Mine forskningsinteresser er fokusert rundt nanofabrikasjon, fotonikk, plasmoniske systemer. Vi jobber med applikasjoner innenfor fornyber energi, energiomstilling og sensorteknologi. 

To av våre viktigste forskningsområdene idag er:
- Forbedre "standard" silisium solceller ved å anvende skreddersydde plasmoniske systemer for å øke effektiviteten.
- Utvikling av et såkalt "kvante diamant mikroskop" for avbildning- og ultrasensitive sensor applikasjoner

Nano161 - Innføring i nanoteknologi og -instrumentering

Energi210 - Energifysikk og -teknologi

SDG207 - Energiomstilling 

PHYS101 - Grunnkurs i mekanikk og varmelære

Vitenskapelig artikkel

• Sabrina Daniela Eder; Xiaodong Guo; Thomas Kaltenbacher et al. (2015). Focusing of a neutral helium beam with a photon-sieve structure. (ekstern lenke)
• Sabrina Daniela Eder; Thomas Reisinger; Martin Møller Greve et al. (2012). Focusing of a neutral Helium beam below one micron. (ekstern lenke)
• Sabrina Daniela Eder; Ranveig Flatabø; Anders K Ravn et al. (2018). Fast resolution change in neutral helium atom microscopy. (ekstern lenke)
• Spiros Kotopoulis; Sabrina Daniela Eder; Martin Møller Greve et al. (2013). Lab-on-a-chip device for fabrication of therapeutic microbubbles on demand. (ekstern lenke)
• Lars Egil Helseth; Martin Møller Greve (2023). Wetting of porous thin films exhibiting large contact angles. (ekstern lenke)
• Martin Møller Greve; Bodil Holst (2013). Optimization of an electron beam lithography instrument for fast, large area writing at 10 kV acceleration voltage. (ekstern lenke)
• Ranveig Flatabø; Akshay Agarwal; Richard Hobbs et al. (2018). Exploring proximity effects and large depth of field in helium ion beam lithography: large-area dense patterns and tilted surface exposure. (ekstern lenke)
• John Benjamin Lothe; Mali Husby Rosnes; Anna Dorota Kosinska et al. (2025). Synthesizing aluminum nanoparticles using DC diode sputtering and gas aggregation cluster source. (ekstern lenke)
• Thomas Reisinger; Sabrina Daniela Eder; Martin Møller Greve et al. (2010). Free-standing silicon-nitride zoneplates for neutral-helium microscopy. (ekstern lenke)
• Håvard Stavn Ugulen; Ranveig Flatabø; Mansoor A. Sultan et al. (2022). Experimental and theoretical investigation of waveguided plasmonic surface lattice resonances. (ekstern lenke)
• Jon Olav Grepstad; Martin Møller Greve; Thomas Reisinger et al. (2013). Nanostructuring of free-standing, dielectric membranes using electron-beam lithography. (ekstern lenke)
• Martin Møller Greve; Das Bijoy; Issac Ibrahim et al. (2020). Electric‐Potential‐Induced Complete Control of Magnetization in MnZnSb Metallic Ferromagnets. (ekstern lenke)
• Justas Zalieckas; Ivan Rios Mondragon; Paulius Pobedinskas et al. (2022). Polycrystalline diamond coating on orthopedic implants: Realization and role of surface topology and chemistry in adsorption of proteins and cell proliferation. (ekstern lenke)
• Ranveig Flatabø; Martin Møller Greve; Sabrina Daniela Eder et al. (2017). Atom sieve for nanometer resolution neutral helium microscopy. (ekstern lenke)
• Martin Møller Greve; Thomas Odijk Håvardstun; Bodil Holst (2013). Measuring the localized surface plasmon resonance effect on large arrays (5 mm × 5 mm) of gold and aluminum nanoparticles on borosilicate glass substrates, fabricated by electron beam lithography. (ekstern lenke)
• Sol Johanne Xiang Helleseth Mehammer; Martin Møller Greve; Pawel Jan Kosinski et al. (2024). Investigation of Erosion and Deposition Due to Flows with Particles. (ekstern lenke)
• Henock Demessie Yallew; Jana Jágerská; Martin Møller Greve (2022). Long, stitch-free slot waveguide with s-bend tapered couplers for IR-sensing applications using electron beam lithography. (ekstern lenke)
• Martin Møller Greve; Alexandre Vial; Jakob J. Stamnes et al. (2013). The Beynon Gabor zone plate: a new tool for de Broglie matter waves and hard X-rays? An off axis and focus intensity investigation. (ekstern lenke)
• Justas Zalieckas; Martin Møller Greve; Luca Bellucci et al. (2024). Quantum sensing of microRNAs with nitrogen-vacancy centers in diamond. (ekstern lenke)
• Jon Olav Grepstad; Martin Møller Greve; Bodil Holst et al. (2013). Finite-size limitations on quality factor of guided resonance modes in 2D photonic crystals. (ekstern lenke)
• Vårin Renate Andvik Holm; B. Y Zheng; Philip Denby et al. (2018). Work Function-Driven Hot Electron Extraction in a Bimetallic Plasmonic MIM Device. (ekstern lenke)
• Mirjam Dyrhovden Fjell; John Benjamin Lothe; Naomi J. Halas et al. (2024). Enhancing Silicon Solar Cell Performance Using a Thin-Film-like Aluminum Nanoparticle Surface Layer. (ekstern lenke)
• Thomas Reisinger; Martin Møller Greve; Sabrina Daniela Eder et al. (2012). Brightness and virtual source size of a supersonic deuterium beam. (ekstern lenke)
• Justas Zalieckas; P. Pobedinskas; Martin Møller Greve et al. (2021). Large area microwave plasma CVD of diamond using composite right/left-handed materials. (ekstern lenke)
• Vårin Renate Andvik Holm; Martin Møller Greve; Bodil Holst (2016). Temperature induced color change in gold nanoparticle arrays: Investigating the annealing effect on the localized surface plasmon resonance. (ekstern lenke)
• Ranveig Flatabø; Antoine Coste; Martin Møller Greve (2016). A systematic investigation of the charging effect in scanning electron microscopy for metal nanostructures on insulating substrates. (ekstern lenke)
• Vårin Renate Andvik Holm; Martin Møller Greve; Bodil Holst (2017). A theoretical investigation of the optical properties of metal nanoparticles in water for photo thermal conversion enhancement. (ekstern lenke)
• Nikolai Frøvik; Martin Møller Greve; Lars Egil Helseth (2019). Nanostructures and wetting properties controlled by reactive ion etching of fluorinated ethylene propylene. (ekstern lenke)
• Ranveig Flatabø; Vårin Renate Andvik Holm; Håkon Eidsvåg et al. (2017). Light absorption and scattering of 40-170 nm gold nanoparticles on glass substrates. (ekstern lenke)
• Paul Thomas; Bichitra Nanda Sahoo; Peter James Thomas et al. (2024). Recent advances in emerging integrated anticorrosion and antifouling nanomaterial-based coating solutions. (ekstern lenke)

Forelesning

• Martin Møller Greve (2017). Nanotechnology for harvesting solar energy. (ekstern lenke)
• Martin Møller Greve (2021). Forbedret solcelleeffektivitet med nanobasert anti-refleksjonsbelegg. (ekstern lenke)
• Martin Møller Greve (2024). Biosfæredagen - Grøn omstilling: energibehov, arealpress og natur i Nordhordland. (ekstern lenke)
• Martin Møller Greve (2021). Nanotechnology for increased solar cell efficiencies. (ekstern lenke)
• Martin Møller Greve (2020). Life-cycle cost analysis for silicon solar cells. (ekstern lenke)
• Martin Møller Greve (2019). Work function driven hot electron extraction from metallic nanowires. (ekstern lenke)
• John Benjamin Lothe; Martin Møller Greve; Mali Husby Rosnes et al. (2025). A novel way of synthesizing particles - Aluminum nanoparticles (AlNPs). (ekstern lenke)
• Martin Møller Greve (2022). Nanoteknologi for fremtiden og klima. (ekstern lenke)
• Martin Møller Greve (2022). Økt solcelleeffektivitet med nanobasert anti-refleksjonsbelegg. (ekstern lenke)
• Leander Jacob Nielsen Eikås; Frank Øvstetun; Martin Møller Greve (2023). AI – Sitep/UiB/Norsun - Kva – korleis - kvifor. (ekstern lenke)
• Martin Møller Greve; Justas Zalieckas (2019). Quantum sensors in diamond for magnetic field sensing. (ekstern lenke)

Konferanseposter

• Martin Møller Greve; Ranveig Flatabø; Karl K Berggren et al. (2018). Atom sieve for nanometer resolution neutral helium microscopy. (ekstern lenke)
• Vårin Renate Andvik Holm; Martin Møller Greve; Bodil Holst (2015). Blue to red observation of a reversed color change in an array of gold nano particles; a systematic investigation.. (ekstern lenke)
• Jon Olav Grepstad; Martin Møller Greve; Thomas Reisinger et al. (2013). Advances on e-beam fabrication of photonic crystal membranes. (ekstern lenke)
• John Benjamin Lothe; Mirjam Dyrhovden Fjell; Mali Husby Rosnes et al. (2022). Enhancing silicon solar cell performance using aluminum nanoparticles. (ekstern lenke)
• Mirjam Dyrhovden Fjell; Bodil Holst; Mali Husby Rosnes et al. (2021). Enhancing Solar Cell Efficiency Using Nanotechnology. (ekstern lenke)
• Vårin Renate Andvik Holm; Ranveig Flatabø; Martin Møller Greve et al. (2014). An all metal solar cell. (ekstern lenke)
• Håvard Stavn Ugulen; Martin Møller Greve; Ranveig Flatabø et al. (2017). Metal nanoparticles fabricated on a waveguide – sensing with white light. (ekstern lenke)
• Vårin Renate Andvik Holm; Martin Møller Greve; Bodil Holst (2016). Investigating the cause of a color change in annealed gold nano particle arrays. (ekstern lenke)
• Martin Møller Greve; Sabrina Daniela Eder; Ranveig Flatabø et al. (2019). Nanostructured optical elements for neutral helium microscopy. (ekstern lenke)
• Vårin Renate Andvik Holm; Ranveig Flatabø; Martin Møller Greve et al. (2014). University of Bergen Nano Physics Group Selected Activities. (ekstern lenke)
• Martin Møller Greve; Vårin Renate Andvik Holm; Ranveig Flatabø et al. (2017). A study of light absorbance of gold metal nanoparticles in the size range 45 to 200 nm fabricated using e-beam lithography. (ekstern lenke)
• Martin Møller Greve; Håvard Stavn Ugulen; Ranveig Flatabø et al. (2018). Metal nanoparticles fabricated on a waveguide – sensing with white light. (ekstern lenke)
• Martin Møller Greve; Philip Denby; Bodil Holst (2013). Mm2 size arrays of metal nano-particles for solar cell applications fabricated by Electron Beam Lithography (EBL). (ekstern lenke)
• Ranveig Flatabø; Bodil Holst; Martin Møller Greve (2016). Measurement error in metal nanostructures on insulating substrates induced by electron beam irradiation. (ekstern lenke)

Konferanseforedrag

• Jon Olav Grepstad; Martin Møller Greve; Ib-Rune Johansen et al. (2014). Photonic crystals designed for optical biosensing, applied to detect single nano-particles. (ekstern lenke)
• Martin Møller Greve (2022). Enhanced solar cell efficiencies using plasmonic nanostructures. (ekstern lenke)
• Martin Møller Greve; Thomas Odijk Håvardstun; Bodil Holst (2013). Testing optical properties of metal nano-particles in large arrays for PV cell applications, fabricated by Electron Beam Lithography (EBL). (ekstern lenke)
• Martin Møller Greve (2015). Nanostructures for tuning of optical properties: Light and matter wave applications. (ekstern lenke)
• Ranveig Flatabø; Martin Møller Greve; Bodil Holst et al. (2017). Large area scanning helium ion beam lithography. (ekstern lenke)
• Ranveig Flatabø; Bodil Holst; Martin Møller Greve (2015). Charging effects in metal nanoparticles on insulating substrates. (ekstern lenke)
• Martin Møller Greve; Henock Demessie Yallew; Jana Jagerska (2022). Long, stitch-free slotted waveguides for IR-sensing applications using e-beam lithography. (ekstern lenke)
• Jon Olav Grepstad; Martin Møller Greve; Bodil Holst et al. (2014). Finite-size limitations on the strength of guided resonances in 2D photonic crystals. (ekstern lenke)
• Martin Møller Greve (2021). Boosting solar cell efficiencies using plasmonic nanostructures. (ekstern lenke)
• Martin Møller Greve (2014). Nanostructures for the manipulation of light and matter waves. (ekstern lenke)
• Martin Møller Greve; Bodil Holst (2013). Optimization of an electron beam lithography instrument for fast large area writing at "low" voltage. (ekstern lenke)
• Martin Møller Greve (2025). Plasmonic nanostructures for increased light incoupling in silicon solar cells. (ekstern lenke)
• Ranveig Flatabø; Martin Møller Greve; Karl K Berggren et al. (2017). Atom sieve for nanometer resolution neutral helium microscopy. (ekstern lenke)
• Martin Møller Greve; Vårin Renate Andvik Holm; Bob Y. Zheng et al. (2016). Investigating the impact on hot electron emission from LSPR in gold nanostructures for varying dielectric separator thickness. (ekstern lenke)
• John Benjamin Lothe; Mirjam Dyrhovden Fjell; Mali Husby Rosnes et al. (2022). Enhancing silicon solar cell performance using aluminum nanoparticles. (ekstern lenke)
• Martin Møller Greve; Justas Zalieckas; Bodil Holst (2019). Wide-field microscopy for magnetic field imaging using nitrogen vacancies in diamond. (ekstern lenke)
• Ranveig Flatabø; Martin Møller Greve; Bodil Holst (2017). Helium ion beam lithography. (ekstern lenke)

Vitenskapelig litteraturgjennomgang

• Johannes Fiedler; Kristian Berland; James Borchert et al. (2022). Perspectives on weak interactions in complex materials at different length scales. (ekstern lenke)
• Bichitra Nanda Sahoo; Peter James Thomas; Paul Thomas et al. (2025). Antibiofouling Coatings For Marine Sensors: Progress and Perspectives on Materials, Methods, Impacts, and Field Trial Studies. (ekstern lenke)

Masteroppgave

• Martin Møller Greve; Sti Olve (2021). Building a Combined Brightfield and Confocal Quantum Diamond Microscope for Imaging of Magnetic Samples. (ekstern lenke)
• Bodil Holst; Håkon Eidsvåg; Martin Møller Greve et al. (2016). A Solar Absorber Based on Metal Nanoparticles. (ekstern lenke)
• Nikolai Frøvik; Martin Møller Greve; Lars Egil Helseth (2017). Altering the wetting properties of FEP films by nano-structuring the surface using reactive ion etching. (ekstern lenke)
• Leander Jacob Nielsen Eikås; Martin Møller Greve; Nello Blaser et al. (2024). Machine learning for early detection of structure loss in the Czochralski process. (ekstern lenke)
• Martin Møller Greve; Lars Egil Helseth; Yana Vaynzof et al. (2020). Modelling and Optimization of the Performance of Droplet based electrostatic Energy Harvester. (ekstern lenke)
• Espen Selfors; Martin Møller Greve; Bodil Holst (2017). Fabrication of large free-standing nanostructured zone plates for focusing a Bose-Einstein condensate. (ekstern lenke)
• Torbjørn Egeland-Eriksen; Bodil Holst; Martin Møller Greve (2018). Simulations of the Effect of Integrated Metal Nanoparticles on the Optical Absorptance of Perovskite Photovoltaic Solar Cells. (ekstern lenke)
• Adrià Salvador Palau; Bodil Holst; Gianangelo Bracco et al. (2015). Time of Flight Modelling and Direct Monte Carlo Simulations for a Neutral Helium Microscope. (ekstern lenke)
• Martin Møller Greve; Alfred Bakkebø (2022). An investigation and optimization of bifacial solar cells for Norwegian solar conditions. (ekstern lenke)
• Hansen Athina; Martin Møller Greve (2025). Diamond-based anti-reflective coatings for solar cells. (ekstern lenke)
• Nello Blaser; Audun Ljone Henriksen; Martin Møller Greve (2023). Learning Acquisition Functions for Cost-aware Bayesian Optimization. (ekstern lenke)
• Mona Heng; Pawel Jan Kosinski; Martin Møller Greve (2024). Evaluation of structural dynamic response of piping subjected to multiphase flow-induced vibration. (ekstern lenke)
• Sverre Magnus Engø; Martin Møller Greve (2022). IR transmission optimization for Cadmium Telluride. (ekstern lenke)
• Mirjam Dyrhovden Fjell; Bodil Holst; Martin Møller Greve (2020). An investigation of the optical properties of metal nanoparticles for the application in a diffuse light solar cell. (ekstern lenke)
• Martin Møller Greve; Lorentz Tvedt Syslak; Morten Førre et al. (2024). Nanofabrication and simulation of nanogratings for geometric induced doping in photovoltaic application. (ekstern lenke)
• Bolstad Marius; Martin Møller Greve; Hansen Jan Petter (2025). Design, fabrication and characterization of gold nanorods for laser-induced fusion. (ekstern lenke)
• Håvard Stavn Ugulen; Martin Møller Greve; Ranveig Flatabø et al. (2018). Optical Properties of Gold Nanoparticle Arrays Fabricated on a Waveguide Material. (ekstern lenke)
• To Minh Chi; Martin Møller Greve (2021). Enhancing Light In-Coupling for Thin-Film Solar Cells Using Plasmonic Nanostructures. (ekstern lenke)
• Martin Møller Greve; Bodil Holst (2010). Testing nano-structured Fresnel zoneplates for neutral helium microscopy on a molecular-beam ultra-high-vacuum apparatus. (ekstern lenke)
• Thomas Odijk Håvardstun; Bodil Holst; Martin Møller Greve (2013). Optical Properties of Metal Nanoparticle Arrays created using Electron Beam Lithography. (ekstern lenke)
• Bodil Holst; Ranveig Flatabø; Martin Møller Greve (2014). Optical Properties of Metal Nanoparticle Arrays Created using Electron Beam Lithography for Solar Cell Application. (ekstern lenke)
• Kanthee Kosolyuthasarn; Martin Møller Greve (2022). Fabrication of nanostructured free-standing Fresnel zone plate for neutral matter-waves microscopy. (ekstern lenke)

Doktorgradsavhandling

• Vårin Renate Andvik Holm; Bodil Holst; Martin Møller Greve (2018). Nanostructured Materials for Solar Energy Applications. (ekstern lenke)
• Ranveig Flatabø; Bodil Holst; Martin Møller Greve (2018). Charged Particle Lithography for the Fabrication of Nanostructured Optical Elements. (ekstern lenke)
• Martin Møller Greve (2013). Nanostructuring for the manipulation of electromagnetice waves. (ekstern lenke)

Medieintervju

• Konrad Tywoniuk; Jan Petter Hansen; Martin Møller Greve et al. (2025). 2025: Kvantefysikkens år. (ekstern lenke)
• Martin Møller Greve (2021). Alle snakkar om klimakrisa. Dette er forskarar som gjer noko med den.. (ekstern lenke)
• Martin Møller Greve; Mathilde Moe Kaupang (2021). Så lang tid tar det før solcellene på taket ditt blir lønnsomme. (ekstern lenke)

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