Perovskita Solar Cell
This animation, commissioned by Agata Communication, illustrates the components of a solar cell. The key feature of this device is the use of molecular switches, molecules capable of reacting to light. The secret to its efficiency lies in strategically positioning these molecules between layers of perovskite structures. As the animation zooms out, we observe how it is integrated into the complete device.
Ion Beam Brilliance: The Spin-Ion Technological Revolution
Step into this animation to witness the cutting-edge technology behind Spin-Ion. It shows Spin-Ion’s distinctive ion beam technology is employed to engineer the structural attributes of magnetic materials. Get to know more about this company in:https://www.spin- ion.com/technology/ To explore more animations, visit www.patriciabondia.com.
Moth-Eye Nanostructures: Nature’s Blueprint for Advanced Surfaces
This animation, crafted in collaboration with Scixel (www.scixel.com), draws inspiration from the work of Isabel Rodriguez and her team at IMDEA Nanoscience. Nature’s moth-eye structures have long fascinated us with their unique antireflective and self-cleaning properties. The animation contrasts two scenarios: one showcasing the nanocone structures, inspired by the moth-eye, and the other without them. As a light ray moves across the material, observe the pronounced difference in reflection and refraction. The introduction of these nanocones significantly modifies the material’s optical attributes, minimizing undesired reflections. To delve deeper into this project, visit: IMDEA Nanoscience – Nanostructured Functional Surfaces.
Controlling Light Emission: A Glimpse into the Nano World
Dive into this animation, which draws inspiration from the work of Sara H. Mejias and Juan Cabanillas’ team at IMDEA Nanoscience. Harnessing the protective environment of proteins, they’ve achieved light emission from clusters, ingeniously controlling the light’s color by altering the cluster size. Explore the brilliance of this nano-innovation and the potential it holds for the future. To know more about this project: https://www.nanociencia.imdea.org/es/bio-engineered- nanophotonics/home For more scientific animations visit www.patriciabondia.com
Magnetized Biomedicine: The Power of Nanoparticles
This animation is inspired by the research of Dr. Cristina Flors and her team at IMDEA Nanoscience. The AFM (Atomic Force Microscopy) pierces the bacterial membrane, enabling the entry of the fluorescence dye. Consequently, the optical microscope can identify when the bacterium is dead. Know more about this project in: https://pubs.acs.org/doi/10.1021/acsami.0c08184
How Much Force Is Needed To Kill a Single Bacterium?
This animation is inspired by the research of Dr. Cristina Flors and her team at IMDEA Nanoscience. The AFM (Atomic Force Microscopy) pierces the bacterial membrane, enabling the entry of the fluorescence dye. Consequently, the optical microscope can identify when the bacterium is dead. Know more about this project in: https://pubs.acs.org/doi/10.1021/acsami.0c08184
A Closer Look: Super- resolution STED Microscopy and Amyloid Imaging
This scientific animation shows a novel approach to imaging amyloid fibers led by the group of Cristina Flors (IMDEA Nanoscience). Leveraging the properties of Thioflavin T (ThT), a commonly used amyloid probe, as a specific, exchangeable fluorophore, we’ve enhanced the capabilities of stimulated emission depletion (STED) super-resolution microscopy. This innovative method achieves an spatial resolution in the range of 60-70 nm, significantly reducing image background noise and boosting photostability for extended periods of STED imaging. These exciting advancements not only broaden the uses of ThT but also pave the way for the application of other common amyloid fluorescent in STED microscopy Delve into this research: https://doi.org/10.1039/D0NR02961K For more scientific animations and more about scientific visual communication: www.patriciabondia.com
Racing on the Edge of Science: Nanocar Challenge
The of researchers at IMDEA Nanociencia are revving up their molecular engines for the international Nanocar Race. Spearheaded by David Écija and Emilio M. Pérez, the teams from Madrid are gearing up to showcase their prowess in the second edition of this race in Toulouse, in March 2022. Dive into the world’s most miniature car race, where vehicles are not cars but molecules, racing tirelessly for 24 hours on a gleaming gold track. These molecular marvels are propelled by the intricate interaction with a scanning tunneling microscope (STM). But it’s not just a race; it’s a mission. The ultimate aim? Pioneering the development of nanomachines that can perform tangible tasks, from transporting molecular-scale cargo to revolutionizing nano-fabrication. Dive deeper and discover more at: https://nanohispa.nanociencia.imdea.org/.
Biofilms lighting storm: the bright battle against superbugs
Danger! Antibiotic bacteria resistance is a serious human threat. The evolution of such superbugs necessitates a revolution in our defense strategies. We must now look towards pioneering solutions, specifically, light-activatable molecules. These innovative agents target not just the bacteria, but also the matrix components that the bacteria form when in their protective biofilm state. This animation brings to life the research led by Dr. Joaquim Torra, Dr. Cristina Flors and and myself, offering an insight into a future where we might successfully combat the looming peril of antibiotic resistance. Check it in: https://pubs.rsc.org/en/content/articlelanding/2021/CC/D1CC03155D For more scientific animations and more about scientific visual communication: www.patriciabondia.com
Pioneering Osmium Compounds: A New Frontier in Cancer Treatment
This animation was created in collaboration with Scixel (www.scixel.com) and inspired by the groundbreaking work of Dr. Ana Pizarro and her team at IMDEA Nanociencia. Traditional chemotherapy treatments, while effective, often come with undesired side effects. This animation explores the untapped potential of osmium compounds in the fight against cancer. Previously thought to be inert, these osmium compounds have been reactivated by researchers, and intriguingly, they’ve achieved this with water. By incorporating a water molecule into the osmium structure, a reversible ring formation is promoted. This ring acts like a swing door, opening and closing, which inhibits the formation of inert osmium species. These complexes play a pivotal role in the conversion of pyruvate to lactate within cancer cells, with the balance between the two being a key aspect of cancer progression. Get to know more about this project in Osmium activation in cancer cells (imdea.org). For more scientific animations visit www.patriciabondia.com and www.scixel.com
Unveiling the Power of STM: A Glimpse into Atomic Precision
Step into this animation, where we spotlight the Scanning Tunneling Microscopy (STM) – a remarkable technique that delves into the atomic and molecular realms with unparalleled precision. This visualization draws inspiration from the work of David Ecija and his team at IMDEA Nanoscience, emphasizing the potential of the STM technique in the world of nanoscience. To explore more about their cutting-edge research, visit: https://nanociencia.imdea.org/nanoarchitectonics-on-surfaces/group- home For more scientific animations that bring complex techniques and concepts to life, visit www.patriciabondia.com.
Revolutionizing 2D Material Interfaces: A Breakthrough in Covalent Heterostructures
In the realm of 2D materials, stacking atomically thin layers to create functional heterostructures has been a common practice. However, the weak van der Waals bonds in these structures have posed challenges in building robust multi-purpose devices due to interface limitations. This animation was created in collaboration with Scixel (www.scixel.com) and shows the groundbreaking work of researchers Enrique Burzurí and Emilio M. Pérez from IMDEA Nanociencia. For the first time, they’ve covalently connected two 2D materials: MoS2 and graphene, using a unique bifunctional molecule. This innovative approach, detailed in Nature Chemistry (10.1038/s41557-022-00924-1), not only enhances the electronic properties of the heterostructure but also paves the way for potential applications by combining the best of MoS2’s semiconducting properties with graphene’s high carrier mobility. For more scientific animations visit www.patriciabondia.com
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