MSc in Chemie

The complexity of issues as diverse as climate change, energy storage, a cure for cancer, and antibiotic resistance requires broad chemical knowledge. This program has a strong experimental focus and prepares you for a career working with anything from materials to pharmaceuticals.

As a skilled chemist, you can play a key role in solving the challenges we are facing concerning the environment and the health of an aging population. This new master’s program has a modern, molecule-centered approach that transcends the boundaries between traditional branches of chemistry.

Learn molecular structures in detail

Throughout the program, our experienced teachers, who are all active researchers, will explain how molecular properties are understood, designed, and used. You will study the details of the chemical bond, followed by synthesis and analysis of molecules and materials. Courses in nanotechnology, medicinal chemistry, and materials science will help you understand how chemistry is central to a wide range of applications, why molecules with certain structures are suited for particular tasks, and how molecular properties can be enhanced to suit the application even better.

Plenty of lab time

You will spend a lot of time in our labs getting hands-on experience of chemistry and applying theories covered in the lectures. Linköping University (LiU) has strong research in chemistry and related subjects, including computational studies of catalysis and surface chemistry, as well as the synthesis of hard and soft materials. We are also developing synthetic molecules for pharmaceutical and diagnostic purposes, and methods for forensic investigations. For your thesis, you can opt to work either with a research group at LiU or with the industry.

Webinar for prospective students

Do you want to learn more about the Chemistry program? Watch this webinar with Professor Henrik Pedersen from January 2019.

Syllabus

Purpose

The Master’s program in Chemistry aims to provide the students with the knowledge, skills, and attitudes required for a professional in the field or for further postgraduate studies. The program meets both national and international needs from universities, industry, and society in general. The training intends to provide in-depth knowledge of chemical synthesis, chemical analysis, and materials chemistry.

Students graduating from the Master's program in Chemistry shall:

• be well prepared for advanced scientific communication with different target groups
• be able to contribute to the sustainable development of society
• be well prepared for both further postgraduate studies and for the national and international labour market.

Aim

Disciplinary knowledge and reasoning

Graduates from the Master’s program in Chemistry demonstrate knowledge and understanding in the chemistry field, including a broad knowledge of the area and considerable in-depth knowledge in certain parts of the area. The graduates are also acquainted with current research in the field.

The program builds upon a Bachelor's education in Chemistry, Chemical Biology, Chemical Engineering, or equivalent, where fundamental knowledge in the area has been acquired.

The Master's program in Chemistry aims to provide in-depth knowledge of chemistry. A graduated student can:

• analyze data and evaluate results from experiments and observational studies of chemical systems and critically evaluate statements about chemical relations.
• apply mathematical and physical models to chemical systems of high complexity, in order to describe and understand them.
• apply concepts and utilize techniques from other sciences to interpret chemical phenomena.

More specifically, a student who graduated from the program can:

• use knowledge of the relationship between the structure and properties of molecules to select suitable synthesis and analysis methods for a given molecule.
• select a suitable molecular structure for a given area of application.
• describe areas of application for a given molecular structure.
• work in a sustainable way through so-called green chemistry.

The Master's program in Chemistry is conducted in close collaboration with strong research environments, which gives the students insight into current research and development within the areas of chemical synthesis, chemical analysis, and materials chemistry. During the Master's thesis work, the student can work for a full year with a research group, a company, or a public authority, getting very well acquainted with research findings within one of the areas. The graduate student is also able to design a scientific study and is skilled in critically reading relevant research literature.

Personal and professional skills and attributes

Students who graduated from the Master's program in Chemistry have achieved the individual and professional skills and attitudes required to be able to critically and systematically integrate knowledge and to analyze and evaluate complex issues even with limited information. The graduates can also take responsibility at work or during post-graduate studies concerning work ethics, reliability, and respect for the expertise of other professionals. Students from the program can make relevant judgments regarding scientific, social, and ethical aspects.

Interpersonal skills: Teamwork and communication

Students having graduated from the Master's program in Chemistry can collaborate with other people. This requires the ability to actively participate in a project with designated roles, tasks, and responsibilities. The graduates can also initiate, plan, lead, and evaluate larger projects. Students who graduated from the program are skilled in written and oral communication. The students can present information, problems, and solutions in a structured way with relevant techniques, in English or in their native language, to different target groups.

Planning, execution, and presentation of research or development projects with respect to scientific and societal needs and requirements

Students who graduated from the Master's program in Chemistry shall have knowledge about the natural scientist and the role of natural science in society. The graduates also understand the social and economic conditions in the field and in the related research area. They can initiate, conduct, and present advanced development projects with established methods.

Research

• Computational chemistry studies of the surface chemical reactions involved in thin film deposition and catalysis. By using supercomputers, chemists can obtain atom-level understanding which is crucial for the development of most chemical applications.
• Synthesis of novel precursor molecules for group 13 metals and chemical vapor deposition and atomic layer deposition of group 13 nitride thin films for electronic devices for next-generation telecom systems. This project is run in close collaboration with the Division of Semiconductor Materials. More information is under ”Pedersen Group” below.
• Synthesis and characterization of designer drug metabolites. This is a great challenge for many forensic science researchers since there are no commercially available reference samples for new drugs and their metabolites on the market. This project is a collaboration with The National Board of Forensic Medicine (Rättsmedicinalverket, RMV). See ”New online drugs” below for further information.
• Synthesis of functionalized oligothiophene derivatives with specific optical and electronic properties. Conjugated polymers suitable for a wide range of applications, such as solar cells, displays, and biosensors, are created by combining features of polymers and the electro-optical properties of conjugated molecules.

Pedersen Group

The Henrik Pedersen research group at Linköping University is working on chemical vapor deposition (CVD) with the aim to develop better CVD routes to, primarily, electronic materials.

Electronic Plants

Electronic plants (E-Plants) is an organic bioelectronics platform that allows electronic interface with living plants.

Laboratory of molecular materials

We are a multidisciplinary team with a passion for science. Our research is focused on the design and development of molecules, soft materials, and hybrid nanoscale components and devices for a wide range of biomedical applications.

Photovoltaics and Thermoelectricity

LiU carries out world-leading research into printed organic solar cells. These cells open completely new possibilities for husbanding the energy of the sun.

Organic nanocrystals

We develop new nanoscale materials and devices for biomedical applications and catalysis. The common theme is using simple organic crystalline building blocks.

Ångströmhuset - electron microscopy

Ångströmhuset is a purpose-built environment, enabling continuous and noise-free operation of one of the world’s sharpest (scanning) transmission electron microscopes.

_Are you curious about what it is like to study at LiU? Join us for a chat about what it is like to live and study on our campuses in Sweden. We offer free webinars and recordings for both prospective and admitted degree students throughout the year. Visit our _ _Meet us online _ _page. _

About Linköping University

Linköping University will never rest on its laurels.

In close collaboration with the business world and society, Linköping University (LiU) conducts world-leading, boundary-crossing research in fields including materials science, IT and hearing. In the same spirit, the university offers many innovative educational programs, many of them with a clear vocational focus, leading to qualification as, for example, doctors, teachers, economists, and engineers.

The university has 32,000 students and 4,000 employees on four campuses. Together we seek answers to the complex questions facing us today. Our students are among the most desirable in the labor market and international rankings consistently place LiU as a leading global university.

LiU achieved university status in 1975 and innovation is our only tradition.

History of Linköping University

In 1975 Sweden’s sixth university was founded in Linköping. Since then Linköping University (LiU) has grown considerably, expanding to Norrköping and Stockholm.

Linköping has been an important center of learning since medieval times when Linköping Cathedral offered a school with extensive international contacts and its own student hall in Paris. In 1627 the Cathedral School became the third upper secondary school in Sweden and in 1843 a college for elementary school teachers began operations. In Norrköping, the Fröbel Institute – Sweden’s first college for training pre-school teachers – was founded in 1902.

From university college to university

What would later become Linköping University began to take shape in the mid-1960s. Higher education in Sweden was expanding and in 1965 the Swedish Parliament decided to establish a branch of Stockholm University, together with a university college of engineering and medicine, in Linköping.

In the autumn of 1967, the branch of Stockholm University moved into premises in central Linköping. There the first students could take courses in the humanities, social sciences, and natural sciences. Two years later the units for engineering and medicine got underway.

In 1970 education and research started moving into the recently built Campus Valla, a short distance from the town center. Buildings A and B were the first to be completed. The same year the various parts were merged to form Linköping University College, including faculties of engineering, medicine and arts, and sciences.

The new university college was the first in Sweden to offer study programs in Industrial Engineering and Management and Applied Physics and Electrical Engineering, both starting in 1969. A few years later, in 1975, Linköping University launched Sweden’s first Computer Science and Engineering program.

1975 was also the year when Linköping University College became Linköping University, the sixth university in Sweden. In line with the 1977 reform of the Swedish higher education system, teacher education was also transferred to Linköping University.

Interdisciplinary research and problem-based learning

Linköping University has always worked with innovation in education and research. In 1980 the newly formed Department of Thematic Studies adopted an approach that was new in Sweden. Research was organized in interdisciplinary themes, such as Technology and Social Change or Water and Environmental Studies. Scientists worked across boundaries to solve complex problems. LiU was also first in Sweden to introduce graduate research schools for different themes. The model later spread to other parts of the university and became a national success.

The new Faculty of Health Sciences (Hälsouniversitetet), formed in 1986, combined governmentally and regionally funded education. It introduced a radically changed methodology, being the first in Sweden to use problem-based learning, PBL. Later, LiU became the first university in the world to allow students from different health sciences programs to treat actual patients on a student-managed training ward.

Expansion to Norrköping – and Stockholm

A significant milestone in the history of the University was the opening of Campus Norrköping in 1997. Some programs had previously operated from Norrköping, but the number of students now grew drastically in line with government efforts to expand higher education. Historical factories in the former industrial district were again filled with life, as they were filled with classrooms, laboratories, cafés, a library and of course students.

Linköping University also expanded to Stockholm when the reputable Carl Malmsten School of Furniture sought a collaborative partner from the academic sector. The Malmsten furniture design and handicraft programs became part of LiU in 2000. After almost 60 years at Södermalm in central Stockholm, Malmstens moved to new premises on the island of Lidingö in the autumn of 2009. LiU got its fourth campus.

Buro Millennial / Pexels

LiU in figures

Some important figures for Linköping University.

Education

• 32,000 students (full-time equivalents 17,907)
• 21,400 on Campus Valla
• 5,500 on Campus Norrköping
• 3,900 on University Hospital Campus (US)
• 2,100 distance students and students in other locations, including Campus Lidingö

(Some students take courses on more than one campus.)

• 120 study programs, of which 27 are international programs in English
• 550 single-subject courses
• Exchange agreements with 400 universities in 50 countries
• 2,400 international students
• 2,200 first cycle degrees
• 2,700 second-cycle degrees

Research and scientific training

• 300 professors
• 1,200 PhD students
• 40 licentiate degrees
• 140 doctoral degrees

Staff

• 4,000 employees (full-time equivalents 3,156)