Forschungseinrichtungen - Laser Technology

Rutherfordstraße 2
12489 Berlin
+49 30 67055-509

The main expertise of this Institute is the development of intelligent sensors and data processing software solutions for commercial, industrial and scientific purposes.

Some of the Institute key products and applications are shown in the figure above, these application are used today for the latest airborne and satellite technology. The knowledge and spin-offs gained from such products have been passed on to commercial and industrial users, and are now used for technology transfer projects for commercial and industrial purposes.

The institute is also dedicated to scientific and research activities, for this education and technology transfer plays a major role, the institute is currently involved with partnerships with global universities and fellow institutes in conducting international summer schools for students, and encouraging and promoting student transfer and scholarships for PhD students.

The Institute also defines and develops geometrically and/or spectral high-resolution sensor systems in the visible and infrared area of the electromagnetic radiation as well as the thematic real time processing of picture data for information relevant for users for strategically purposes. The operational application for such sensors requires an extensive autonomy which allows the independent operating of the system which is used in the development and building of small satellites.

Magdeburger Straße 50
14770 Brandenburg
03381 355 101
Gustav-Kirchhoff-Str. 4
12489 Berlin
+49 (0)30 / 6932-2602

The Ferdinand-Braun-Institut, Leibniz-Institut fuer Hoechstfrequenztechnik (FBH) researches electronic and optical components, modules and systems based on compound semiconductors. These devices are key enablers that address the needs of today’s society in fields like communications, energy, health and mobility. Specifically, FBH develops light sources from the visible to the ultra-violet spectral range: high-power diode lasers with excellent beam quality, UV light sources and hybrid laser systems. Applications range from medical technology, high-precision metrology and sensors to optical communications in space. In the field of microwaves, FBH develops high-efficiency multi-functional power amplifiers and millimeter wave frontends targeting energy-efficient mobile communications as well as car safety systems. In addition, compact atmospheric microwave plasma sources are devellopped for medical applications or surface coating.

The FBH is a competence center for III-V compound semiconductors and has a strong international reputation. FBH competence covers the full range of capabilities, from design to fabrication to device characterization.

In close cooperation with industry, its research results lead to cutting-edge products. The institute also successfully turns innovative product ideas into spin-off companies. Thus, working in strategic partnerships with industry, FBH assures Germany’s technological excellence in microwave and optoelectronic research.

The Ferdinand-Braun-Institut develops high-value products and services for its partners in the research community and industry which are tailored precisely to fit individual needs. The institute offers its international customer base complete solutions and know-how as a one-stop agency – from design to ready-to-ship modules.

Research topics & competencies:

  • Diode lasers
  • Gallium nitride optoelectronics
  • Microwave components & systems
  • Gallium nitride electronics
  • Materials and process technology
Geiselbergstr. 69
14476 Potsdam
+49 (0)331 / 568-10


Progress in optical technologies is considerably based on novel functional materials with special optical, electrical and photosensitive properties. Functional polymers and polymer-based functional elements for optical technologies are focal points of development at Fraunhofer IAP. These activities can be summarized under the headline “Light as a tool – tools for light”. Research projects combine on an interdisciplinary bases polymer synthesis, processing and the fabrication of optical functional elements and devices. Key aspects in research complexes cover: materials for all-optical structuring used for optical components, security labels and structured biofunctional surfaces; holographic materials for fabrication of diffractive optical elements; liquid crystals and polymers processable by photo-orientation for the fabrication of anisotropic functional layers in display technologies, sensor systems (e.g. retarder, polarizer, anisotropic emitter); semi-conducting and electro-luminescent polymers and nano-composites applicable for organic light-emitting diodes (OLED), organic field-effect transistors (OFET) and organic photovoltaic, development of optical probes for life sciences, optical oxygen measurement in small volumes and development of polymer lasers. Additional subjects of current research cover for example fluorescent materials for special light converter systems, organic lasing and chromogenic materials for smart windows and display application, materials for functionalization of surfaces and optical functional layers in sensor systems as well as organic-inorganic hybrid materials and nano-composites for various applications in optics and photonics.

Tailored on customer needs Fraunhofer IAP offers a complete range of research and development services from high-purity synthesis and analysis of materials, processing and device technologies up to prototype testing based on interdisciplinary experiences of chemists, physicists and engineers and state-of-the-art equipment, such as clean-room facility, as well. Working with partners from optical and chemical industries Fraunhofer IAP acts at the interface between material science and optics and as mediator between chemical and optical industry.

Scientists of Fraunhofer IAP give lectures at Potsdam University, e.g. on polymer chemistry, polymer physics, photochemistry, photophysics and supramolecular chemistry, and take care of PhD students.

Gustav-Meyer-Allee 25
13355 Berlin
+49 (30) 46403-219

Fraunhofer IZM specializes in industry-oriented applied research. Fraunhofer IZM develops assembly and interconnection technology, also known as electronic/photonic packaging. Almost invisible and undervalued by many, electronic packaging is at the heart of every electronic application. Our technologies connect the individual components, protect components and devices from vibration and moisture, and reliably dissipate heat. Fraunhofer IZM thus ensures that electronic devices continue to function reliably in even the harshest conditions – we even integrate electronics into golf balls. Modern packaging technologies make developing smaller and smaller products possible. We process ICs thinner than a sheet of paper.

The business area Photonics combines Fraunhofer IZM’s skills and know-how to tackle challenges in telecommunication, data communication, light generation, materials processing and optical sensors.
We pursue different goals in each of these areas. In communication, broadband capacity, power efficiency, high, heterogeneous packaging density are the main focus, while in lighting, we aim to improve high power density, thermal management, multifunctional integration, wavelength conversion and beam guiding. In sensor technology, application-specific heterointegration of excitation source, sensor and analysis electronics take center-stage. However, three goals are pursued across all these areas: volume adjusted manufacturing technology, cost-efficiency and high yield.

Wilhelminenhofstraße 75A
12459 Berlin
+49 (0)30 / 5019-3298

The HTW offers an impressive range of study programmes in five different departments spanning fields from engineering, computer science and economics, to culture and design. Traditional applied sciences like mechanical engineering, automotive engineering and business administration go hand-in-hand with more contemporary and innovative studies such as Information Technology/Networked Systems, Life Science Engineering, Environmental Engineering/Regenerative Energies and Microsystems Technology.

Let us consider the closer microsystems technology. Today this item is penetrating nearly every area of everyday life. Automotive technology, multimedia, medical engineering, bioengineering and genetic engineering, environmental protection – highly complex microsystems can be found everywhere. This study programme at the HTW Berlin runs for seven terms during one of which company placement is done. Apart from imparting students with solid skills in the core areas of engineering, it also provides access to modern simulation and CAD technology, computer science, electronics, sensors and microtechnology.

The HTW Berlin is regularly distinguished for the high quality of its study programmes. Students who wish to spend a part of their studies abroad will find that the HTW offers ideal conditions: it cultivates ties with over 100 other universities worldwide, thus maintaining strong bonds with collaborative partners.

The HTW encourages research and development projects on a wide range spectrum. Within Berlin, the Federal Republic of Germany and Europe, the HTW works together with small and medium-sized businesses, unions, administrations, associations, research and training institutions, and other individuals to fulfill these objectives and goals.

Das Institut für interdisziplinäre Technologien Berlin gGmbH (IITB) wurde im Jahre 2017 als gemeinnützige private Forschungseinrichtung zur Durchführung von Technologieprojekten mit interdisziplinärem Charakter gegründet. Die Kernkompetenzen liegen auf den Gebieten Photonik, Elektronik und Messtechnik.Das IITB ist vor allem Partner von kleinen und mittelständischen Unternehmen. Zu diesem Zweck bietet das IITB komplette Lösungen an und führt Forschungsvorhaben aus.Mit dem Fokus in der Region ist das Institut für interdisziplinäre Technologien Berlin aber auch überregional und international tätig. Arbeitsgebiete Unser Spezialgebiet sind Laser-F&E und Laseranwendungen sowie Komponentenentwicklung. Darüber hinaus verfügen wir über umfangreiche Erfahrung mit Sensoren, optischer Simulation, Elektronik, Plasmatechnik und Spektroskopie.

Leistungsangebot Forschung, Entwicklung, Projekt- und IP-Management, Studien und Beratungsleistungen, Technologie-Transfer Beispiele für unsere qualifizierten Beratungsleistungen sind

•    Produktentwicklung und Produktdesign
•    Bewertung und Vergleich von Technologien, Konzepten und Produkten
•    Erstellung oder Bewertung von Anträgen für Förderprojekte und Patentanmeldungen

Wir arbeiten sowohl in unseren eigenen Räumlichkeiten als auch in den Räumlichkeiten unserer Kunden. Durch die Zusammenarbeit mit Forschungsinstituten haben wir Zugang zu einer breiten Palette weiterer spezialisierter Instrumente und Geräte.

Fabeckstr. 60-62
14195 Berlin
+49 (0)30 / 844 923 25

LMTB ... from ideas to new optical methods in medical technology and micromachining

LMTB is a nonprofit institute for research, development and training in biomedical optics and applied laser technology. Years of experience and expertise in the areas of analytical and imaging diagnostics, minimally invasive therapy and laser precision machining, move boundaries and enable new solutions. The Laser and Medical Technology GmbH, Berlin (LMTB) is a nonprofit research and development facility for Biomedical Optics and Applied Laser Technology. The main objective is technology transfer, i.e. to develop new concepts in those two areas and to transfer them into industry and into medical practice.

Many ideas at LMTB are due to the proximity to the University Hospital Charité, the three major universities and other non-university research institutions in Berlin. There are several leading medical technology manufacturers among the shareholders of LMTB. A science-driven team of approximately 30 employees is active in a variety of mostly publicly funded research collaborations with academic and industrial partners and in direct contact with the industry.

At the same time, LMTB is a partner in providing customized solutions in the context of commercial R&D projects. It organizes courses and workshops on medical lasers and industrial laser applications. LMTB offers expert advice and the conduction of studies on approval and patent related issues to medical device manufacturers. Molecular methods have become increasingly important for LTMB in recent years compared to traditional laser therapies and diagnostic methods.

For the blood products and transfusion market, LMTB has developed a number of sensors for hemolysis and for gathering several other blood parameters, which are now ready for integration into system solutions of respective companies. Other appliers of this technology are blood donation centers, which are provided with a non-invasive quality control. The main expertise of LMTB is its comprehension of interaction processes between light and irradiated matter. In biomedicine, light propagation in strongly scattering media is especially important, the so-called tissue optics. This is an essential basis for the development of new diagnostic and laser-therapeutic procedures, and corresponding devices. The main focus in the field of material processing is precision machining of transparent and brittle materials and the development of laser-optical components. 3D processing stations and short-pulse laser systems are available for the development of innovative methods for glass processing and photovoltaics. A new trepanning optics was developed by the applied laser technology group of LMTB, which combines a high operating speed with a substantially improved quality of laser drilling and laser cutting.

Brief history of LMTB
Today's LMTB is a result of the merger of two institutions in 1995, that had significantly promoted the use of lasers. One was the Laser Medical Center (LMZ), founded in 1985, the first of such institutions in Germany. The other merger partner was founded in 1987 in Berlin, the Solid-state Laser-Institute (FLI), which gave its sector essential stimuli for many years. Today, LMTB focuses on the R&D transfer using innovative laser and light emitting diodes in material processing and medical diagnostics and therapy.

Max-Born-Strasse 2A
12489 Berlin
+49 (0)30 / 63921402

The Max-Born-Institute for Nonlinear Optics and Short Pulse Spectroscopy (MBI) conducts basic research in the field of nonlinear optics and ultrafast dynamics of lightmatter interactions. It pursues applications which emerge from this research. Ultrashort pulses in a wide spectral range from the far-infrared to hard x-rays, nonlinear phenomena and high intensities are key aspects of this mission for which lasers are both a topic and a tool of research.

The MBI is involved in a large variety of cooperative research projects with universities, research institutions and industrial partners. It offers its facilities and scientific know-how to external researchers within the framework of a guest program.


Abbestraße 2-12
10587 Berlin
+49 030-3481-7238
Straße des 17. Juni 136
10623 Berlin
+49 (0)30 / 314 21699

The group's activities are focused on the research of light-matter-interaction and its applications. The research, development and education are carried out in an international surrounding of science and industry. Different materials are investigated for their linear and nonlinear properties and transferred into possible applications. Current topics are:

Nonlinear Optics and Optical Spectroscopy

  • Colloidal nanoparticles and quantum dots in life sciences, labeling, as a biomarker, in photovoltaics and as single-photon sources
  • Semiconductor structures of low dimensionality and their optical properties
  • Nanoscaled Quantum Systems as potential ultrafast amplifiers and switches
  • Hybrid semiconductor / metal nanostructures for fundamental principles and applications in active and passive nano-plasmonics

Laser Development and Laser Material Processing

  • Development of powerful diode and lamp pumped solid-state lasers in the near infrared spectral range from 1 to 2 µm, especially in the eye-safe region from 1.5 to 1.7 µm for material processing, medical and remote sensing applications
  • Optimization of neodymium and erbium based laser sources with respect to their spectral and spatial characteristics
  • Spectroscopic investigation of crystalline materials in terms of stimulated Raman scattering and further second and third order nonlinear effects
  • Development of compact Raman lasers for efficient conversion of the emission wavelength of existing laser sources

Optical Thin Film Coatings

  • Calculation, preparation and characterization of dielectric and metal thin film systems for reflective and anti-reflective optical surfaces and for the production of spectral filters, beam splitters and functionalized surfaces
  • Antireflection coatings of the terminal surfaces of glass fibers used for the construction of fiber lasers and for transmitting high laser power, e.g. used in material processing and medical therapeutic applications
  • Manufacture of hybrid thin film structures on the end-faces of optical fibers for the development of optical fiber sensors, fiber coupled modulators for data communication, and other innovative applications


  • Development and characterisation of integrated electro-optic components  fabricated in a  BiCMOS production process on Silicon-On-Insulator (SOI) wafers. This includes the development of optical couplers, splitters, spectral filters and resonators as well as active electro-optic structures e.g. modulators, Raman amplifiers and delay generators
  • In addition, complex photonic integrated circuits are designed for transceiver applications in optical data communication
  • The worldwide smallest high speed modulator in SOI has been demonstrated at the Institute of Optics an Atomic Physics
Hochschulring 1
15745 Wildau
+49 (0)3375-508119

Technical University Wildau – A Competent Partner for Commercial Businesses and Scientific Institutions

The opening of the Technical University Wildau in 1991 has resulted in academic teaching as well as scientific research and development becoming firmly established and highly esteemed in the region to the south-east of Berlin. Not only businesses and scientific institutions, but also public administrative bodies all profit directly from this development by being able to recruit Wildau graduates directly as young specialists and managers. They also benefit from R&D cooperation and projects, networks for knowledge and technology transfer in addition to further-training programmes which can be tailor-made for companies and a wide range of institutions.

Documented quality control and direct practical relevance are the outstanding hallmarks of 28 degree courses on offer, ranging from engineering, business and administration to legal studies, available both on campus and via distance learning. With more than 4,200 students Wildau is the biggest university in the regional state of Brandenburg. Changing from diploma to bachelor and master programmes has considerably strengthened the academic character of the Technical University Wildau.

Photonic, Laser and Plasma Technologies

Professor Sigurd Schrader’s working group is active in the areas of photonics, optical technologies, laser and plasma technologies, both in teaching and applied research. This group is involved in the following fields:

  • Material syntheses and experiments
  • Producing optoelectronic elements and components
  • Characterizing optoelectronic elements and components
  • Process characterization and optimization

This research group cooperates closely with industrial partners, mainly small and medium-sized companies situated in the Berlin-Brandenburg capital region. Additionally, as a participant in national and international networks it has considerable contact with research institutions and universities. There is also direct cooperation on a contractual basis with the IHP Leibniz Institute for Innovative Microelectronics Ltd in Frankfurt an der Oder, which had led to their joint research and training centre (Joint Lab). The main focus of this activity is to develop concepts for innovative silicon based elements and technologies for high-speed electronics and photonics. Among Joint Lab’s activities are experiments aimed at generating graphic layers in order to attain higher limit frequencies up to the terahertz level. This may lead to new applications in sensorics and medical technology.

Microsystems Technology

Microsystems Technology is represented in the teaching and applied research carried out by Professor Andreas Foitzik. Hardware content is predominant in this field and the focus is on biological microsystems technology for life-science products and applications. A dust-free room (for structures as small as a nanometre) and a plastics laboratory (for the quick implementation of prototypes) are available. The wide range of research areas includes:

  • Elements for biochips and biosensors
  • Reactors in macro and micro fields (including microfluidics)
  • Processing surface structures
  • Constructing and joining technology (joining smaller elements to a larger system)
  • Integrating circuits (signal connection between the micro and macro world)
  • Measuring and regulating the overall system
  • Microstructuring
  • Micro injection moulding of small plastic elements
  • Cutting plastic or metal micro elements
  • Mechanical and optical material examination

The group’s expertise and infrastructure are available for applications beyond biological microsystems technology.


Karl-Liebknecht-Str. 24/25
14476 Potsdam
0331 977 5222

Die    Physikalische    Chemie    der    Universität Potsdam (UPPC,   ist   Teil   des   Instituts für Chemie   und   hat   ihren   Sitz   am neuen naturwissenschaftlichen Campus in   Potsdam-Golm,   der   Teil   des   Golmer Wissenschaftsparks ist. Unter Leitung von Prof. Dr. Hans-Gerd Löh-mannsröben, apl. Prof. Dr. Michael U. Kumke und JProf. Dr. Ilko Bald führt UPPC die Ausbildung in den naturwiss. Bachelor- und Masterstudiengängen in der Teildisziplin „Physikalische Chemie“ durch und ist stark in der Doktorandenausbildung engagiert. Sehr erfolgreich ist die Beteiligung an der Graduiertenschule SALSA, 2012 Siegerin im Exzellenzwettbewerb des Bundes und der Länder.

Grundlagen- und Anwendungsforschung in Photochemie und Photophysik, Laserspektroskopie und optischer Sensorik sind die Kernkompetenzen von UPPC. Die Untersuchung von elementaren  Gasphasenreaktionen mit laserbasierter Ionenmobilitäts (IM)-Spektrometrie als ein spannendes Beispiel für die Erforschung von fundamentalen physiko-chemischen Phänomenen und die Entwicklung optischer Detektionsschemata für die point-of-care Diagnostik von Biomarkern für Lungenkrebs- und Alzheimer-Erkrankun¬gen verdeutlichen das breite Spektrum der Aktivitäten und Expertisen.
Die Berufung von JProf. Dr. Ilko Bald (Jan. 2013) ist eine wichtige wissenschaftliche und personelle Verstärkung (s. Beispiele für faser-basierte optische Methoden, in denen UPPC eine führende Rolle innehat, sind die Photonendichtewellen (PDW)-Spektroskopie (Bunsen-Kirchhoff-Preis für Dr. Oliver Reich 2014, spin-off-Firma PDW Analytics) sowie die O2- und pH-Sensorik auf mikroskopischer und zellulärer Ebene (spin-off-Firma Colibri Photo¬nics). Die hervorragende F&E-Infrastruktur verbun-den mit einer erstklassigen instrumentellen Ausstattung, beides noch deutlich gesteigert durch den Bezug des Drittmittelzentrums (Haus 29) im Herbst 2013, sowie die ausgeprägte interdisziplinäre Anlage der Forschungsthemen zeichnen UPPC als exzellenten Forschungspartner aus. Derzeit sind ca. 50 Mitarbeiter/innen an 15 F&E-Vor-haben mit regionalen, nationalen und internationalen Forschungs- und Industriepartnern beteiligt. Gemeinsam mit dem Leibniz-Institut für Astrophysik Potsdam (AIP) wird UPPC das Zentrum für Innovationskompetenz inno-FSPEC Potsdam, gerade (August 2016) mit der weiteren BMBF-Förderung 2016 – 2020 ausgezeichnet, zu einem nationalen Exzellenzzentrum für faseroptische Spektroskopie und Sensorik entwickeln.

F&E-Programme und Projekte von UPPC (Auswahl, Kurztitel, Stichpunkte i. Klammern)

(I) „Zentrum für Innovationskompetenz inno-FSPEC Potsdam. Innovative faseroptische Spektroskopie und Sensorik“, Sieger in BMBF-Wettbewerben 2008 und 2015 (faserbasierte chemische Sensorik und optische Vielkanalspektroskopie, Vielfachstreuung, Photonendichtewellen, Angewandte Analytische Photonik, seit 2009).

(II) „Geochemische Radionuklidrückhaltung an Zementalterationsphasen (GRaZ)“, BMWi-Verbundvorhaben (molekulares Prozessverständnis, Wechselwirkungen von Lanthanoiden mit Komponenten homogener und heterogener salinarer Systeme, 2015 – 2018).

(III) Nachwuchsgruppe „Angewandte Laser-sensorik in komplexen Biosystemen (ALS ComBi)“, BMBF, Sieger im Wettbewerb Inno-Profile-Transfer 2012 (super resolution Spek-troskopie, Einzelmolekül- & Einzelzell-Detek-tion, photonische Kristallfasern, Atomkraft-Mikroskopie, Optogenetik, 2012 – 2017).

(IV) „School of Analytical Sciences Adlershof (SALSA)“, Exzellenzgraduiertenschule (Analytik in Bio- und Lebenswissenschaften, Bild¬gebung und Mikroskopie, 2012 – 2019, derzeit 6 Doktoranden bzw. Doktorandinnen).

(V) „Nanopartikel-basierte photonische Vor-Ort-Analytik von Endotoxinen in Biopharmazeutika (EndoProve)“, BMBF-Verbundprojekt (Quantenpunkte als photonische Sonden, Aptamere-Erkennungselemente, 2015 – 2018).

(VI) „Entwicklung innovativer bestandsspezifischer Impfstoffe für Geflügel, innoVAK4¬DART“, BMEL-Verbundprojekt (Charakterisierung von Bakterien durch Fluoreszenzmikroskopie und Durchflußzytometrie, Photo-Inaktivierung, 2014 – 2017).

(VII) „Sensorsystem für Methan-Monitoring b. Schiefergasgewinnung“, BMWi ZIM-Koop.-Projekt, (CH4-Lasersensorik, 2014 – 2016).

(VIII) „Rohstoffscreening mit spektral-opti-schen Verfahren bei der Getreidelagerung (OptiScreen)“, BMEL-Verbundprojekt (Myko-toxin-Detektion, Fluoreszenzspektroskopie an Getreide, IMS-Analytik, 2015 – 2018).

(IX) „Intelligence for Soil. Integrated System for Site-Specific Soil Fertility Management (I4S)”, BMBF-Verbundvorhaben (2015 – 18).

(X) „Photonisch-mikrofluidisches Produktionsverfahren zur ultraschnellen Herstellung maßgeschneiderter monoklonaler Antikörper (Affinity Track)“. StaF-Programm (2017 – 19)

(XI) Industrieprojekte “UV Absorber” und “Lebensmitteldispersionen (2016 – 17)

Instrumentierung von UPPC

Umfassende optisch-spektroskopische Instrumentierung, Spektralbereich 200 nm – 10 µm, hohe spektrale, zeitliche (sub ps) und räumliche (sub µm) Auflösung, Mikroskopie und Bildgebung. Erstklassige instrumentelle Ausstattung mit Investitionsmaßnahmen von ca. 10 Mio. € seit 2001. Derzeit Ausstattung s. Beispiele:

•    Diverse Laserapparaturen mit Absorptions- und Emissionsdetektion
•    Einzelmolekülspektrometer
•    Fluorescence-Imaging-Mikroskop-System
•    PDW-, Lichtstreu- und Photonenkorrelationsspektrometer
•    Ionenmobilitäts- und Massenspektrometer
•    Fasertechnologie und –fusionsspleißgerät
•    Ultrakurzpuls Ti:Sa-Laser mit Nachver-stärkung, Frequenzkonversion und OPA
•    Schreibstand für Faser-Bragg-Gitter
•    Durchflusszytometer
•    Mikro-Thermophorese NanoTemper




Am Neuen Palais 10
14469 Potsdam

The main task of the company is to organize a modern and competitive knowledge and technology transfer at the University of Potsdam as well as in the region, but also on a national and international scale. The goal is the effective addition of excellence in research and teaching by a professional transfer of results from science and research.

The Department of Executive Education currently focuses on:
•    Master degree programs in the areas of Public Administration and Private Management,
•    Certificate courses in Mediation;
•    Scientific training courses;
•    International projects in further education;
•    Projects for refugees and migrants.

The projects of the Department of Applied Research & Development mainly focus on:
•    Basic research;
•    Applied research and development;
•    Contract research;
•    Scientific and technical consulting and services.

Important research areas are especially antibody research, inorganic chemistry research to improve the recycling of valuable precious and rare earth metals, laser development, material research of innovative polymer materials, geoscience research and consulting services.

The Department of UP Transfer Services offers the following services:
•    Conference services mainly for scientific events;
•    Patent licensing for higher education and research institutions of Brandenburg (Project “Brainshell”);
•    UniShop of the University of Potsdam, selling a great variety of merchandising products;
•    Project management and controlling;
•    Administrative services.