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Learning Objectives

At the end of this simulation, you will be able to:

Learn the principles of bioremediation and explore virtual labs where microbes are used to treat contaminated soil, water, and air.
Analyze the effectiveness of microbial interactions and their role in environmental cleanup processes.
Participate in interactive tutorials to design and simulate biofilters for air and water purification.
Use virtual experiments to study the degradation of pollutants and trace the breakdown products in different environmental conditions.
Develop strategies to minimize waste generation, reduce pollution, and promote eco-friendly biotechnological solutions.

How do virtual labs work?

Enhance students' involvement in science by immersing them in interactive learning scenarios. Create simulations for experiments, provide hands-on training in laboratory techniques, and convey theoretical concepts through captivating visual experiences to improve their overall long-term learning outcomes.

Access web-based simulations that are compatible with laptops, Chromebooks, tablets, and iPads, eliminating the need for software installation.
Incorporate a teacher dashboard for automated grading and monitoring of student progress.
Utilize embedded quizzes to assist students in mastering scientific content.
Comprehensive repository of educational materials, including learning resources, lab reports, videos, theory pages, graphics, and more.

Environmental Biotechnology and Bioremediation

Relevant Course Packages All Course Packages →

Product Lifecycle Management (PLM)

This XR simulation teaches students about the comprehensive processes involved in managing a product's lifecycle, from initial conception through design, development, production, and eventual retirement. Virtual tools allow students to coordinate product design, development, production, and sustainability, integrating CAD, CAM, and data management into the development cycle. Students will interact with real-world scenarios to optimize project timelines, resource allocation, and overall product lifecycle efficiency. Feedback is provided on their decisions related to production costs, environmental impact, and product sustainability.

Mechanical System Design and Optimization

Enable students to design and optimize complex mechanical systems through XR simulations. The simulation offers virtual scenarios where students can create and refine mechanical systems like engines, HVAC systems, turbines, and gearboxes. They will use interactive tools to adjust system parameters, reduce weight, improve efficiency, and lower production costs. Real-time feedback will guide students on design constraints, feasibility, and cost-effectiveness, helping them develop the skills to optimize mechanical systems for peak performance.

Welding Blueprint Reading and Symbols

The Welding Blueprint Reading and Symbols simulation uses XR to enhance understanding of welding blueprints and symbols, enabling accurate interpretation and application of welding instructions.

Medical Device Design and Prototyping

Immerse students in the principles of medical device design, prototyping, and testing with a cutting-edge XR-powered simulation. Through virtual scenarios, learners can design devices such as prosthetics, implants, diagnostic tools, and wearables, create interactive 3D models, and simulate their functionality, durability, and compliance with regulatory standards.

Suspension Systems and Ride Comfort Analysis

Suspension Systems and Ride Comfort Analysis focuses on the design and tuning of automotive suspension systems to achieve optimal ride quality and handling. Students will engage in virtual scenarios to adjust suspension components such as shock absorbers, springs, control arms, and anti-roll bars. The course includes interactive lessons on suspension geometry, damping characteristics, and vehicle stability, with feedback on ride comfort, handling precision, and minimizing road vibrations.

Mechanics of Solids and Fluids

Equip students with the foundational knowledge of solid mechanics and fluid dynamics, key principles in engineering applications. This course focuses on understanding the behavior of solid materials under stress and strain, as well as the movement of fluids within various engineering systems. Students will explore how these principles interact to optimize structural designs and fluid-based systems.

LMS Integration

imaginX seamlessly integrates with leading LMS (Learning Management Systems), enabling educators to track student performance and allowing students to maintain their work records. It is compatible with popular platforms such as Canvas, Blackboard, Moodle, Google Classroom, Schoology, Sakai, Brightspace/D2L, and can also be used independently of an LMS.