Applied chemistry is the application of the principles and theories of chemistry to answer a specific question or solve a real-world problem, as opposed to pure chemistry, which is aimed at enhancing knowledge within the field.
Applied Chemistry covers a wide range of chemistry fields and is involved in a variety of materials, including metal compounds, inorganic and organic compounds, polymers, proteins, etc., doing basic research and applications.
Applied Chemistry is striving to contribute to the advancement of modern society by designing new materials synthesis processes and creating new functional materials based on a deep understanding and precise control of various chemical reactions.
Applied Chemistry focuses on inorganic and organic compounds with nano and mesoporous structures, functional solid materials of polymers and their hybrid systems, from their basic physiochemical properties and their use in catalysts, sensors, electronic devices, etc.
Applied Chemistry also focuses on structural-functional relationships in biomolecules such as proteins and nucleic acids, separation and wastewater treatment methods, plant biotechnology, protein engineering, and protein production methods in synthetic biology and medicine.
Applied chemistry students have basic knowledge, theory, skills of chemistry and relevant engineering and technical knowledge as well as strong experimental skills. Through scientific thinking and scientific experimental training in basic research and applied basic research, graduates can be employed in scientific research institutions, institutions of higher education and enterprises. Their primary responsibility is scientific research, teaching and management in the chemical industry.
Compared with other majors, the employment rate of applied chemistry graduates is very high. The employment areas include education, environmental protection, building materials, chemicals and machinery. The employment department includes quality supervision and inspection departments at all levels, research institutes, design institutes, teaching units, and production enterprises.
Pure chemistry or applied chemistry, which is better?
For students who like chemistry, they don’t know whether to choose pure chemistry or applied chemistry. If you enjoy the task of manipulating chemicals into new substances then applied chemistry is the most fun - pure chemistry tends to be all theory and little action.
In short, pure chemistry is a study of how elemental atoms react or combine with other elements to form different compounds, substances, and materials. While applied chemistry refers to the use of knowledge generated by purification to solve specific problems or achieve specific results.
Pure chemistry is more about theory, and applied chemistry involves practical applications such as polymer chemistry, ceramic industry, the pharmaceutical industry. Think about the polyethylene you use, the cement you use to make the building or the drugs you take are included in the applied chemistry. Group theory and Quantum mechanics are examples of pure chemistry.
One of the tasks of pure chemistry is to study the elemental composition of new types of rock. This does not seem to have commercial value, but it has great scientific value. You can also study the three-dimensional structure of newly discovered substances to gain pure scientific interest and knowledge. This work is usually funded by grants and published in peer-reviewed journals, both of which are powerful measures of academic success. But for students who are now looking for better and broader employment opportunities, the industry needs more patience and time.
In fact, I recommend learning applied chemistry than pure chemistry due to reasons as follows. Applied chemistry has it's own benefits, in this you learn most about the processes, production, designing of equipment and also analytical techniques. I prefer applied chemistry if you want to do a job in industries. Applied chemistry graduates have diversified options for entry level in industries.
By definition, many things are examples of applied chemistry in our daily life. Metal forging and metallurgical science are examples of applied chemistry. In general, the manufacture of drugs and drugs is also an example. Explosives, cars, tape, plastics, oil industry, textiles and so on. Almost every field and industry is attributed to chemistry and its applications.
The course of Applied Chemistry is a combination of chemical and chemical engineering. Students used to participate in 4-5 laboratories each week, and they are good at chemical processing. Their introduction to the field of research enables them to work in different fields, notably pharmaceuticals, fast moving consumer goods, textiles, oil, food, supply chains, safety and hazards, polymers, metallurgy, etc. They work in quality control, quality assurance, production and R&D departments. After a bachelor's degree in applied chemistry, you will soon get a management position. The best part is that you have a lot of ways to choose to work or learn more.
Applied chemistry is of great value in commerce, which provides students with more applied chemistry employment opportunities. Applied chemistry begins with market demand and value and attempts to find a fast but not necessarily novel way to meet customer needs, including cost requirements, and to send some products for field trials. Patents are crucial to protecting inventions from imitation. Trade secrets are critical if patents are not available, although in some cases it makes more sense to disclose them as uncensored research to prevent others from blocking your patents. Industrial scientists mainly apply chemistry. Patents and commercial products are good indicators of industrial success.
high polymer chemistry
Common skills gained from this degree
- Collect chemical data
- sophisticated instrumentation and equipment
- Critically analyze chemical information
- Laboratory work and data analysis
- Apply the principles of chemistry to solve problems