Warmest wishes for a happy holiday season and a wonderful new year 2018 from Nanoscience at Lund University Scanning electron micrograph of an array of wurtzite GaP columns. | By: Sebastian Lehmann, Gustav Nylund, Alexander Berg, Magnus Borgström.

https://www.nano.lu.se/sites/nano.lu.se/files/2021-08/Julkort%202017%20digitalt.pdf - 2025-07-29

Postal address Box 118, 221 00 Lund, (internal HS14) Visiting address Professorsgatan 1, Lund Telephone +46 222 33 88, +46 46 222 00 00 (switch board) E-mail info@nano.lu.se Website https://www.nano.lu.se Call for NanoLund project proposals for funding start in 2022 Faculty members and affiliated faculty members of NanoLund are invited to propose projects for financial contributions by NanoLund. I

https://www.nano.lu.se/sites/nano.lu.se/files/2021-09/Call%20for%20NanoLund%20projects%20for%202022.pdf - 2025-07-29

Microsoft Word - NanoLund Distinction lansering final.docx NanoLund Distinction for PhD students The NanoLund Distinction will be awarded to PhD students within the NanoLund environment who have shown particular dedication to research, education and outreach activities, have acquired broad knowledge within nanoscience research and its societal relevance and impact, and have demonstrated research i

https://www.nano.lu.se/sites/nano.lu.se/files/2021-09/NanoLund%20Distinction.pdf - 2025-07-29

NanoLund Annual Meeting 2021 Light for Nano – Nano for Light 12 October 2021, Scandic Star Hotel, Glimmervägen 5, Lund More information: www.nano.lu.se/annualmeeting2021 Program chairs: Ivan Scheblykin and Jesper Wallentin 08:30 – 08:55 Coffee and registration Opening session Chairs: Ivan Scheblykin, Jesper Wallentin 08:55 Welcome and opening by Heiner Linke, Deputy Dean, LTH and Chair of NanoLund

https://www.nano.lu.se/sites/nano.lu.se/files/2021-09/Program%20NanoLund%20Annual%20Meeting%202021.pdf - 2025-07-29

NanoLund_Poster_Denizhan_Ekin_Onder Parallel Capacitance and Boundary current Conclusion Spectral Analysis and the Formation of the E-Field Domains in the THz Quantum Cascade Lasers In the case of extended devices such as Quantum Cascade Lasers, the formation of the electric field domains occur in the negative differential conductivity region [1]. For the device studied here, the relation between

https://www.nano.lu.se/sites/nano.lu.se/files/2021-10/%C3%96nder_Spectral%20Analysis%20and%20the%20Formation%20of%20the%20Electric%20Field%20Domains%20in%20the%20THz%20Quantum%20Cascade%20Lasers.pdf - 2025-07-29

c) d) e) Branch growth in the (110) direction b)a) c) d) e) f) Conventional LEDs consist of heterojunction structures in which the active region (AR) is embedded in-between the layers in a p-n junction. Recent developments have made it possible to decouple the AR from the p-n junction and demonstrate a working LED where electron and holes are injec- ted by carrier diffusion into the AR. [1] In ord

https://www.nano.lu.se/sites/nano.lu.se/files/2021-10/Adham_Kristi%20Adham%20Poster.pdf - 2025-07-29

NanoLundPoster NanoLundAnnualMeeting 2021 • The TRPL decay is faster with increasing Ga content, indicating Ga related trap states, possibly Ga vacancies at the NW surface • Comparing samples with a similar Ga content, the lifetimes for the samples grown using TEGa are somewhat longer. Compare for example the TEGa sample with x = 0.52 with the faster decay in the TMGa samples at x = 0.43 and x = 0

https://www.nano.lu.se/sites/nano.lu.se/files/2021-10/Alcer_NanoLund%20Annual%20Meeting%20Poster%20David%20Alcer.pdf - 2025-07-29

e- e- e- e- hv The incorporation of Bi atoms into III-V semiconductors is of large interest due to the potential formation of topological insulator states (1), band gap tuning (2) and increased spin-orbit coupling (3). Common techniques focus on bulk growth of Bi-III-V compounds imposing a limitation on the available crystal structure. Our approach enables the homogenous incorporation of single Bi

https://www.nano.lu.se/sites/nano.lu.se/files/2021-10/Benter_20210914_NanoLund_poster_SandraBenter_Optimized.pdf - 2025-07-29

PowerPoint Presentation Coherent Bragg imaging of nanoparticles with unknown rotation Huaiyu Chen1, Alexander Björling2, Jesper Wallentin1 1 Synchrotron Radiation Research, Lund University, Sweden. Email: huaiyu.chen@sljus.lu.se 1 2 MAX IV Laboratory, Lund University, Sweden Motivation and Methods EMC for BCDI Experiment[1] References Effect of Data Resolution on BCDI-EMC Bragg coherent diffractio

https://www.nano.lu.se/sites/nano.lu.se/files/2021-10/Chen_NanoLundAM_HY_Poster.pdf - 2025-07-29

PowerPoint Presentation Fifth order spectroscopy of Fe-carbene complexes Edoardo Domenichini, Petter Persson, Arkady Yartsev 1. NanoLund, Lund University Iron complexes are promising candidates for photovoltaic cells, however their current efficiency is far from the more expensive metals. This is due to the different nature and energy of the states involved in light harvesting and primary charge s

https://www.nano.lu.se/sites/nano.lu.se/files/2021-10/Domenichini_POSTER_NANOLUND%20Edo.pdf - 2025-07-29

https://www.nano.lu.se/sites/nano.lu.se/files/2021-10/Fast_Poster_NanoLund2021_Jonatan_Fast_Optimized.pdf - 2025-07-29

Conclusions and outlook • • •

https://www.nano.lu.se/sites/nano.lu.se/files/2021-10/Havir_Reflectometry%20Measurements%20on%20a%20Quantum%20Dot.pdf - 2025-07-29

MRS2021_high res.pdf PHOTOLUMINESCENCE MAPS OF WAFER-SCALE NANOWIRE ARRAYS Varied (a, b) and homogeneous (c, d) DTL doses. (a) and (c) show the highest measured intensity of every pixel. (b) and (d) show the peak position of the measured PL. Photoluminescence Maps 0 10 20 30 40 50 0 10 20 30 40 50 0 10 20 30 40 50 X [mm] 0 10 20 30 40 50 0 5000 10000 15000 20000 25000 30000 850 860 870 880 890 900

https://www.nano.lu.se/sites/nano.lu.se/files/2021-10/Hrachowina_Wafer-Scale%20Synthesis%20and%20Optical%20Characterization%20of%20InP%20Nanowire%20Arrays.pdf - 2025-07-29

PowerPoint Presentation Towards highly efficient earth-abundant photoelectrodes for solar-assisted catalysis Anurag Kawde1,2,3*, Lukas Hrachowina2, Pierre-Adrien Mante1, Kaibo Zheng1, Qi Shi1, Pavel Chabera1, Magnus Borgström2, Marius Graczyk2, Arkady Yartsev1, Jens Uhlig1,2,3*, Tonu Pullerits1,2* 1. Chemical Physics, Lund University, Sweden, 2. NanoLund, Lund University, Sweden, 3. LINXS, Lund Un

https://www.nano.lu.se/sites/nano.lu.se/files/2021-10/Kawde_Towards%20highly%20efficient%20earth-abundant%20photoelectrodes%20for%20solar-assisted%20catalysis.pdf - 2025-07-29

Higher-order sweet spot in a quantum double dot qubit References: Want to develop a new noise-resilient qubit design based on the available expertise at NanoLund: - Double quantum dots in nanowire systems. - Control with microwave resonators [1]. - Unique possible implementation with ring-like states [2]. We find a parameter regime of a double quantum dot which we expect to be highly resistent to

https://www.nano.lu.se/sites/nano.lu.se/files/2021-10/Kjaergaard%20Munk_PosterNanoLundAnnual2021MKM.pdf - 2025-07-29

Light Guiding and Tunneling, nanowire fabrication Photo-induced hot carrier cooling in two- dimensional perovskite single crystal Hot carrier solar cell (HCSC) is a promising solution to overcome Shockley-Queisser limit.[1-2] Here we investigate the potential of two-dimensional (2D) organic-inorganic hybrid perovskites [(BA)2(MA)2Pb3I10] as a building block in HCSC. To reveal the HC cooling mechan

https://www.nano.lu.se/sites/nano.lu.se/files/2021-10/Lin_Photo-induced%20hot%20carrier%20cooling%20in%20two%20dimensional%20perovskite%20single%20crystal.pdf - 2025-07-29

Correlation Clustering Correlation clustering - A tool to analyse blinking in semiconductor films Boris Louis1,2, Sudipta Seth1, Johan Hofkens2 and Ivan G. Scheblykin1 1Lund University, Division of Chemical Physics, SE-22100, Lund, Sweden 2KULeuven, Department of Chemistry, Celestijenlaan 200F, B-3001 Leuven, Belgium. 3. Results 4. Method Validation 5. Perspectives 2. Methods1. Introduction 6. Con

https://www.nano.lu.se/sites/nano.lu.se/files/2021-10/Louis_Correlation%20clustering%20-%20A%20tool%20to%20analyse%20blinking%20in%20semiconductor%20films.pdf - 2025-07-29

PowerPoint Presentation Ultrafast Dynamics in Charge Density Waves Pierre-Adrien Mante1,2, Chin Shen Ong3, Arkady Yartsev1,2, Oscar Gränås3, and Olle Eriksson3, 4 1. NanoLund, Lund University 2. Department of Chemical Physics, Lund University 3. Department of Physics and Astronomy, Uppsala University 4. School of Science and Technology, Örebro University, Sweden The strong interplay between degree

https://www.nano.lu.se/sites/nano.lu.se/files/2021-10/Mante_Ultrafast%20Dynamics%20in%20Charge%20Density%20Waves.pdf - 2025-07-29

AnnualMeeting2021 WACQT Wallenberg Centre for Quantum Technology Metastability and effective long-time dynamics • Metastable regime: defined by spectral gap • Long-time dynamics: • Projection onto metastable manifold [3,4]: • Every state probabilistic mixture of • constitute (competing) metastable phases |ρ(t)) ≈ |ρss) + eλ1t (ρ(0) ⃗l1) | ⃗r1) ρ(t) = p1(t) ρ̃1 + p2(t) ρ̃2 ρ̃1, ρ̃2 ρ̃1, ρ̃2 Quantum

https://www.nano.lu.se/sites/nano.lu.se/files/2021-10/Matern_Transient%20dynamics%20&%20metastability%20in%20parallel%20QDs.pdf - 2025-07-29

HEERA MENON1,2, NICHOLAS PAUL MORGAN3, HOSSEIN JEDDI2,4,5, CRISPIN HETHERINGTON2,6, HÅKAN PETTERSSON2,4,5, ANNA FONTCUBERTA i MORRAL3, MATTIAS BORG1,2 E-mail: heera.menon@eit.lth.seElectrical and Information Technology, Lund University 1. Electrical and Information Technology, Lund University, Lund, Sweden 2. NanoLund, Lund University, Sweden 3. Laboratory of Semiconductor Materials, Ecole Polytec

https://www.nano.lu.se/sites/nano.lu.se/files/2021-10/Menon_Integration%20of%20single%20crystalline%20InSb%20on%20Si%20by%20rapid%20melt%20growth_Optimized.pdf - 2025-07-29