs of their peers' swinging motion, stitch each frame together in photoshop as a work of chronophotography. Through the process, they will observe the continuous motion of sport and transform it into colorful visual languages.

Super Clean Life

Disciplines/Subjects: Language、Science、Social Study、Visual Arts Key Themes: Empathy、Clean life、Material change、Marketing and sales In this project, learners will act as an expert team to help "Stinky Princess" solve some of the problems she encounters in her life. "Stinky Princess" hopes to find a magical soap that not only makes her clean and fragrant but is also made from eco-friendly and healthy materials. During this learning journey, learners will be assigned the following roles: Bacteria Investigator: When they put on the white investigator's hat, they need to gather as much knowledge as possible about bacteria through various channels, create a set of bacteria profile cards, and make an "ID card" for the bacteria residents. Healthy Lifestyle Guardian: When they put on the green guardian's hat, they need to explore and experience a lifestyle that coexists harmoniously with bacteria and nature during their outings, and document their inspirations and creative ideas. Magic Experimenter: When they put on the blue experimenter's hat, they will use their knowledge of acids, bases, and changes in states of matter to conduct chemical magic experiments. Fragrant Clean World Inventor: When they put on the yellow inventor's hat, the most critical part of the project arrives, soap making! In this phase, they need to consider factors such as cleanliness, environmental friendliness, scent, safety, and user needs. Soap Company Salesperson: When they put on the red salesperson's hat, it means they need to find suitable customers to promote their product. At this stage, they must use specific sales techniques tailored to different clients to market their product effectively.

Simulated Store Shopping Experience

Disciplines/Subjects: Mathematics Key Themes: Money Price Calculation Role-playing, Shopping Experience Change Transaction In the Grade 2 Mathematics "Money" unit, students engage in an interactive and fun hands-on project—simulating running a small store. In this activity, students are divided into groups and take turns playing the roles of customers, shop assistants, and cashiers. The activity includes: Setting Prices for Items: Students apply their knowledge of price calculation to assign prices to different items. Role Distribution and Interaction: Students rotate between being customers and store staff, learning about store operations and transactions. Simulated Shopping: Customer groups use simulated RMB to purchase items from their designated stalls. Shop assistants help customers select products and inform them of the total price. Cashiers handle payments and give change when necessary. This activity not only allows students to apply their mathematical knowledge in a real-world context but also helps them understand the concepts of money management, price calculation, and social interaction through role play.

Projects

Each project is like an adventure journey. As little detectives, we keep asking questions and, with curiosity and courage, try to solve every challenge.