Molecular virology - - Lund University   Areas

https://www.virology.lu.se/molecular-virology/projects - 2025-08-25

a Principal Investigator

https://www.virology.lu.se/clinical-virology/patrik-medstrand - 2025-08-25

PATRIK MEDSTRAND Patrik Medstrand_LUCRIS Patrik Medstrand_PubMed

https://www.virology.lu.se/clinical-virology/publications - 2025-08-25

a

https://www.virology.lu.se/clinical-virology/collaborators - 2025-08-25

Patrik Medstrand, Professor E-post: patrik [dot] medstrand [at] med [dot] lu [dot] se (patrik[dot]medstrand[at]med[dot]lu[dot]se) Professor vid Klinisk virologi, Malmö Telefon: +46 46 222 14 89 Mobil: +46 70 841 57 97 Rumsnummer: BMC B1354b Professor vid EpiHealth: Epidemiology for Health Chef vid Klinisk virologi, Malmö Forskargruppschef vid Klinisk virologi, Malmö

https://www.virology.lu.se/clinical-virology/contact - 2025-08-25

HIV-1 and HIV-2 host interactions - - Lund University Karlsson I, Tingstedt JL, Sahin GÖ, Hansen M, Szojka Z, Buggert M, Biague A, Da Silva Z, Månsson F, Esbjörnsson J, Norrgren H, Medstrand P, Fomsgaard A*, and Jansson M*; Sweden-Guinea-Bissau Cohort Research Group. Cross-Reactive Antibodies With the Capacity to Mediate HIV-1 Envelope Glycoprotein-Targeted ADCC Identified in HIV-2-Infected Indivi

https://www.virology.lu.se/hiv-host-interactions/marianne-jansson - 2025-08-25

Marianne Jansson Marianne Jansson_LUCRISMarianne Jansson_PubMed  

https://www.virology.lu.se/hiv-host-interactions/publications - 2025-08-25

Welcome to Advanced Chip Technologies (ACT) – a Vinnova Competence Centre The ACT-consortium gathers organizations and companies, all passionate about development of advanced chips, to meet current and future needs by industry and society. The consortiumThe consortium has 17 committed partners ranging from start-ups to multinational companies all passionate about the continued development of our j

https://www.advancedchiptechnologies.lu.se/start - 2025-08-25

In work package 1 we will develop materials, processes and devices to be used in WP2 and WP3. The topics include:Material synthesis with emphasis on III-V nanowire epitaxial growth both using metal organic vapor phase epitaxy and aerotaxy.Scaling of nanowire growth substrates from individual dies to 100 mm Si wafersNanowire surface passivation for photonic devices and gate-stack optimization for t

https://www.advancedchiptechnologies.lu.se/wp1-devices-3d-integration - 2025-08-25

In work package 2 we will explore the integration of photonic device elements with silicon for applications in communication, sensing and power generation. The topics include:Development of epitaxy, material characterization and single pixel elements for infrared detector arraysDesign and fabrication of CMOS-based read-out circuitry for focal plane arraysUsing Nanowire-based photovoltaics for on-c

https://www.advancedchiptechnologies.lu.se/wp2-photonic-integration - 2025-08-25

In work package 3 we explore the use of 3D integration technologies to enable innovative merging of control electronics and power devices and make an early evaluation of system benefits and technology limitations. The topics include:Characterization and modelling of DC and RF performance of III-V nanowire transistorsFabrication of amplifiers, switches, or detector circuits operating at D-band freq

https://www.advancedchiptechnologies.lu.se/wp3-circuit-implementation-smart-energy-and-rf - 2025-08-25

Avdelningar Denna institution består av avdelningarna biomedicinsk teknik (BME), industriell elektroteknik och automation (IEA) samt teknisk geologi (TG). BME Avdelningen för biomedicinsk teknik IEA Avdelningen för industriell elektroteknik och automation TG Avdelningen för teknisk geologi

https://www.bmt.lth.se/start - 2025-08-25

Biomedicinsk teknik EkonomiadministratörUlrika WesterdahlTel: 046 - 222 75 26PrefektIngrid SvenssonTel: 046-2227525PostadressLunds UniversitetBiomedicinsk teknikBox 118221 00 LundBesöksadressE-huset, LTHOle Römers väg 3223 63 Lund Industriell elektroteknik och automation EkonomiadministratörUlrika WesterdahlTel: 046-222 92 89Biträdande PrefektUlf JeppssonTel: 046-222 92 87PostadressLunds Universit

https://www.bmt.lth.se/kontakt - 2025-08-25

Mentor programme

https://www.wcmm.lu.se/career-support - 2025-08-25

Welcome to the Division of Synchrotron Radiation Research The Division of Synchrotron Radiation Physics has about 60 employees and covers a wide range of research topics that are interlinked with each other as well as to research groups in Lund, Sweden, and internationally. We perform experimental studies of physical, chemical, structural, and dynamical properties of materials, especially at surfa

https://www.sljus.lu.se/start - 2025-08-25

Do your project at the Division of Synchrotron Radiation Research! Bachelor's and Master's projects are available in all research fields of the Division. Please feel free to contact the corresponding project leader or any other member of the group for more information. A large part of our research is performed at the MAX IV Laboratory. In addition, we are using several international synchrotron fa

https://www.sljus.lu.se/education/bsc-msc-projects - 2025-08-25

Safety requires everyone's responsibility and awareness. Safety work at the Division of Synchrotron Radiation Research is regulated at three levels:General RegulationsThe "General Regulations" are relevant for everyone working at the division. Specific Safety RegulationsThe "Specific Safety Regulations" are relevant for everyone working in the laboratories of the division, i.e. the Scanning Probe

https://www.sljus.lu.se/safety-information-employees - 2025-08-25

Our research concerns the intersection of nanoscience and X-ray science. We use X-rays to investigate nanostructured devices, and we develop nanostructures as X-ray detectors. We have a strong collaboration with the Nanomax beamline at MAX IV, and we also visit other synchrotrons for experiments. Most of the projects also involve colleagues in NanoLund, and we are frequent users of the Lund Nano L

https://www.sljus.lu.se/jesper-wallentin-0 - 2025-08-25

CsPbBr3 metal halide perovskite nanowire X-ray detectors. A) Cross-sectional SEM and B) X-ray image of test pattern with 2 micron lines [Zhang 2022]. C) 3D X-ray microscopy of grains [Dierks 2022]. Metal halide perovskites are most famous for their rapid development in solar cells, but they are also promising materials for X-ray scintillation detectors. We are synthesizing CsPbBr3 nanowire arrays

https://www.sljus.lu.se/growth-metal-halide-perovskite-nanowires-x-ray-detection-applications - 2025-08-25

Freestanding CsPbBr3 nanowires. Left: Cross-sectional SEM of as-grown nanowires. Middle: Cross-sectional optical microscopy (not false colored) of blue-green CsPbCl1.1Br1.9-CsPbBr3 heterostructured nanowires [Zhang 2022]. Single nanowire transistor [Lamers 2022]. We have discovered a method to grow free-standing vertically aligned CsPbBr3 metal halide perovskites [Zhang 2022]. Part of the nanowire

https://www.sljus.lu.se/free-standing-metal-halide-perovskite-nanowires-devices-and-heterostructures - 2025-08-25