Surfaces and interfaces are all around us and everywhere. In this podcast, we dig deeper into surface-related phenomena to take a closer look at how they affect us and the world we live in. We invite leading scientists from different areas to have interesting discussions spanning everything from con…
How important is it to be productive to succeed in academia? And what about being creative?In this episode, we once again have the pleasure talking to Prof. Fredrik Höök, Professor of Nano and Biophysics, at the Department of Physics at Chalmers University of technology. Prof. Hook was our guest in episode 29. Then we had an interesting conversation around several aspects related to research and life in science. At the end of the session, there were still lots of questions that I was curious to ask, and fortunately, Prof. Hook kindly agreed to continue the discussion in an additional episode. This time, we talk about some of the challenges of an academic career path and how to strategically relate to these. We pick up the conversation essentially where we left it - Prof. Hook had just mentioned that he decided to go for a career in science despite all the risks and uncertainties involved. We talk about what those uncertainties are, and how they can be addressed and related to. We also discuss the potential need for a backup plan, the role productivity, inspiration, and if it is important to be creative to succeed with an academic career. Prof. Hook shares his best advice to those of you that dream about pursuing a career in science but who hesitate, or think it seems too risky. He also shares his view on what personal qualities that are needed to be successful in academia. Thanks for listening! If you are interested in surface and interface science and related topics, you should check out our blog - the Surface Science blog
What is an initial value problem? And why do many of us find mathematical modelling so challenging? In this episode, we again have the honor of talking to Prof. Marina Axelson-Fisk, Professor in Mathematical Statistics at Chalmers University of Technology. This is the third time Prof. Axelson-Fisk is a guest in Science on Surfaces – tips, tricks and tools, and this time she shares some of her vast knowledge on mathematical modelling and how this is used in science. As always, we started with the basics and Prof. Axelson-Fisk explained what mathematical modelling is, when it is typically used, and what is important to consider when doing this type of analysis. Prof. Axelson-Fisk also described a few examples of common models and their characteristics, how to improve a model and how to find the set of parameter values that best fit the data. We also talked about assumptions, limitations, and validation, as well as challenges encountered when modelling, and pitfalls to avoid. She also shared her thoughts are on why so many of us find modelling so challenging and how this limiting barrier can be addressed. This episode really is packed with information.Thanks for listening! If you are interested in surface and interface science and related topics, you should check out our blog - the Surface Science blog
What is life in research like? How ambitious and performance-oriented do you have to be to do a PhD? And - what is the difference between Food science and Food engineering?I this episode, we talk to Dr. Holly Huellemeier, Graduate Research Assistant at the Department of Food, Agricultural, and Biological Engineering at the Ohio State University, to learn more about what it is like to spend years in research to earn a doctoral degree.At the time of the recording, Dr. Huellemeier had just graduated and was preparing to take on a postdoc overseas. With the experience fresh in mind, she generously shared some of her insights and perspectives on her years as a PhD student. We talked about why she decided to go for a career in science, what a typical day looked like, what aspects she enjoyed the most and what she found challenging. We also talked about her research project which was on the mechanisms of fouling and cleaning during thermal milk processing, and she also explained what the difference between food science and food engineering is. Finally, Dr. Huellemeier shared some advice to those of you who are considering doing a Ph.D.Thanks for listening! If you are interested in surface and interface science and related topics, you should check out our blog - the Surface Science blog
Data analysis basics and how to make the most of the collected dataHow do you maximize the information extraction from that data that you may have spent weeks collecting? And what is the difference between ‘precision' and ‘accuracy'? In this episode, we talk to Prof. Marina Axelson-Fisk, Professor in Mathematical Statistics at Chalmers University of Technology about Data analysis, to learn more about how to make the most of the data that you have collected.In this informative conversation, Prof. Axelson-Fisk guides us through a range of different data analysis types such as exploratory-, descriptive-, and predictive analysis and explains when to use which method. We also talk about the data analysis process from start to end; how to handle the data before you analyze it, requirements on the data input, and how to assess the analysis output. We then move on to briefly discuss data modelling and key aspect related to this procedure. Prof Axelson-Fisk's explains key terminology such as repeatability, replicability and reproducibility. And, finally and once and for all, we get the difference between precision and accuracy explained. Last but not least, we talk about the main challenges with data analysis, what pitfalls to look out for, and we get a recommendation on data analysis software to use. By the way, the English translation of ‘supraledare' is of course ‘superconductor' Thanks for listening! If you are interested in surface and interface science and related topics, you should check out our blog - the Surface Science blog
Collecting quality data with QCM-D – what to consider and pitfalls to avoidHow do you maximize your chances of a measurement being successful? And which are the main pitfalls to avoid when planning and executing experiments?In this episode, we talk to Jennie Ringberg, Global Technical Product Manager for QSense at Biolin Scientific, to learn more about the practical aspects of data collection and experimental design with the ambition to maximize the data quality. The conversation focuses on the QCM-D measurements, but some of the principles discussed are relevant also for other types of analysis of surfaces and interfaces.In this educational conversation, Jennie takes us through the five main steps of preparing and running QCM-D measurements. One by one, we go through the steps and discuss what's important to consider for the measurement to be successful with the ambition to optimize the quality of the collected data. We talk about what aspects to pay particular attention to and why these are important for the result. We also cover common challenges, and what will be the consequence if important aspects are ignored.Thanks for listening! If you are interested in surface and interface science and related topics, you should check out our blog - the Surface Science blog
Why are surface analytical tools useful when scrutinizing virus infections and when trying to figure out ways to tackle them? And what makes research successful?In this episode, we talk to Prof. Fredrik Höök, Professor of Nano and Biophysics, at the Department of Physics at Chalmers University of Technology, about his research and work related to biological nanoparticles, virus infections, and vaccine development.This inspiring and intriguing conversation covered multiple facets of academic life - from the bigger perspectives, drivers, and challenges of a career in science, to the quest for solutions to long-lasting problems and discussion on specific scientific detail. We talked about the ‘what', ‘why' and ‘how' of Prof. Hook's research and work, and what he and his team are striving to achieve. He also revealed a question that did keep him awake at night for decades, but to which he now finally found the answer. We talked about model systems and instrumentation, and what surface analytical tools they are using in their work. We also discussed more philosophical aspects of life in science, such as what makes research successful, and what pieces of the puzzle must come together for everything to fall into place.Thanks for listening! If you are interested in surface and interface science and related topics, you should check out our blog - the Surface Science blog
Is it possible to be more time-efficient when planning, executing and evaluating experiments? And what do the latin squares have to do with it?In this episode, we talk to Prof. Marina Axelson-Fisk, Professor in Mathematical Statistics at Chalmers University of Technology about Design of Experiments, DoE, to learn more about how to efficiently plan your work and to make the most of the time spent in the lab.As always, we start with the basics, and Prof. Axelson-Fisk takes us through what DoE is, when it could be used and who will benefit from using this methodology. We then move on to talk about how DoE works in practice. Prof. Axelson-Fisk describes a few examples to demonstrate how this method to plan, execute and evaluate experiments could be used in real life. We talk about what challenges and difficulties that may arise, and what pitfalls to look out for. Finally, we get to learn about some key concepts in DoE, and Prof. Axelson-Fisk explains terminology such as analysis of variance - transformations, model validation and residual analysis; factorial design with fixed, random and mixed effects, latin squares and confounding, just to mention a few.Thanks for listening! If you are interested in surface and interface science and related topics, you should check out our blog - the Surface Science blog
What is Quartz Crystal microbalance with Dissipation monitoring? And what's the deal with all the harmonics?In this episode, we talk to Fredrik Pettersson and Erik Nilebäck, both Senior Application Scientists at Biolin Scientific, about the QCM-D technology. Erik has a MSc in Engineering Biology and Devices and Materials in Medicine and a Ph.D. in Bioscience, and Fredrik has a MSc Biophysical engineering.Both Erik and Fredrik have extensive experience working with the QCM-D technology and in this episode, they share lots of useful information and insights that they have gathered over the years. The conversation starts with the basics, and we talk about what QCM-D technology is, what information it provides, and when it is typically used. We then move on to talk about different versions of QCM:s and their respective strengths and weaknesses. Finally, we go into how a QCM-D measurement is run in practice, and Erik and Fredrik share some useful tips and tricks on how to get the most out of this surface sensitive technology.Thanks for listening! If you are interested in surface science and related topics, you should also check out our blog - the Surface Science blog
How is the gut-microbiota related to human health? And why do some Lactobacillus strains show health-promoting properties?I this episode, we talk to Dr. Joana Ortega-Anaya, postdoc researcher at the Department of Food Science and technology, at the Ohio State University, to learn more about probiotics and how food can be used to support the symbiotic microbes in the gut microbiome. Dr.Ortega-Anaya specializes in the study of milk components and how they affect probiotics and human health. The conversation starts with Dr. Ortega-Anaya explaining what the microbiome is and what role it plays in the body. She describes the so-called “gut-brain axis” and how different lifestyle factors, such as stress and diet affect the composition of the microbiota – a composition which in turn affects our wellbeing. We then move on to talk about Dr.Ortega-Anaya's research. Using QCM-D technology and other methods, she has studied four different lactobacillus strains, and how the bacterial adhesion, one of the key aspects of probiotic lactic acid bacteria, was affected by the presence of milk fat.Thanks for listening! If you are interested in surface science and related topics, you should also check out our blog - the Surface Science blog
What analytical instrumentation should you have in your biointerfaces lab? And which equipment should you prioritize to invest in if the funding available for new instrument purchase is limited?I this episode, we talk to Dr. Jenny Malmstrom, Senior Lecturer in Chemical and Materials Engineering at the University of Auckland to learn more about lab instrumentation and analysis methods. With a background in bioengineering and nanoscience, Dr. Malmström has long experience characterizing and understanding the interaction between biomolecules and surfaces. Today, her research is all about interfaces. In this episode, she shares her knowledge and expertise on which analytical methods are used in this field. Using her own research as a starting point, Dr. Malmström exemplifies what characterization that is needed to answer key questions, and describes some of the technologies used by her team. She also shares advice on what equipment to focus on if you are starting up a new lab and have limited funding available for investment, and how to handle a situation where your lab is not equipped with all the instrumentation that you need for your research.Thanks for listening! If you are interested in surface science and related topics, you should also check out our blog - the Surface Science blog
How determined do you have to be to make a career as a scientist? Do all future positions have to be in the same field as the focus of your PhD research? And what's it like to transition from academia to industry?In this episode of Science on Surfaces, we take a different approach and dive into the mind of the scientist. We talk to Dr. Fredrik Andersson, Scientist and Project Leader at Agriculture and Food for Nouryon Performance formulations, about his career path, which started with a PhD in biochemistry, followed by a postdoc, from where he then moved on to jobs in industry.The conversation covers career plans, personal and professional drivers, and reflections on how determined you must be to pursue a career in science. We talk about Dr. Andersson's decision to do a PhD and what about science that inspires him. He also shares his story on why he decided to leave academia for industry, and how he experienced this transition. And not only did Dr. Andersson take the academia-industry leap, but he also changed research fields and moved from the area of biochemistry to that of surfactants, which is a topic that we of course also had to talk about. Finally, Dr. Andersson shares his thoughts on what's challenging and what's fun with his current position, and what career plans he has for the future.Thanks for listening! If you are interested in surface science and related topics, you should also check out our blog - the Surface Science blog
Did you know that light can be manipulated at the nanoscale to control not only colors but also chemical reactions as well as what we see, or do not see?In this interesting and last episode of the season, we talk to Prof. Magnus Jonsson, Associate Professor and head of the Organic Photonics and Nano-Optics group at the Laboratory of Organic Electronics at Linköping University in Sweden, about light-interaction with matter. Guiding us through the realm of different light-matter interaction phenomena, Prof. Jonsson touches upon optical concepts and terminology such as scattering, reflection, diffraction, refraction, interference, plasmons, Planck radiation, optical cavities, and radiative cooling. We are also introduced to fascinating research. Prof. Jonsson describes how he and his team manipulate light at the nanoscale in various fundamental and applied projects. For example, we get to hear about the paper-like displays - a type of display that is based on reflection rather than emission, which would be both energy efficient and work well outdoors on a sunny day. In another project, they use optical properties to cool objects using space as a heat sink; a solution that could be used to reduce the need for air conditioning in warmer regions. And of course, we had to talk about the intriguing concept of an invisibility cloak and reveal the mystery of how this could work.Thanks for listening! If you are interested in surface science and related topics, you should also check out our blog - the Surface Science blog
Is it possible to map a specific taste experience without anyone tasting the actual product? And is it possible to prevent sensitive natural colorants from bleaching when used in acidic beverages?In this episode of Science on surfaces we talk to Dr. Younas Dadmohammadi, from the Abbaspourrad lab at Cornell University, about the discipline of food science. The conversation starts with Dr. Dadmohammadi explaining how this multidisciplinary area originated, and then he takes us through two of his most recent research projects. He guides us through two different challenges related to key aspects of food intake - food appearance and food taste, and how these were addressed in his lab. In the conversation we get to learn more about how the shelf-life stability of sensitive natural colorants can be enhanced, and that those nutritious, but off-flavor, food ingredients that we would like to consume due to their health promoting properties, are not doomed to ruin the eating experience.Thanks for listening! If you are interested in surface science and related topics, you should also check out our blog - the Surface Science blog
How does a Li-ion battery differ from the ones you use in a torch? What makes it so special that its development even was awarded the Nobel Prize in chemistry in 2019? And what’s the deal with the whiskers? In this episode of Science on surfaces we talk to Prof. Erik Berg about the fascinating area of Li-ion batteries. Prof. Berg is Associate senior lecturer and Assistant Professor at the Department of Chemistry - Ångström Laboratory, and Structural Chemistry at Uppsala University in Sweden. Prof. Berg takes us on an interesting and educational journey through area of batteries in general, and Li-ion batteries in particular. He teaches us about the five key aspects of battery performance - aspects that are more or less important depending on the intended battery application, but where no single battery type gets top score in all five areas. We also get to learn about the history of battery development - why and how they were invented, how the area has evolved over the years and how scientists have been scouting the periodic table to find suitable battery materials. Prof. Berg explains why the Li-ion battery is so special, and why dendrite formation, or whiskers as they are also called, are so problematic and certainly should be avoided in a battery. And – he shares the story of when he met one of the laureates who was awarded the Nobel prize for the development of this exceptional type of battery.Thanks for listening! If you are interested in surface science and related topics, you should also check out our blog - the Surface Science blog
What are nanomedicines? And how are they different from traditional ones? In this episode of Science on surfaces we talk to we talk to Dr. Gustav Emilsson about the fascinating area of nanomedicines. Dr. Emilsson is working as a Postdoc with nanomedicine development at the department of Advanced drug delivery in Pharmaceutical Science at AstraZeneca, a global, science-led biopharmaceutical company. We start out by talking about what nanomedicines are and how they work. Dr. Emilsson explains how intricate design of these minuscule drug carriers can help overcome challenges such as drug toxicity and solubility issues, and how nanomedicines can be used to control the drug release in the body. We also talk about a phenomenon that is very relevant in the context of nanomedicines - the formation of the so-called protein corona, which affects how the drug delivery vessel interacts with the body. And finally, Dr. Emilsson shares some thoughts on what the future looks like for this intriguing area.Thanks for listening! If you are interested in surface science and related topics, you should also check out our blog - the Surface Science blog
How come egg and oil will turn into a nice emulsion called mayonnaise when mixed, while water and oil will unavoidably separate into two different phases no matter how vigorously you stir? And is there a way to predict the stability of such phase-mixtures?In this episode of Science on surfaces we talk to Dr Susanna Lauren at Biolin Scientific about interfacial rheology and how this can be used to predict emulsion and foam stability. Susanna did her Ph.D. on superhydrophobic surfaces and microfluidics and she is an expert on surface related phenomena, such as surface tension, wettability, adhesion and interfacial rheology. Susanna explains key terminology such as viscosity, stabilization of interfaces and surface-active molecules, which then leads us to the discussion of how emulsions and foams form. Susanna then moves on to explain in what situations, and why, it is important to be able to measure emulsion and foam stabilities and how this information can be used. She also describes how these measurements can be performed using either of the two approaches of shear- or dilatational methods. Thanks for listening! If you are interested in surface science and related topics, you should also check out our blog - the Surface Science blog
Is it possible to learn a method that will help you get published in high-impact journals? And is there such a thing as a writer’s block? In this first episode of Season 3 of Science on surfaces we talk to Dr Anna Clemens, Scientific writing coach & editor, about the challenges of scientific writing. Dr. Clemens has a PhD in Chemistry and she is also a journalist. In her company “Scientists Who Write”, she helps scientists to improve their writing skills, to write more efficiently, and to get published in high-impact journals. In this episode, we really get to the bottom of the writing process and we get to reveal all the secrets of how to methodically, step-by-step, write a successful manuscript. Dr. Clemens starts by talking about the core of a good paper, which is also the key to success - the storytelling framework. She then guides us through the five step-process that will make sure all the bits and pieces are in place and that they all fit nicely together within the storytelling framework. Also, as we discussing the challenges of scientific writing, we of course had to bring up the phenomenon of the writer’s block – this unwelcome nuisance that most of us have experienced at one point or another in our lives, and which simply makes it impossible to get any words down on paper. Of course, Dr Clemens has reflected on this topic and shares her thoughts on how to address it.Thanks for listening! If you are interested in surface science and related topics, you should also check out our blog - the Surface Science blog Episode linksBooks discussed in the episode Deep work, Cal Newport: https://www.goodreads.com/book/show/25744928-deep-workOn Writing Well, William Zinsser: https://www.goodreads.com/book/show/53343.On_Writing_WellWriting Science, Joshua Schimel: https://www.goodreads.com/book/show/13122323-writing-scienceGet in touch with Dr Clemens Website: https://www.annaclemens.com/Blog: https://www.annaclemens.com/blog-overview (or navigate to Blog button) Work with Anna: https://www.annaclemens.com/work-with-me (or navigate to "Get Writing Support" button) Twitter: @scientistswriteLinkedIn: https://www.linkedin.com/in/annaclemens/
Is it really possible to get more done in less time and at the same time be happier and perhaps even live longer? In this last episode for the season, we talk to David Stiernholm, Struktör, about structure. For almost two decades, David has been helping people and organizations become more efficient by creating better structure and order.The episode is packed with inspiration, tips, tricks, and tools on how to get started structuring your work and to, once and for all, get rid of that overwhelming feeling of the to-do:s controlling you instead of the other way around. David talks about the three building blocks of how the structure is created - organize, focus, and automate. Taking us through each category, what they mean and how they can be addressed, David gives us concrete tips and tools on what to do and how to implement structure in your life and work (see links below). We also talk about the benefits of structure, if it can be too much, and how to make the most of the structuring tool to free time and get in control of your schedule.Thanks for listening! If you are interested in surface science and related topics, you should also check out our blog - the Surface Science blogEpisode linksThe noise app Noisli: http://www.noisli.comThe timeline tool Timeline: http://timeline.knightlab.comThe workflow automation tool Power Automate: https://flow.microsoft.com/sv-se/The workflow automation tool Zapier: http://www.zapier.comThe text expansion tool TextExpander: http://textexpander.comStudy on the Relationships of Job Demands and Job Control with Mortality https://onlinelibrary.wiley.com/doi/abs/10.1111/peps.12206About the (10+2)x5-method https://www.stiernholm.com/en/blog/how-two-egg-timers-make-you-focus-on-the-right-thingDavid’s blog: https://www.stiernholm.com/en/blog/David’s podcast: https://podcasts.apple.com/se/podcast/done/id559834100?mt=2David’s book: http://www.superstructured.comDavid’s Youtube channel: https://www.youtube.com/user/stiernholmconsulting/David’s weekly newsletters: https://www.stiernholm.com/en/tips/
What makes a liquid droplet just roll off the surface of a lotus-leaf? And what does it take for us to mimic this extraordinary design by nature and to make self-cleaning surfaces?In this episode of Season 2 of Science on surfaces we talk to Susanna Lauren at Biolin Scientific about superhydrophobic surfaces. Susanna did her Ph.D. on superhydrophobic surfaces and microfluidics and she is an expert on surface related phenomena, such as surface tension, wettability, adhesion and surface free energy. We start the conversation with Susanna describing how superhydrophobicity is defined and what properties that need to be fulfilled for a surface to qualify as superhydrophobic. She then explains how such surfaces can be manufactured and lists the many areas where these surfaces would be beneficial. We also talk about why, in spite the very useful qualities of hydrophobicity, there still are so few commercial products available in the market, and what the future holds for man-made mimics of this amazing design by nature. Thanks for listening! If you are interested in surface science and related topics, you should also check out our blog - the Surface Science blog
What makes a liquid spread more on some surfaces than on others?In this episode of Season 2 of Science on surfaces we talk to Susanna Lauren at Biolin Scientific about Surface Free Energy. Susanna did her Ph.D. on microfluidics and superhydrophobic surfaces and is an expert on surface related phenomena, such as surface tension, wettability, adhesion and surface free energy.Susanna describes how the surface free energy of a solid arises and how molecular interactions such as cohesive and adhesive forces are used to determine the value. She then explains how the surface free energy of a solid will determine for example how a liquid will behave when placed on top of it and how much the liquid will spread. We also get to learn more about why the surface free energy is not measured but calculated using Youngs equation and how this fairly complicated theory is made simple with existing software. Thanks for listening! If you are interested in surface science and related topics, you should also check out our blog - the Surface Science blog
Which day-care center has the best air quality? And is this Li-ion battery approaching a catastrophic failure?These are questions that NPS technology could answer. In this episode of Season 2 of Science on surfaces we talk to Dr. Elin Langhammer about Nanoplasmonic sensing, also called NPS. Dr Langhammer is co-founder and technical director of Insplorion, a company that develops and manufactures NPS sensors for research and development instruments as well as large volume sensor applications.The conversation starts by Dr Langhammer describing how NPS technology works and how nanoparticles at a surface, illuminated by light, can reveal what happens in their surroundings. We then move on to talk about how this technology is used in diverse areas, both as a research tool and in large scale sensing applications, for example in measurements of air quality. We also talk about future applications and how NPS measurements can reveal the status and health of Li-ion batteries, information that could facilitate the transition to renewable energy sources, where batteries are an important component. Thanks for listening! If you are interested in surface science and related topics, you should also check out our blog - the Surface Science blog
How come paint sticks to the wall? And what makes the ink, used to print logos and text on the milk carton, stay in place?In this episode of Season 2 of Science on surfaces we talk to Susanna Lauren at Biolin Scientific about adhesion. Susanna did her Ph.D. on microfluidics and superhydrophobic surfaces and is an expert on surface related phenomena, such as surface tension, surface free energy, wettability, and adhesion.Susanna describes how adhesion is defined and talks about the three different components that, in combination, give rise to this phenomenon. We then move on to talk about in what areas adhesion is important and what different factors that affect it. We also get to learn more about what possibilities there are to predict the quality of the adhesion and how it can be tested. Thanks for listening! If you are interested in surface science and related topics, you should also check out our blog - the Surface Science blog
How come a water droplet spreads more on a clean glass surface than on a plastic one? And why does the nature of the water spread on the surface matter in a biomedical application?In this episode of Season 2 of Science on surfaces we talk to Susanna Lauren at Biolin Scientific about contact angles, which is a measure of wettability of a surface. Susanna did her Ph.D. on microfluidics and superhydrophobic surfaces and is an expert on surface related phenomena, such as surface tension, adhesion, surface free energy and wettability.Susanna explains what factors affect the wettability and why the contact angle differs between different materials, making some materials hydrophilic and others hydrophobic. We also get to learn more about how the contact angle can be measured and how it can reveal whether a material will be suitable for a biomedical implant and if your paint will stick to the wall or not.Thanks for listening! If you are interested in surface science and related topics, you should also check out our blog - the Surface Science blog
Why are so many scientists struggling with stress at work? And what can we do to improve the situation? In this episode, we talk to Dr Déborah Rupert, certified professional coach, about well-being and stress management for scientists. Dr Rupert, who has a background in science, today works to support science innovators with knowledge and tools designed to take care of their minds and protect them from burnout.In the conversation, we talk about the work-related stress experienced by many academia and what the root causes are. Dr Rupert then gives us some tips and shares some practical tools that can help us take care of our minds, reduce the stress levels and protect ourselves from burnout. Thanks for listening! If you are interested in surface science and related topics, you should also check out our blog – the Surface Science blog
Why is surface tension so important in nature, and even a requirement for life? And why are so many industries struggling to overcome its effects? In this episode of Season 2 of Science on surfaces we talk to Dr Susanna Lauren at Biolin Scientific about Surface Tension. Susanna did her Ph.D. on microfluidics and superhydrophobic surfaces and is an expert on surface-related phenomena, such as adhesion, wettability, surface free energy and – most importantly - surface tension, the topic of today’s conversation. Susanna explains why the surface of water behaves like an elastic sheet and how this phenomenon impacts several aspects of the world around us, from the ecosystems to laundry soil removal, and many other aspects of our lives. We also talk about how the surface tension can be measured, and what challenges that could be involved in such an analysis.Thanks for listening! If you are interested in surface science and related topics, you should also check out our Surface Science blog
How does soil removal really work? And why is it so difficult to remove the sweaty smell from sportswear? In this first episode of Season 2 of Science on surfaces we talk to Lars Mathiesen, Global Marketing Manager at Novozymes and expert in soil removal. Lars has a background in biology and biology-technology and has been working with enzymes within cleaning solutions for more than 10 years. The conversation starts with an overview of the soil removal basics. Lars describes the different components included in a cleaning formulation, what their roles are, and why cleaning formulation design can be so challenging. We also talk about why some soil is particularly difficult to remove, and what cleaning solutions that we can expect to see in the future.Thanks for listening! If you are interested in surface science and related topics, you should also check out our Surface Science blog
Viral outbreaks and cancer represent two of the world’s biggest health problems. Could a materials science and engineering approach be used to address these challenges in global health?In this last episode of Season 1, of Science on surfaces - a bigger perspective on the small, we talk to Prof. Nam-Joon Cho, Nanyang Associate Professor at the School of Materials Science and Engineering at Nanyang Technological University in Singapore. Prof. Cho is leading the Engineering in Translational Science group, where they apply engineering strategies to solve challenging biomedical problems and to combat e.g. infectious diseases.We start the conversation talking about the challenges of global health and Prof. Cho describes their surface science approach towards antiviral drug design, an approach which he believes could revolutionize antiviral drug development. He and his team have engineered an antiviral peptide that targets the Achilles heel of the Zika virus and other viral pathogens, such as hepatitis C, yellow fever and dengue. Prof. Cho talks about their published results on this drug candidate for therapeutic treatment of the Zika virus, as well as the work they are doing for early detection of circulating cancer tumor cells.If you are interested in surface science and related topics, you should also check out our Surface Science blog!
What is tissue engineering, can all tissue be engineered and what’s in a bioink?In this episode of Science on surfaces - a bigger perspective on the small we talk to Prof. Paul Gatenholm, Division of Chemistry and Chemical Engineering at Chalmers University of technology and Director of 3D Bioprinting Center, BBV at Biotech Center. In the studio, we also have Prof. Bengt Kasemo, Chalmers University of technology, who has long experience in the area of biomaterials.We start with the basics and Paul tells us more about what tissue engineering is, how it works and what the engineered tissue can be used for. We also talk about where surfaces come into play, what challenges there are in terms of growing and using the tissue, and how vascularized organ tissue in the future could be sent into space to learn more about what negative effects deep space mission would have on humans.If you are interested in surface science and related topics, you should also check out our Surface Science blog!
Could CCS help us fight climate change? How much CO2 is it possible to capture? And what is the difference between CCS, BECCS and DAC?In this episode of Science on surfaces - a bigger perspective on the small we talk to Prof. Filip Johnson from the Division of Energy Technology at Chalmers University of technology, who’s research focuses on ways to reduce the negative impact of the energy system on the climate. In the studio, we also have Prof. Bengt Kasemo, Chalmers University of technology, who has worked a lot with sustainable energy and the energy system of the future. As always, we start with the basics and Filip tells us more about what CCS is, why it is needed and what negative emission means. We also talk about how CCS works in practice, from capture to storage, and what the captured CO2 can be used for. Finally, Filip shares his view on what challenges there are in terms of CCS implementation and what the future looks like.If you are interested in surface science and related topics, you should also check out our Surface Science blog!
With the overall global ambition to shift from fossil fuel-based energy sources to sustainable ones, such as wind and solar power, the need for energy storage will increase.In this episode of Science on surfaces - a bigger perspective on the small we talk to Prof. Bengt Kasemo about energy storage and how surface science matters for some of the important storage methods. Prof. Kasemo, who has long experience in surface science and who has worked a lot with sustainable energy and the energy system of the future, explains key concepts and terminology and shares some of his knowledge, thoughts, and ideas on the topic.As always, we start with the basics and talk about why energy storage is needed and what different ways there to store energy. We then dig deeper into the storage methods where surface processes are involved, such as batteries and super capacitors, and touch upon the related topic of fuel cells. We also talk about how the surface material properties and surface condition matters, what are the pros and cons of the respective method, including challenges and limitations, and what the future looks like for these methods.If you are interested in surface science and related topics, you should also check out our Surface Science blog!
Global warming is by definition a macroscopic phenomenon and its consequences will affect the entire planet. Even in a context of such a magnitude, surface science, and processes taking place at the nanoscale, have a role to play.In this episode of Science on surfaces - a bigger perspective on the small we talk to Prof. Bengt Kasemo about climate change, the energy system, and how surface science helps us in the endeavor towards sustainable energy solutions. Prof. Kasemo, who has long experience in surface science and the energy systems of the future, shares some of his knowledge and ideas on the topic.We start with the basics and talk about the greenhouse effect, the relation between the energy system and global warming and what possibilities there are to reduce the emission of greenhouse gases. We also talk about sustainable energy and the fact that surface science plays an important part, both in the development of alternative solutions for energy production and for solutions that may help us reduce the amount of CO2 released into the atmosphere.If you are interested in surface science and related topics, you should also check out our Surface Science blog!
What makes an implant integrate into the surrounding tissue in our bodies, and how come some biomaterials stick while other materials can smoothly be removed from the body even after a longer period of contact or insertion?In this episode of Science on surfaces - a bigger perspective on the small we take a closer look at the interfacial boundary between a physical body and synthetic materials. We talk to two experts in the field; Prof. Bengt Kasemo, Chalmers University of Technology, who has long experience in the area of biomaterials, including working in the project which resulted in the Brånemark concept for titanium implants, and Dr. Åsa Westling, Senior R&D Scientist at Wellspect Health Care, a company that develops and produces medical devices .We talk about what happens at the interface between a biomaterial and the body when they meet, the concept of biocompatibility and what complications that can arise if the intended surface interactions do not take place. We also talk about how an understanding of the interfacial processes can be used to design products with certain functionality and what we can expect to see in the area of biomaterials in the future.If you are interested in surface science and related topics, you should also check out our Surface Science blog!
Nanotechnology has been around for decades, and today these minuscule entities enter into our everyday lives via products such as sunscreen, food, sports clothes and electronics. Why has ‘nano’ become so popular, and what are risks involved when we are exposed to these nanoengineered objects? In this episode of Science on surfaces - a bigger perspective on the small, we talk to Bengt Kasemo, Professor of physics at Chalmers University of Technology and a member of both the Royal Swedish Academy of Sciences and the Royal Swedish Academy of Engineering Sciences. Prof. Kasemo has long experience in surface science, and he also works with nanotoxicology and nano-safety. We talk about how nanotechnology originated, what advantages this particular size range offers over others, and what makes nanotechnology so extremely attractive. We also talk about the risks involved and what safety challenges there are. Prof. Kasemo lists a range of unexplored opportunities which could be realized in the future.If you are interested in surface science and related topics, you should also check out our Surface Science blog!
Biolin ScientificWhat defines a surface? What kind of science is related to surfaces, and most importantly, does surface science really matter to, and have an impact on, our everyday lives?In this episode of Science on surfaces - a bigger perspective on the small, we talk to Prof. Bengt Kasemo, who is Professor of physics at Chalmers University of Technology. Prof. Kasemo has long experience in surface science and is a member of both the Royal Swedish Academy of Sciences and the Royal Swedish Academy of Engineering Sciences. We start out with the surface science basics and talk about what defines a surface and what different types of surface-related science there is. We also talk about how, when and why this field of research started, why this kind of research is important, and what inventions, that impact our everyday lives, that originate in this area. If you are interested in surface science and related topics, you should also check out our Surface Science blog!