The difficulty of applied physics versus pure physics can vary depending on individual perspectives and preferences. Both branches of physics have their own unique challenges and complexities. Here's a general comparison:
Pure Physics: Pure physics, also known as theoretical physics, focuses on understanding the fundamental laws and principles that govern the universe. It involves theoretical exploration, mathematical modeling, and conceptual analysis. Pure physicists aim to uncover the underlying mechanisms and explain natural phenomena through rigorous mathematical frameworks.
Challenges in pure physics stem from its abstract nature and the need to grasp complex mathematical concepts. It requires a high level of mathematical proficiency, as well as strong analytical and critical thinking skills. Pure physics often involves developing and working with advanced theoretical models, which can be intellectually demanding and require creative problem-solving.
Applied Physics: Applied physics, on the other hand, involves utilizing principles and theories of physics to solve practical problems and develop real-world applications. It encompasses various fields such as engineering, materials science, optics, electronics, and more. Applied physicists bridge the gap between pure physics and technology, working on designing, developing, and optimizing systems and devices.
The difficulty in applied physics lies in the multidisciplinary nature of the field. Applied physicists need a strong foundation in pure physics, along with a deep understanding of other disciplines relevant to their area of specialization. They often face challenges in integrating physics principles with engineering constraints, practical limitations, and technological considerations. Problem-solving in applied physics requires both theoretical knowledge and hands-on experimental skills.
In summary, the difficulty of applied physics versus pure physics depends on one's aptitude and interests. Pure physics can be intellectually challenging due to its abstract and mathematical nature, while applied physics requires a broader knowledge base and the ability to apply physics concepts to real-world scenarios.